Von Uruhren bis hin zu zirkadianen Oszillatoren
Nature volume 616, pages 183–189 (2023)Cite this article
16k Accesses
2 Citations
124 Altmetric
Metrics details
Circadian rhythms play an essential part in many biological processes, and only three prokaryotic proteins are required to constitute a true post-translational circadian oscillator1. The evolutionary history of the three Kai proteins indicates that KaiC is the oldest member and a central component of the clock2. Subsequent additions of KaiB and KaiA regulate the phosphorylation state of KaiC for time synchronization. The canonical KaiABC system in cyanobacteria is well understood3,4,5,6, but little is known about more ancient systems that only possess KaiBC. However, there are reports that they might exhibit a basic, hourglass-like timekeeping mechanism7,8,9. Here we investigate the primordial circadian clock in Rhodobacter sphaeroides, which contains only KaiBC, to elucidate its inner workings despite missing KaiA. Using a combination of X-ray crystallography and cryogenic electron microscopy, we find a new dodecameric fold for KaiC, in which two hexamers are held together by a coiled-coil bundle of 12 helices. This interaction is formed by the carboxy-terminal extension of KaiC and serves as an ancient regulatory moiety that is later superseded by KaiA. A coiled-coil register shift between daytime and night-time conformations is connected to phosphorylation sites through a long-range allosteric network that spans over 140 Å. Our kinetic data identify the difference in the ATP-to-ADP ratio between day and night as the environmental cue that drives the clock. They also unravel mechanistic details that shed light on the evolution of self-sustained oscillators.
Circadian clocks are self-sustained biological oscillators that are ubiquitously found in prokaryotic and eukaryotic organisms. In eukaryotes, these systems are complex and highly sophisticated, whereas in prokaryotes, the core mechanism is regulated by a post-translational oscillator that can be reconstituted in vitro with ATP and three proteins (encoded by kaiA, kaiB and kaiC)1. Seminal work on the KaiABC system has resulted in a comprehensive understanding of its circadian clock. KaiC is the central component that autophosphorylates by binding to KaiA and autodephosphorylates following association with KaiB3,4,5,6. The interplay among these three proteins has been shown in vitro to constitute a true circadian oscillator characterized by persistence, resetting and temperature compensation. Consequently, the KaiABC system is considered an elegant and the simplest implementation of a circadian rhythm. The evolutionary history of kai genes established kaiC as the oldest member dating back around 3.5 billion years ago. Subsequent additions of kaiB and most recently kaiA formed the extant kaiBC and kaiABC clusters, respectively2,10. Notably, some studies of more primitive organisms that lack kaiA hinted that the kaiBC-based systems might already provide a basic, hourglass-like timekeeping mechanism7,8,9. Contrary to the self-sustained oscillators found in cyanobacteria, such a timer requires an environmental cue to drive the clock and for the daily flip of the hourglass. The central role of circadian rhythms in many biological processes, controlled by the day and night cycle on Earth, makes their evolution a fascinating topic.
Here we investigate such a primitive circadian clock through biochemical and structural studies of the KaiBC system of the purple, nonsulfur photosynthetic proteobacterium R. sphaeroides KD131 (hereafter, its components are referred to as KaiBRS and KaiCRS). The organism shows sustained rhythms of gene expression in vivo, but whether kaiBC is responsible for this observation remains inconclusive in the absence of a kaiC knockout11. A previous study of the closely related bacterium Rhodopseudomonas palustris that used a knockout strain demonstrated causality between the proto-circadian rhythm of nitrogen fixation and expression of the kaiC gene9. Here through in vitro experiments, we discover that KaiBCRS is a primordial circadian clock with a mechanism that is different from the widely studied circadian oscillator in Synechococcus elongatus PCC 7942 (hereafter, its components are referred to as KaiASE, KaiBSE and KaiCSE)3,4,5,6. We identify an environmental cue that regulates the phosphorylation state and consequently produces a 24 h clock in vivo as the switch in the ATP-to-ADP ratio between day and night. Our results from kinetic studies combined with X-ray and cryogenic electron microscopy (cryo-EM) structures of the relevant states unravel a long-range allosteric pathway that is crucial for the function of the hourglass and sheds light on the evolution of self-sustained oscillators. Notably, we find a new protein fold for KaiCRS and uncover a register shift in the coiled-coil domain that spans around 115 Å as the key regulator in this system, which shows structural similarities to dynein signalling12.
To gain insight into the evolution of the kaiBC cluster, we constructed a phylogenetic tree of kaiC after the emergence of kaiB (Fig. 1a, Extended Data Fig. 1a and Supplementary Datasets 1 and 2). The first question we sought to answer is how KaiCRS and other members in the clade can autophosphorylate despite having no KaiA. KaiA is known to be crucial for this function in the canonical KaiABC system at its optimum temperature. We observed a large clade that exhibits a C-terminal tail about 50 amino acids longer compared with kaiC in other clades (Extended Data Fig. 1b). This C-terminal extension near the A loop is predominantly found in the kaiC2 subgroup, which was previously annotated as having two serine phosphorylation sites instead of the Thr–Ser pair found in the kaiC1 and kaiC3 subgroups13,14,15 (Extended Data Fig. 1b). In S. elongatus, the binding of KaiASE to the A loop of KaiCSE tethers them in an exposed conformation16 that activates both autophosphorylation and nucleotide exchange17. Given the proximity of the extended C-terminal tail to the A loop, we conjectured that it could serve as the ‘primitive’ regulatory moiety that was made redundant with the appearance of KaiA.
a, Schematic of the phylogenetic tree of kaiC showing the appearance of kaiB and kaiA during evolution. The kaiC clade with an approximately 50-amino-acid C-terminal extension is labelled in red, and a timeline was predicted as previously reported2. Ga, billion years ago. b, Phosphorylation rate over time of KaiCRS (6.5 ± 1.0 h−1) and KaiCSE in the presence (0.40 ± 0.02 h−1) or absence of KaiASE at 30 °C. The s.d. in reported parameters were obtained from the fitting. c, Nucleotide exchange between ATP and mant-ATP in KaiCRS alone (18.0 ± 1.5 h–1) compared with KaiCSE in the presence (4.7 ± 0.3 h–1) and absence of KaiASE (0.08 ± 0.04 h–1) measured at 30 °C. Representative traces are shown, and the fitted parameters (mean ± s.d.) were obtained from three replicate measurements. d, X-ray structure of dodecameric KaiCRS (PDB: 8DBA) coloured by hexamer A (light green) and hexamer B (dark green). The CI, CII and coiled-coil domains are indicated, and the A loop is labelled in e. e, Superposition based on an alignment of the CII domain of KaiCRS (green; PDB: 8DBA, chain B), KaiCSE (purple; PDB: 1TF7, chain B)36 and KaiCSE-S431E/T432A (yellow; PDB: 7S65, chain A)19 shows that KaiCRS has an extended A loop orientation that no longer forms the inhibitory interaction with the 422 loop (KaiCSE numbering). The conformation of the 422 loop in KaiCRS resembles the one seen in the cryo-EM structure of the phosphomimetic KaiCSE-S431E/T432A (yellow; PDB: 7S65)19. No electron density is observed for the C-terminal part of wild-type KaiCSE and the S431E/T432A mutant owing to flexibility, and the missing 22 residues for wild-type KaiCSE (46 for S431E/T432A) are represented by a dashed line (not shown for the mutant).
To test our hypothesis, we first measured the autophosphorylation and nucleotide exchange rates in KaiCRS, which both depend on the presence of KaiA in the KaiABCSE system. We observed an autophosphorylation rate for KaiCRS that was about 16-fold higher than for KaiCSE activated by KaiASE (6.5 ± 1.0 h−1 compared with 0.40 ± 0.02 h−1, respectively; Fig. 1b and Extended Data Fig. 2a–e). Similarly, the nucleotide exchange rate was faster in KaiCRS compared with KaiCSE, even in the presence of KaiASE (18.0 ± 1.5 h−1 compared with 4.7 ± 0.3 h−1, respectively; Fig. 1c and Extended Data Fig. 2f). Our data show that KaiCRS can perform both autophosphorylation and nucleotide exchange on its own and does so faster than its more recently evolved counterparts.
To mechanistically assess how KaiC in kaiA-null systems accomplishes autophosphorylation, we turned to structural biology. The crystal structure of KaiCRS, unlike KaiC from cyanobacteria, revealed a homododecamer that consisted of two homohexameric domains joined by a 12-helical coiled-coil domain that is formed by the extended C-terminal tail (Protein Data Bank (PDB) identifier: 8DBA; Fig. 1d and Extended Data Table 1). A closer inspection of the CII domains in KaiCRS and KaiCSE/TE (Thermosynechococcus elongatus BP-1 referred to as KaiCTE) showed an obvious difference in A loop orientations: an extended conformation in KaiCRS compared with a buried orientation in KaiCSE/TE (Fig. 1e). The existence of such an extended conformation following binding of KaiA has been previously proposed18. This hypothesis was based on the perceived hyperphosphorylation and hypophosphorylation that occurred after removing the A loop or disrupting KaiA binding, respectively18. A recently solved cryo-EM structure of the night-time phosphomimetic KaiCSE-S431E/T432A in its compressed state directly showed a disordered A loop that no longer interacts with the 422 loop19, similar to the extended A loop conformation we observed in KaiCRS (Fig. 1e). The loss of interaction between the A loop and the 422 loop (just 10 residues apart from the phosphorylation sites) results in closer proximity between the hydroxyl group of Ser431–Thr432 and the γ-phosphate of ATP, thereby, facilitating the phosphoryl transfer step20. Furthermore, the sequence similarity between KaiCRS and KaiCSE is less than 30% for the A loop and residues considered important for stabilization of this loop in its buried orientation (that is, the 422 loop and residues 438–444) (Fig. 1e). Together, our structural and kinetic data support the idea that an exposed A loop is key for the KaiA-independent enhancement of nucleotide exchange and hence autophosphorylation in KaiCRS and perhaps other KaiBC-based systems.
We then questioned whether the purpose of the coiled-coil domain is to ‘pull up’ the A loop or to actively participate in nucleotide exchange and autophosphorylation of KaiC. To further understand its role, we generated a truncation at residue Glu490 based on the phylogenetic tree and crystallographic information (KaiCRS-Δcoil) (Extended Data Fig. 1b) to disrupt the coiled-coil interaction between the two hexamers. The crystal structure of KaiCRS-Δcoil (PDB: 8DB3; Fig. 2a,b and Extended Data Table 1), its size-exclusion chromatogram and analytical ultracentrifugation profile (Extended Data Fig. 3a–c) showed a hexameric structure with no coiled-coil interaction. Nucleotide exchange rates in the CII domain for KaiCRS-Δcoil and the wild-type protein were comparable (19.1 ± 0.8 h−1 and 18.0 ± 1.5 h−1, respectively; Extended Data Fig. 3d). The phosphorylation rates were also similar (5.5 ± 0.4 h−1 and 7.4 ± 0.3 h−1 for KaiCRS-Δcoil and wild type, respectively; Extended Data Fig. 3e,f). These results indicate that the extended A loop and not the coiled-coil interaction plays a pivotal part in nucleotide exchange and autophosphorylation in KaiCRS. The results also provide a potential mechanism of autophosphorylation in other KaiBC-based systems that lack a coiled-coil bundle. Notably, the coiled-coil bundle provides additional hexameric stability. In detail, the KaiCRS dodecamer is stable for extended periods of time in the presence of only ADP (Extended Data Fig. 3g,h), whereas for KaiCSE, oligomers are not observed under these conditions21.
a, X-ray structure of KaiCRS-Δcoil was solved in the C2221 space group and contained three monomers in the asymmetric unit, with ADP present in all active sites. The obtained electron density map allowed for model building up to Pro463, which indicated that the truncation at position 490 results in enhanced flexibility beyond Pro463. Phosphorylation of Ser414 (pS414) was observed in chain B (cyan) as shown by the electron density mFo–DFc polder map (green mesh, 3σ contour level). b, Assembly analysis using the PISA software37 revealed a hexamer as the most probable quaternary structure (top view). c, Structural comparison of the coiled-coil domain for unphosphorylated KaiCRS (dark and light green; X-ray structure) and the KaiCRS-S413E/S414E phosphomimetic mutant (dark and light blue; cryo-EM structure). d, Overlay of interacting dimers of the structures in c using the CII domain of chain A as a reference (dark shades; bottom). Unphosphorylated KaiCRS (dark green) interacts with the opposite partner on the right (light green), whereas KaiCRS-S413E/S414E (dark blue) interacts with the partner on the left (light blue). The hydrophobic packing in the coiled-coil domain is mediated by only the Cβ atoms of alanine and arginine residues in unphosphorylated KaiCRS, but involves the entire side chain of leucine and isoleucine residues in the phosphomimetic structure. e, Allosteric network in the phosphomimetic state (blue) from the coil (light blue) propagating through the KaiCRS CII domain to the active site (dark blue) compared with the unphosphorylated state (dark green) (Supplementary Video 1). f, Autodephosphorylation of KaiCRS and KaiCRS-Δcoil over time in the presence of 4 mM ADP at 30 °C. The phosphorylated (P) and unphosphorylated (U) proteins were separated by Zn2+ Phos-tag SDS–PAGE (for gel source data, see Supplementary Fig. 1).
The change in phosphorylation state of KaiC has been well established to be the central feature for the circadian rhythm22,23. Notably, when comparing the unphosphorylated form of full-length KaiCRS (PDB: 8DBA) and its phosphomimetic mutant (S413E/S414E; PDB: 8FWI) (Extended Data Fig. 4 and Extended Data Table 2), we observed two distinct coiled-coil interactions. Following phosphorylation, the coiled-coil pairs swap partners by interacting with the other neighbouring chain from the opposite hexamer, which resulted in a register shift that propagated around 115 Å along the entire coiled-coil (Fig. 2c and Extended Data Fig. 5). In the phosphomimetic state, the register comprised bulkier hydrophobic residues that resulted in a more stable interaction than for the dephosphorylated form (Fig. 2d and Extended Data Fig. 3g). Furthermore, the C-terminal residues of KaiCRS-S413E/S414E interacted with the CII domain of the opposite hexamer, whereas the lack of electron density for the last 30 residues in the wild-type structure indicates more flexibility in the dephosphorylated state. We discovered that these conformational changes in the coiled-coil domain seemed to be coupled through a long-range allosteric network to the phosphorylation sites. The rotameric states of residues Ser413, Ser414, Trp419, Val421, Tyr436, Leu438, Val449 and Arg450 moved concertedly and pointed towards the nucleotide-binding site when the protein was phosphorylated or pointed away in the absence of a phosphate group (Fig. 2e, Extended Data Fig. 5d and Supplementary Video 1). We propose that the proximity of the nucleotide to the phosphorylated residue facilitated more efficient phosphoryl transfer. We therefore experimentally determined the impact of the coiled-coil domain on the autodephosphorylation rate of KaiCRS. The wild-type protein dephosphorylated comparatively quickly (observed rate constant = 11.5 ± 0.8 h−1) in the presence of only ADP. By contrast, little dephosphorylation was observed for KaiCRS-Δcoil (Fig. 2f and Extended Data Fig. 3i), for which allosteric propagation was disrupted (Extended Data Fig. 5d). Consistent with this accelerated dephosphorylation rate mediated by the coiled-coil domain, our crystallographic data showed a phosphate group on Ser414 for KaiCRS-Δcoil but not for the wild-type protein (Fig. 2a and Extended Data Fig. 5d).
It was notable that KaiCRS can autodephosphorylate on its own despite being constitutively active for phosphorylation owing to its extended A loop conformation. In the canonical kaiABC system, the interaction between KaiB and KaiC is required to provide a new binding interface that sequesters KaiA from its activating binding site, thereby promoting autodephosphorylation at the optimum temperature of the organism24,25,26. We therefore sought to discover whether the KaiCRS system can oscillate and whether there is a regulatory role for KaiBRS in this process. Comparing the in vitro phosphorylation states of KaiCRS in the absence and presence of KaiBRS showed an initial, rapid phosphorylation followed by an oscillatory-like pattern in the presence of KaiBRS (hereafter referred to as KaiBCRS), whereas KaiCRS alone remained phosphorylated (Fig. 3a,b). Notably, the ATP consumption during the reaction with KaiBRS was significantly higher than without (Fig. 3a). As noted above, KaiCRS will also dephosphorylate completely in the presence of only ADP (Fig. 2f). These results suggest that the phosphorylation state of KaiCRS and the observed oscillatory half-cycle (Fig. 3a,b) is probably related to a change in the ATP-to-ADP ratio. We conjectured that this could constitute the environmental cue to reset the timer. To test our hypothesis, an ATP-recycling system was added after complete dephosphorylation of KaiBCRS. As predicted, KaiCRS was able to restart the cycle and phosphorylate again (Extended Data Fig. 6a). We note that in vivo, the ATP-to-ADP ratio will not vary as substantially as in this in vitro experiment, as nucleotide homeostasis is tightly regulated. To mimic the day and night period for R. sphaeroides, we repeated the experiments while keeping the ATP-to-ADP ratio constant (mostly ATP at daytime owing to photosynthesis compared with 25:75% ATP-to-ADP during night time)27. In the presence of high ATP (that is, mimicking daytime), KaiCRS remained single or double phosphorylated (Fig. 3c and Extended Data Fig. 6b) irrespective of KaiBRS. By contrast, a constant 25:75% ATP-to-ADP ratio (that is, mimicking night time) resulted in a much higher fraction of dephosphorylated KaiCRS in the presence of KaiBRS (Fig. 3c). Moreover, when the ATP-to-ADP ratio was flipped to mimic daytime, KaiCRS was able to phosphorylate again (Fig. 3c, around the 28 h mark). Our data support the notion that the phosphorylation behaviour of KaiBCRS strongly depends on the ATP-to-ADP ratio and demonstrate that the physical binding of KaiBRS results in a higher level of KaiCRS dephosphorylation at night time.
a, SDS–PAGE gel of 3.5 μM KaiCRS and 4 mM ATP in the absence (top) and presence (bottom) of 3.5 μM KaiBRS at 35 °C, with the percentage of ATP indicated at specific time points. b, Phosphorylation (single and double) of KaiCRS during the reaction in the absence (grey circles) or presence (red diamonds) of KaiBRS. c, Phosphorylation–dephosphorylation cycle of 3.5 μM phosphorylated KaiCRS in the absence and presence of 3.5 μM KaiBRS in a constant ATP-to-ADP ratio of high ATP (4 mM) to mimic daytime and about 25% ATP to mimic the night time (exact percentage of ATP indicated at specific time points) at 30 °C. U, S and D in a and c represent the unphosphorylated, single phosphorylated (at Ser413 or Ser414) and double phosphorylated state of KaiCRS, respectively (for gel source data, see Supplementary Fig. 1). d, ATPase activity of wild-type KaiCRS in the absence and presence of KaiBRS, KaiCRS-E62Q/E63Q in the absence and presence of KaiBRS, and KaiCRS-E302Q/E303Q in the absence and presence of KaiBRS at 30 °C. Bar graphs show mean ± s.d. from three replicates. e, Time-dependent autodephosphorylation of 32P-labelled KaiCRS bound with ADP in the presence of 20 μM KaiBRS and 4 mM ADP at 30 °C showing phosphorylated 32P-KaiCRS, 32P-ATP and free 32Pi. The reaction products were separated by thin layer chromatography. f, The decay of phosphorylated 32P-KaiCRS bound with 4 mM ADP in the absence (grey circles) and presence (red diamonds) of KaiBRS at 30 °C is obtained from autoradiography quantification (Extended Data Fig. 7). g, The nucleotide exchange of 3.5 μM KaiCRS (grey trace) and 3.5 μM KaiCRS in complex with 30 μM KaiBRS (red dotted trace) in the presence of ATP with mant-ATP. Representative traces are shown, and the fitted parameters (mean ± s.d.) were obtained from three replicate measurements.
Next we investigated the accelerated ATPase activity observed in KaiCRS after the formation of the complex. The ATPase activity reported for KaiCSE is low (about 15 ATP molecules per day per molecule of KaiCSE) and was proposed as a reason for the slowness of circadian oscillation28. KaiCRS alone shows a significantly faster ATPase rate than KaiCSE, which is further enhanced by binding of KaiBRS (208 ± 19 and 1,557 ± 172 ATP molecules day per day per KaiCRS, respectively; left two bars in Fig. 3d and Extended Data Fig. 6c–g). Furthermore, KaiCRS does not exhibit temperature compensation for its ATPase activity (temperature coefficient Q10 about 1.9; Extended Data Fig. 6c), a feature that is present in KaiCSE and proposed to be a prerequisite for self-sustained rhythms28. The deviation from unity for Q10 is consistent with our earlier observation that the KaiBCRS system is not a true circadian oscillator but rather an hourglass timer (Fig. 3b).
Mechanistic details of how the binding of KaiBRS in the CI domain allosterically affects the autodephosphorylation of KaiCRS in the CII domain remain unclear. There are three plausible scenarios to explain this: (1) KaiBRS binding stimulates the phosphoryl transfer from pSer back to ADP (Extended Data Fig. 7a); (2) KaiBRS binding increases the hydrolysis rate of the active-site ATP (Extended Data Fig. 8a); or (3) KaiBRS binding accelerates nucleotide exchange in the CII domain (Extended Data Fig. 8e). To differentiate among these possibilities, we performed radioactivity experiments to follow nucleotide interconversion. We also measured ATPase activity for wild-type KaiCRS and mutant forms that are incapable of ATPase activity in the CI or CII domain, and quantified nucleotide-exchange rates by measuring the fluorescence of mant-ATP. First, we detected fast, transient 32P-ATP formation in our radioactivity experiments when starting from 32P-phosphorylated KaiCRS, which was due to its ATP synthase activity in the CII domain (Fig. 3e and Extended Data Fig. 7b–d). The observed phosphoryl-transfer rate was independent of KaiBRS (observed rate constant = 12.0 ± 1.7 h−1 and 15.4 ± 1.7 h−1 in its absence and presence, respectively; Fig. 3f) and agreed well with the rates determined from our gel electrophoresis experiments (11.0 ± 0.8 h−1 and 11.5 ± 0.8 h−1 with or without KaiBRS, respectively; Extended Data Fig. 7e,f). Our experimental data confirmed that KaiCRS undergoes dephosphorylation through an ATP synthase mechanism, similar to what was observed for KaiCSE (ref. 29). KaiB does not expedite the actual phosphoryl-transfer reaction, which is never the rate-limiting step. As we were unable to stabilize the first phosphorylation site (Ser414) in the presence of ADP, the rates reported here correspond exclusively to dephosphorylation of Ser413. Second, to deconvolute the contributions of the CI and CII domains to the observed ATPase activity, we measured ADP production from KaiCRS mutants that abolish hydrolysis in either the CI domain (KaiCRS-E62Q/E63Q) or the CII domain (KaiCRS-E302Q/E303Q). For wild-type KaiCRS, the binding of KaiBRS resulted in a 7.5-fold increase in ATPase activity, and both domains were affected and contributed additively (3-fold for CI and at least 1.7-fold for CII) to the overall effect (Fig. 3d and Extended Data Fig. 8b–d). Of note, the fold increase in the CII domain represents a lower limit as the mutations induced to generate KaiCRS-E62Q/E63Q interfere with KaiBRS binding, as previously reported for KaiCSE (ref. 30). Third, our measurements of nucleotide exchange showed that this rate is also unaffected by KaiBRS binding (19.8 ± 1.8 h−1 and 18.0 ± 1.5 h−1 with or without KaiBRS, respectively; Fig. 3g). As there is no tryptophan residue near the nucleotide-binding site in the CI domain, only the exchange rate in the CII domain could be determined. Notably, the change in fluorescence amplitude was smaller in the presence of KaiBRS, which demonstrates that even though the binding of KaiBRS does not accelerate nucleotide exchange, it appears to induce a conformational rearrangement in the CII domain, especially at higher temperatures (Fig. 3g and Extended Data Fig. 8f–h).
To elucidate the structural underpinning of the enhanced ATPase activity of KaiCRS after KaiBRS binding, we solved the cryo-EM structures of KaiCRS alone (PDB: 8FWI) and in complex with KaiBRS (PDB: 8FWJ) (Extended Data Table 2). Twelve KaiBRS molecules (monomeric in solution; Extended Data Fig. 9a) bind to the CI domain of the KaiCRS-S413E/S414E dodecamer (Fig. 4a–c and Extended Data Fig. 9b). The bound state of KaiBRS adopts the same fold-switch conformation as observed for KaiBTE (ref. 25) and suggests that this is the canonical binding-competent state (Fig. 4b). Following binding of KaiBRS, the CI–CI interfaces loosen up (Fig. 4c), which enables the formation of a tunnel that connects bulk solvent to the position of the hydrolytic water in the active sites (Fig. 4d and Extended Data Fig. 9c). There are other lines of evidence for the weakened interactions within the CI domains. First, KaiBRS binding to either KaiCRS-CI domain (Extended Data Fig. 10a) or KaiCRS-Δcoil (that is, missing the C-terminal extensions; Extended Data Fig. 10b) resulted in disassembly of the hexameric KaiCRS structure into its monomers. By contrast, full-length KaiCRS maintained its oligomeric state following binding of KaiBRS, which is probably due to the stabilization provided by the coiled-coil interaction. Second, a decrease in melting temperature (Tm) of KaiCRS was observed with increasing KaiBRS concentration (Extended Data Fig. 10c). There was no interaction between neighbouring KaiBRS molecules within the complex (Extended Data Fig. 9b), which suggests that there is a non-cooperative assembly of KaiBRS to KaiCRS. This result is contrary to what has been observed for KaiBCSE and KaiBCTE complexes31,32.
a, Cryo-EM structure of KaiCRS-S413E/S414E (yellow) in complex with KaiBRS (blue) (PDB: 8FWJ). b, Superposition of KaiCRS-S413E/S414E (yellow) bound to KaiBRS (blue) (PDB: 8FWJ) and KaiCTE-S413E (dark grey) bound to fsKaiBTE (fold-switch, binding-competent state of KaiBTE; light grey) (PDB: 5JWQ)26. c,d, Binding of KaiBRS (blue) creates a tunnel (grey mesh) that enables water to reach the catalytic position (red sphere) for ATP hydrolysis in the CI domain. e, Binding of wild-type and mutant forms of KaiCRS to His-tagged KaiBRS in the presence of ADP or an ATP-recycling system at 25 °C. Bar graphs show mean ± s.d. from three replicates. f, Fluorescence anisotropy of unlabelled KaiBRS competitively displacing KaiBRS–6IAF (where 6IAF is the fluorophore) from unphosphorylated KaiCRS in the presence of ADP (dark green circles) and phosphorylated KaiCRS in the presence of the ATP-recycling system (light green triangles) at 30 °C. The average anisotropy and standard error were calculated from ten replicate measurements. g, Schematic of the uncovered mechanism of KaiCRS regulated by coiled-coil interactions and KaiBRS in the CI and CII domains.
Furthermore, we noted that KaiB-bound structures in phosphomimetic variants of KaiCRS (Fig. 4c,d) and KaiCSE (ref. 26) have ADP bound in their CI domain. This result demonstrates that the post-hydrolysis state is also the binding-competent state for KaiBRS. To test this hypothesis, a His-tagged KaiBRS protein was used in pull-down assays to detect its physical interaction with wild-type and mutant forms of KaiCRS bound with either ADP or ATP. Nearly all KaiBRS was complexed to ADP-bound KaiCRS, whereas less than 30% co-eluted in the ATP-bound form, regardless of the phosphorylation state (Fig. 4e and Extended Data Fig. 10d,e). The formation of complexes depended inversely on the ATP-to-ADP ratio (Extended Data Fig. 10f). We performed fluorescence anisotropy competition experiments to obtain a more quantitative description of the binding interaction between KaiCRS and KaiBRS. Highly similar dissociation constant (Kd) values were obtained for unphosphorylated, wild-type KaiCRS (Fig. 4f) and its phosphomimetic form (Extended Data Fig. 10g) bound with ADP (0.42 ± 0.03 µM and 0.79 ± 0.06 µM, respectively). No measurable binding curves were obtained for ATP-bound phosphorylated wild-type KaiCRS (Fig. 4f) or for KaiCRS-S413E/S414E (Extended Data Fig. 10g) with ATP-recycling system, which is probably due to the small fraction of complex present. Our data show that the post-hydrolysis state in the CI domain is key for KaiBRS binding, whereas the phosphorylation state of KaiCRS has only a marginal effect.
In summary, we demonstrate that binding of KaiBRS at the CI domain in the post-hydrolysis state facilitates the hydrolysis of transiently formed ATP after dephosphorylation of KaiCRS in the CII domain (Fig. 4g). Our fluorescence experiments (Fig. 3g and Extended Data Fig. 8f) detected a conformational change in the CII domain following KaiBRS binding, but we did not observe major structural changes in the cryo-EM structures. Based on the temperature dependence of the fluorescence amplitudes (Extended Data Fig. 8f), we conjecture that the inability to detect conformational differences is probably because of the low temperature. As the CII domain prefers to bind ATP over ADP (Extended Data Fig. 10h), ATP hydrolysis in the CII domain stimulated by KaiBRS is particularly important to keep KaiCRS in its dephosphorylated state at night time. During this period, the exogenous ATP-to-ADP ratio remains sufficiently high to otherwise result in ATP-binding in the CII active site (Fig. 3c and Extended Data Fig. 6b).
The KaiBCRS system studied here represents a primordial, hourglass timekeeping machinery, and its mechanism provides insight into more evolved circadian oscillators such as KaiABC. The dodecameric KaiCRS showed constitutive kinase activity owing to its extended C-terminal tail that forms a coiled-coil bundle with the opposing hexamer. This structure elicits a conformation akin to the exposed A loop conformation in KaiACSE, and autophosphorylation occurs within half an hour. In the KaiABCSE system, the transition from unphosphorylated to double phosphorylated KaiC takes place over about 12 h, and the fine-tuning of this first half of the circadian rhythm is accomplished by the emergence of KaiASE during evolution. The second clock protein, KaiB, binds the CI domain with the same fold-switched state in both systems. The interaction is controlled by the phosphorylation state in the KaiABCSE system, and its sole function is to sequester KaiASE from the activating binding site, whereas KaiB binding directly accelerates ATPase activity in the KaiBCRS system regardless of the phosphorylation state. The KaiBCRS system requires an environmental switch in the ATP-to-ADP concentration to reset the clock. The system therefore follows the day–night schedule when nucleotide concentrations inherently fluctuate in the organism. By contrast, the self-sustained oscillator KaiABCSE remains functional over a wide range of nucleotide concentrations and responds to changes in the ATP-to-ADP ratio by changing its phosphorylation period and amplitude to remain entrained with the day–night cycle33.
The newly reported structural fold of KaiC utilizes the versatile coiled-coil architecture as part of a long-range allosteric network that regulates KaiCRS dephosphorylation. Nature uses conformational changes in coiled-coil domains for a variety of regulatory functions34, including the activity of the motor protein dynein in the cellular transport of cargo along the actin filament12. A similar register shift, although in a coiled-coil interaction formed by only two helices, is used in dynein motility. Given that this simple heptad repeat sequence emerged multiple times and is found throughout all kingdoms of life35, it is an example of convergent evolution.
The wild-type KaiCRS (GenBank identifier: ACM04290.1) and KaiBRS (GenBank: WP_002725098.1) from R. sphaeroides strain KD131/KCTC 12085 (equivalent: Cereibacter sphaeroides strain KD131) constructs used in this paper were ordered from GenScript (Supplementary Table 1). Codon-optimized plasmids for KaiCRS and KaiBRS were subcloned into NcoI/KpnI sites of the pETM-41 vector. A QuikChange II Site-Directed Mutagenesis kit (Agilent Technologies) was used to generate single mutant, double mutant and truncated versions of KaiCRS. The truncated KaiCRS (KaiCRS-Δcoil and KaiCIRS) were generated by introducing stop codons in the KaiCRS wild-type plasmid. All primers were ordered from Genewiz (Supplementary Table 2). The presence of the intended KaiCRS mutations in the plasmid was confirmed by DNA sequencing by Genewiz using primers ordered from the same company (listed in Supplementary Table 2).
Both KaiCSE and KaiASE plasmids were a gift from E. K. O’Shea. Expression and purification were performed according to a previously described procedure6.
KaiCRS, KaiCRS mutants and KaiBRS were expressed in Escherichia coli BL21(DE3) cells (New England Biolabs) harbouring the plasmid pETM-41 containing the kaiCRS or kaiBRS gene. Three colonies from a freshly prepared transformation plate were inoculated into 1 litre of TB medium containing 50 μg ml–1 kanamycin. This culture was grown at 25 °C with shaking at 220 r.p.m. for 48 h without IPTG induction (leaky expression). The cells were pelleted by centrifugation at 4,200 r.p.m. for 15 min at 4 °C and stored at −80 °C.
Frozen cell pellets of KaiCRS and KaiCRS mutants were resuspended into lysate buffer (buffer AC-RS) containing 1× EDTA-free protease inhibitor cocktail (Thermo Fisher Scientific), DNAse I (Sigma Aldrich) and lysozyme (Sigma Aldrich), and the lysate was sonicated for 10–15 min (20 s on, 30 s off, output power less than 40%) on ice followed by centrifugation at 18,000 r.p.m. at 4 °C for 45 min to remove cell debris. The lysate was filtered through a 0.45 μm filter and then loaded on HisTrap HP prepacked Ni-sepharose columns (Cytiva) pre-equilibrated with buffer AC-RS at 0.5 ml min–1. The column was washed with buffer AC-RS at 1 ml min–1 until the UV absorbance returned to baseline. Impurities were then washed with 15% buffer BC-RS, and the protein was eluted with 50% buffer BC-RS. The eluted complex was diluted with 1.5-fold dialysis bufferC-RS then subjected to in-house prepared His-tagged TEV protease (1:10, TEVP:KaiCRS molar ratio) cleavage to remove the His6–MBP tag from KaiCRS (wild-type and mutants) overnight at 4 °C in 6–8 kDa snakeskin dialysis tubing (Thermo Fisher Scientific) that was exchanged against dialysis bufferC-RS. Cleaved KaiCRS was filtered through a 1 μm filter and once again loaded onto HisTrap HP prepacked Ni-sepharose columns at 0.5 ml min–1 to remove His-tagged TEV protease, His6–MBP tag and uncleaved protein. The flow through was concentrated using a Millipore Amicon Ultra-15 centrifugal filter device (10 kDa cut-off) and immediately passed through a HiPrep Sephacryl S-400 HR column (Cytiva) pre-equilibrated with buffer CC-RS. Protein was purified to homogeneity with a single band on Bis-Tris 4–12% gradient SDS–PAGE gel (Genscript) at 62.5 kDa. All protein purification steps were done at 4 °C or on ice. Protein was aliquoted and flash-frozen before storage at −80 °C until further use. The protein concentration was measured using a Microplate BCA Protein Assay kit (Thermo Fisher Scientific) on a SpectraMax MiniMax 300 imaging cytometer using BSA as a standard curve. Typical yields of KaiCRS (wild-type and mutants) were 20–40 mg l–1 of culture.
To test whether the purified KaiCRS had any ATPase contamination, Q-sepharose HP columns (Cytiva) pre-equilibrated with buffer DC-RS was used before the final HiPrep Sephacryl S-400 HR column. The protein was eluted with 5 CV of a linear gradient from 0 to 100% buffer EC-RS. The ATPase activity of the protein samples purified using Q-sepharose HP columns was identical to the samples without this additional purification step. Buffer AC-RS comprised 50 mM Tris-base (pH 7.5), 250 mM NaCl, 10 mM imidazole, 2 mM TCEP, 5 mM MgCl2, 1 mM ATP and 10% glycerol (v/v). Buffer BC-RS comprised 50 mM Tris-base (pH 7.5), 250 mM NaCl, 500 mM imidazole, 2 mM TCEP, 5 mM MgCl2, 1 mM ATP and 10% glycerol (v/v). DialysisC-RS comprised 50 mM Tris-base (pH 7.0), 50 mM NaCl, 2 mM TCEP, 5 mM MgCl2, 1 mM ATP and 10% glycerol (v/v). Buffer CC-RS comprised 50 mM Tris-base (pH 7.0), 50 mM NaCl, 2 mM TCEP, 5 mM MgCl2, 1 mM ATP and 10% glycerol (v/v). Buffer DC-RS comprised50 mM Tris-base (pH 7.0), 2 mM TCEP, 5 mM MgCl2, 1 mM ATP and 10% glycerol (v/v). Buffer EC-RS comprised 50 mM Tris-base (pH 7.0), 1 M NaCl, 2 mM TCEP, 5 mM MgCl2, 1 mM ATP and 10% glycerol (v/v).
The purification of KaiBRS was similar to KaiCRS, but with slight modifications as outlined below. After sonication and centrifugation to remove cell debris, the lysate was filtered through a 0.22 μm filter and then passed through HisTrap HP prepacked Ni Sepharose columns, pre-equilibrated with buffer AB-RS. The column was washed with buffer AB-RS until the UV absorbance returned to baseline. Impurities were washed with 5% buffer BB-RS, and the protein was eluted with 50% buffer BB-RS. The fusion protein was concentrated down to around 30 ml using Amicon stirred cells (Millipore Sigma) with 10 kDa cut-off. In-house prepared His-tagged TEV protease was added, and the fusion protein was cleaved overnight at 4 °C in a 3.5 kDa dialysis cassette that was exchanged against dialysisB-RS buffer. The cleaved KaiBRS was passed through HisTrap HP prepacked Ni-sepharose columns and concentrated down to about 10 ml using a Millipore Amicon Ultra-15 centrifugal filter device (3.5 kDa cut-off). The protein sample was then loaded onto a 26/60 Superdex S75 gel-filtration column (Cytiva) pre-equilibrated with buffer CB-RS at 4 °C. The eluted protein was loaded onto Q-sepharose HP columns pre-equilibrated with buffer DB-RS to remove ATPase contamination. The protein was eluted out in the flow through. A gradient from 0 to 100% buffer EB-RS was passed through Q-sepharose HP columns to ensure that no KaiBRS was bound to the columns. Protein was purified to homogeneity with the single band on Bis-Tris 4–12% gradient SDS–PAGE gels at 10.3 kDa. Protein was aliquoted and flash-frozen before storage at −80 °C until use. The protein concentration was measured using a Microplate BCA Protein Assay kit (Thermo Fisher Scientific) on a SpectraMax MiniMax 300 imaging cytometer using BSA as a standard curve. Typical yields of KaiBRS were 30–40 mg l–1 of culture.
Buffer AB-RS comprised 50 mM Tris-base (pH 7.5), 250 mM NaCl, 10 mM imidazole, 2 mM TCEP and 10% glycerol (v/v). Buffer BB-RS comprised 50 mM Tris-base (pH 7.5), 250 mM NaCl, 500 mM imidazole, 2 mM TCEP and 10% glycerol (v/v). DialysisB-RS comprised 50 mM Tris-base (pH 7.5), 250 mM NaCl, 2 mM TCEP and 10% glycerol (v/v). Buffer CB-RS comprised 50 mM Tris-base (pH 7.5), 50 mM NaCl, 2 mM TCEP and 10% glycerol (v/v). Buffer DB-RS comprised 50 mM Tris-base (pH 7.5), 2 mM TCEP and 10% glycerol (v/v). Buffer EB-RS comprised 50 mM Tris-base (pH 7.5), 1 M NaCl, 2 mM TCEP and 10% glycerol (v/v).
Protein sequences used in this study were identified in a multistep process. In the first step, a selection of sequences was identified using the BLASTP algorithm, utilizing a query based on the protein sequence for KaiC from S. elongatus (GenBank: WP_011242648.1)38. The query was run against NCBI’s non-redundant protein database with the exclusion of models or uncultured and environmental sample sequences. A multiple sequence alignment of the selected 1,538 sequences was generated using MAFFT39,40,41 (Supplementary Dataset 1). This alignment was used as input to generate an initial phylogenetic tree for KaiC with RAxML (v.8.2.9)42 using the PROTGAMMALG model. The generated tree was then used to identify the emergence of KaiB to create the final tree that focused on systems containing either KaiBC or KaiABC. To do so, a BLASTP search was performed for each branch tip with the KaiB sequence from S. elongatus, with the results restricted to the organism at which the branch tip was identified from. The observed branch point of emergence of KaiB agrees well with previous results in which it was shown that KaiB is mainly seen in non-archaea, non-proteobacteria2.
To ensure the best possible sequence coverage, a BLASTP search using KaiB as query (GenBank: WP_011242647.1) was performed. The resulting sequences were then used to identify the organisms that they came from, which allowed us to create a list of organisms with an identified KaiB sequence. This list was then used to select for a subsequent BLASTP search using KaiC as query and therefore to identify only KaiC sequences for organisms that contain both KaiB and KaiC. A spot check was run to confirm that, for example, KaiA was indeed found among all cyanobacteria identified except for Prochlorococcus marinus. The obtained sequences were trimmed down to only include sequences with a sequence homology of 90% or less using CD-HIT43 to arrive at a total of 401 sequences. For the calculation of the phylogenetic tree, RecA from S. elongates was added to serve as the outgroup. Sequences were aligned using MAFFT39,40,41 (Supplementary Dataset 2) with the E-INS-I algorithm44. The multiple sequence alignment was then used as input for the phylogenetic tree calculation with IQ-TREE (v.1.6.beta5), using the LG-substitution matrix45 with the freeRate model (using 10 categories; LG+R10)46,47. To enable determination of branch support, an aBayes test48, a SH-aLRT test (20,000 bootstrap replicates49) and an ultrafast bootstrap (20,000 bootstrap replicates50) were performed (Supplementary Dataset 1; branch supports in order: SH-aLRT support (%)/aBayes support/ultrafast bootstrap support (%)).
KaiCRS and KaiCRS-Δcoil crystals were obtained by sitting-drop vapour diffusion using a 96-well Intelli-Plate (102-0001-00, Art Robbins) at 291 K. Drops contained 0.5 μl crystallization solution, 0.5 μl protein at 10 mg ml–1 in 20 mM MOPS pH 6.5, 50 mM NaCl, 2 mM TCEP, 5 mM MgCl2, 3 mM ATP and 1 mM AMPPCP, and were equilibrated against 50 μl of the solution in the reservoir. The KaiCRS crystallization solution consisted of 200 mM magnesium chloride hexahydrate, 100 mM HEPES pH 7.5 and 30% (w/v) PEG 400. KaiCRS-Δcoil crystals were grown using 200 mM ammonium acetate, 100 mM sodium citrate tribasic dihydrate pH 5.6 and 30% (w/v) PEG 4,000.
The PEG 400 in the KaiCRS crystallization solution acted as a cryoprotectant, whereas KaiCRS-Δcoil crystals were cryoprotected in LV Cryo Oil (MiTeGen). Single crystals were cooled in liquid nitrogen, and X-ray diffraction images were collected at ALS beamline 8.2.1 at 100 K (data collection details are described in Extended Data Table 1). The data were indexed and integrated in iMosflm51, and scaled and merged in Aimless52.
To obtain a structural model of KaiCRS, first the KaiCRS-Δcoil structure was solved by molecular replacement in MRage53 using the KaiCRS sequence (residues 1–490) as input to search for homologues in the PDB database. The initial KaiCRS-Δcoil structure based on the KaiCSE (PDB: 1TF7 (ref. 36)) was manually rebuilt in Coot (v.0.9.81)54 and refined in Phenix (v.1.20.1-4487)55. Finally, the KaiCRS-Δcoil structure was used as the molecular replacement search model in Phaser56 to solve the full-length KaiCRS structure.
The assigned space groups were validated in Zanuda57, and the position of the asymmetric unit in the unit cell was standardized using Achesym58. KaiCRS coiled-coil registers were analysed using SamCC-Turbo (v.0.0.2) with the default socket cut-off value of 7.4 (ref. 59). The images of protein structures were rendered using PyMOL (v.2.6.0)60.
Tunnel detection and calculation were performed using CAVER 3.0.2 PyMOL plugin61, with the minimum probe radius varying between 0.9 and 1.1. Default values were used for all other parameters. All atoms except waters were used in the calculation. The residue selection for starting point consisted of Glu62, Glu63 and ADP602. The catalytic position of the water in the CI domain was modelled from the crystal structure of the transition-state analogue-bound F1-ATPase (PDB: 1w0j, water 2,064 from chain D62).
For preparation of EM grids, 3–4 μl of 4.3 mg ml–1 (per monomer concentration) of sample in 20 mM MOPS pH 6.50, 50 mM NaCl, 2 mM TCEP, 10 mM MgCl2 and 2 mM ATP was applied to glow-discharged 1.2/1.3 400 mesh C-flat carbon-coated copper grids (Protochips). The grids were frozen using a Vitrobot Mark IV (ThermoFisher) at 4 °C and 95% humidity, with a blot time of 4 s. All datasets were collected on a Titan Krios operated at an acceleration voltage of 300 keV, with a GIF quantum energy filter (Gatan) and a GATAN K2 Summit direct electron detector controlled by SerialEM63.
Inspection of the raw cryo-EM images revealed some heterogeneity in the relative orientations between individual hexamers of the dodecameric particles, presumably due to inherent flexibility in the coiled-coil regions, which limited the resolution to 3.3–3.4 Å. To obtain higher resolution reconstructions, the dodecamers were split and processed as individual hexamers, with C6 symmetry being applied throughout processing. To reconstitute the full dodecamer reconstruction, two copies of the hexamer reconstruction were overlaid on top of each other using the ‘fit in map’ function in Chimera64 to fit one hexamer into the lower resolution end density of the other. The overlaid hexamers were then combined, creating a new map in which each voxel takes the value from the hexamer with highest absolute value.
For KaiCRS-S413E/S414E alone, a dataset of approximately 2,500 movies was collected. The movies were recorded with a pixel size of 1.074 Å, including 70 frames and with an exposure rate of 1.31 e− per Å2 per frame. Approximately 825,000 particles were picked, and after 2D classification, around 320,000 particles from good class averages were carried forward for further processing. The final measured resolution of the reconstruction was 2.9 Å (Extended Data Fig. 4a).
For the KaiCRS-S413E/S414E:KaiBRS complex, a dataset of around 2,000 movies was collected. The movies were recorded with a pixel size of 1.023 Å, including 70 frames and with an exposure rate of 1.35 e− per Å2 per frame. About 440,000 particles were picked, and after 2D classification around 190,000 particles from good class averages were carried forward for further processing. The final measured resolution of the reconstruction was 2.7 Å (Extended Data Fig. 4b).
All data processing was carried out using cisTEM (v.2.0.0)65, and followed the workflow of motion correction, CTF parameter estimation, particle picking, 2D classification, ab initio 3D map generation, 3D refinement, 3D classification, per-particle CTF refinement and B-factor sharpening. The highest resolution of 3D refinement used was 4 Å for both reconstructions, and final resolutions were estimated using the cisTEM PartFSC and a threshold of 0.143.
To validate the combined dodecamer structure, we also processed both datasets as full D6 symmetric dodecamers (Extended Data Fig. 4c,d). This was accomplished by extracting the picked hexamers into a large box size and performing 2D classification with automatic centring. Clear dodecamer class averages were then selected and re-extracted from the original images, with picking coordinates that were adjusted by the translation required to match the centred class average. After this centring, duplicate picks were removed to obtain the final dodecamer particle stacks. These stacks were processed as described above, with the highest resolution of 3D refinement used as 4.25 Å.
In an attempt to find deviations from D6 symmetry, we also calculated reconstructions for both structures assuming C1 symmetry, starting from the ab initio 3D step. The resulting refined C1 structures did not exhibit detectable departures from D6 symmetry (Extended Data Fig. 4e). We therefore present symmetrized volumes as our final result.
The cryo-EM structures were built using the KaiCRS model obtained by X-ray crystallography and fold-switch-stabilized KaiBTE (PDB: 5JWO (ref. 26)) as starting points. The models were constructed using Coot (v.0.9.81)54, and refinement was carried out using Phenix (v.1.20.1-4487)55.
Purified KaiCRS (about 20 μM) from −80 °C was dialysed in 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP, 10 mM MgCl2 and 0.1 mM ADP overnight at 4 °C to remove glycerol and to replace ATP with ADP. The dialysed KaiCRS was then heated at 30 °C for 4 h to obtain fully unphosphorylated KaiCRS bound with ADP, and the sample was then passed through 0.22 μm Spin-X centrifuge tube filters (Corning). The sample was concentrated to a higher concentration (less than 100 μM) at 4 °C. The protein concentration was measured using a BCA assay.
Unphosphorylated KaiCRS (3.5 μM, prepared as described above) in the presence or absence of KaiBRS (3.5 μM and 35 μM) was preincubated at 20, 25, 30 and 35 °C for 1 h in 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP, 10 mM MgCl2 and 0.1 mM ADP. The reactions were started by adding 3.9 mM ATP to obtain a final concentration of 4 mM nucleotide in the presence of 2 U ml–1 pyruvate kinase (Millipore Sigma) and 10 mM phosphoenolpyruvate (Millipore Sigma) to regenerate ATP during the reaction. The reaction samples were sampled by hand at specific time points and mixed with an equal amount of loading dye (stock concentration of 0.1 M Tris-base (pH 7.5), 4% SDS, 0.2% bromophenol blue, 30% glycerol and 0.5 M 2-mercaptoethanol). The mixed samples were then stored at −20 °C until further use.
Purified KaiCRS (around 20 μM) was dialysed in reaction buffer containing 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP, 10 mM MgCl2 and 0.1 mM ADP overnight at 4 °C to remove glycerol and to generate KaiCRS bound with ADP. After dialysis at 4 °C, KaiCRS exists in two states: 50% unphosphorylated and 50% single phosphorylated at Ser413 (pSer413), which were confirmed by tandem mass spectrometry (data not shown). The autodephosphorylation reaction was started by adding KaiCRS or KaiCRS in the presence of KaiBRS (3.5 μM) into reaction buffer pre-equilibrated at 30 °C.
Dialysed KaiCRS (3.5 μM) was preincubated at 35 °C for 30 min in 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP, 10 mM MgCl2 and 0.1 mM ADP in the presence or absence of KaiBRS (3.5 μM). The reactions were started by adding 4 mM ATP and reaction samples were collected at specific time points for 10% SDS–PAGE and HPLC analysis to identify phosphorylation state of KaiCRS and amount of nucleotide at each time point, respectively.
KaiCRS was dialysed in reaction buffer containing 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP, 10 mM MgCl2 and 1 mM ATP overnight at 4 °C. To start the reaction as shown in Fig. 3c, KaiCRS (3.5 μM) in the absence or presence of KaiBRS (3.5 μM) was mixed with additional ATP (final 4 mM to mimic daytime), and the reaction samples (500 μl) were added into a D-Tube Dialyzer (midi 3.5 kDa cut-off, EMD Millipore) that was exchanged against 4 mM ATP buffer (400 ml). After the 12-h time point, the reaction samples were transferred into preincubated 25% ATP/ADP buffer (400 ml) that mimics the night time. After the 24-h time point, the same samples were changed into preincubated 4 mM ATP to mimic the daytime again.
To start the experiment as shown in Extended Data Fig. 6a, KaiCRS (35 μM) in the presence of 3 mM ATP in 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP and 10 mM MgCl2 was heated at 35 °C for 25 min to generate fully phosphorylated KaiCRS. The KaiCRS sample was then diluted 10-fold into 25% ATP/ADP buffer pre-equilibrated at 30 °C to final concentration of KaiCRS (3.5 μM) and KaiBRS (3.5 μM or 35 μM). The reaction samples (300 μl) were added into a D-Tube Dialyzer (midi 3.5 kDa cut-off, EMD Millipore) that was exchanged against 25% ATP/ADP buffer (300 ml).
During the reaction, the samples were gently shaken in a 30 °C incubator, and reaction samples were collected at specific time points for 10% SDS–PAGE and HPLC analysis to identify the phosphorylation state of KaiCRS and the amount of nucleotide at each time point, respectively.
The rationale for the ATP-to-ADP ratio at daytime and night time comes from two earlier literature reports. The change in ATP-to-ADP ratio at daytime and night time were directly measured in vivo in the strain R. sphaeroides27, in which ATP is 2.0–2.4 mM during day and drops to 0.5–0.6 during night, and it is well known that the total nucleotide concentration stays constant. We chose the total nucleotide concentration of 4 mM in our in vitro work to be identical to the described in vitro experiments performed for the canonical KaiCSE. Because of photosynthesis in daylight, virtually all nucleotide is ATP33. We note that a slightly higher amount of ATP will not affect our results, as the affinity of KaiCRS for ATP is higher than for ADP.
Unphosphorylated, single phosphorylated and double phosphorylated KaiCRS were separated by 10% SDS–PAGE with 37.5:1 acrylamide:bis-acrylamide (Bio-Rad), 18 cm × 16 cm × 1 mm Tris-HCl gel with 1× Tris-glycine SDS running buffer (Invitrogen). The samples were heated at 95 °C for 3 min, and 400 ng of material was loaded onto the Tris-HCl gel. The gel was run with a constant current of 35 mA, 150 W, and the voltage was greater than 700 V for 5.5 h in a cold room, with a water bath set to 12 °C using a Hoefer SE600 electrophoresis unit.
Unphosphorylated and phosphorylated KaiCRS-Δcoil were separated by Zn2+ Phos-tag SDS–PAGE with 10% acrylamide gel containing 50 μM Phos-tag acrylamide (Wako). The gel was run with a constant current of 30 mA for 5 h 30 min in a cold-room, with 1 μg per well protein samples pre-heated at 95 °C for 3 min.
The gels were stained overnight at room temperature with InstantBlue protein gel stain (Expedeon) with gentle shaking and destained with distilled water until bands were clearly visible. The gels were imaged on a ChemiDoc Imager (Bio-Rad), and Image Lab software (Bio-Rad) was used for analysis.
Data shown in main text figures and Extended Data figures are representative SDS–PAGE gels for at least three independent biological replicates (n = 3), except for experiments presented in Fig. 3a,c, which were performed in duplicate.
KaiCRS, unphosphorylated KaiCRS and all KaiCRS mutants with a concentration of around 40–80 μM were loaded with a flow rate of 0.2 ml min–1 onto a prepacked Superdex-200 10/300 GL (GE Healthcare) pre-equilibrated with 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP, 10 mM MgCl2 and 1 mM ATP (0.1 mM ADP for unphosphorylated KaiCRS) at 4 °C using an ÄKTA Pure system (GE Healthcare). KaiBRS (0.5 mM) was loaded onto Superdex-75 10/300 GL (GE Healthcare) pre-equilibrated with 20 mM MOPS (pH 6.5), 50 mM NaCl and 2 mM TCEP at 4 °C. The eluate was collected in fractions of 1 ml each and subjected to SDS–PAGE analysis. A standard curve (that is, molecular weight versus elution time) was determined for the column using molecular weight protein standards (Bio-Rad) run in the same buffer and flow rate. The protein standard mixture contained thyroglobulin (670 kDa), γ-globulin (158 kDa), ovalbumin (44 kDa), myoglobin (17 kDa) and vitamin B12 (1.35 kDa).
Sedimentation velocity centrifugation experiments were run at 50,000 r.p.m. (for KaiBRS) and 30,000 r.p.m. (for KaiCRS wild-type and mutants and KaiCSE), with continuous scans from 5.8 to 7.3 cm at 0.005 cm intervals at 20 °C on a Beckman Optima XL-A (Beckman-Coulter) equipped with absorption optics and a four-hole An60Ti rotor. Measurements were set up at 280 nm (for KaiBRS) and 295 nm (for KaiCRS and KaiCSE) to avoid interference from ATP. The software package SEDFIT (v.14.1) was used for data evaluation66. KaiCRS and KaiCRS-Δcoil (100 μM) were prepared in 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP, 10 mM MgCl2 and 1 mM ATP. KaiCSE (100 μM) was prepared in 20 mM MOPS (pH 8.0), 150 mM NaCl, 2 mM TCEP, 5 mM MgCl2, and 1 mM ATP. KaiBRS (500 μM) was prepared in 20 mM MOPS (pH 6.5), 50 mM NaCl and 2 mM TCEP.
Purified KaiCRS (both wild-type and mutant forms (around 20 μM)) and KaiBRS (about 90 μM) were dialysed in 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP, 10 mM MgCl2 and 1 mM ATP (reaction buffer) overnight at 4 °C. The samples were passed through 0.22 μm Spin-X centrifuge tube filters, and concentrations were measured using a BCA assay before setting up the reactions. Typical KaiCRS or KaiBCRS reactions contained 3.5 μM KaiCRS (wild type and mutants) and 3.5 μM KaiBRS in reaction buffer with a final concentration of 4 mM ATP. The samples were incubated at the indicated temperatures and were sampled by hand at specific time points. Next 10 μl of sample was quenched with 10 μl of 10% trichloroacetic acid (Millipore Sigma), and the mixture was passed through a 0.22 μm Spin-X centrifuge tube filter to remove the precipitated protein. The flow through sample was then re-adjusted to pH 6.2 for nucleotide separation by adding 10 μl of 0.75 M HEPES, pH 8.0. The final samples were kept at −20 °C until HPLC analysis.
Three microlitres of each sample were injected with a high-precision autosampler (injection error of <0.1 μl, resulting in a maximum systemic error of about 6%) to a reverse-phase HPLC instrument with an ACE 5 μm particle size, C18-AR and 100 Å pore size column (Advanced Chromatography Technologies). The instrument was pre-equilibrated with 100 mM potassium phosphate pH 6.2 with a flow rate of 0.4 ml min–1. Using pure nucleotide samples, the retention times of ATP, ADP and AMP were determined to be 2.6, 3.1 and 4.4 min, respectively. The concentration of each nucleotide was calculated from the relative ratio of the peak areas and the total nucleotide concentration. To determine ATPase activity rates, the observed rate constants were determined from at least five data points for each temperature using initial rate analysis and least-squares linear regression (Extended Data Figs. 6c,d and 8b–d). The mean values and uncertainties (s.d.) shown in Fig. 3d, Extended Data Figs. 6 and 8 were derived from three replicate experiments. KaleidaGraph (v.4.5.3; Synergy) was used for data analysis and plotting.
KaiCRS (wild type or mutants) and KaiBRS were dialysed into 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP, 10 mM MgCl2 and 50 μM ATP overnight at 4 °C. The samples were passed through 0.22 μm Spin-X centrifuge tube filters, and the protein concentration was measured using a BCA assay. The reaction contained 3.5 μM of KaiCRS-S413E and/or 35 μM of KaiBRS, and samples were incubated at 20, 25, 30 and 35 °C for 16–24 h in the presence of an ATP-recycling system. The reactions were started by adding 250 μM of mant-ATP (Jena Bioscience). The spectrum was measured using the fluorescence energy transfer from tryptophan residues in KaiCRS to mant-ATP by exciting the sample at 290 nm (2.5 nm bandwidth) and collecting the emission intensity from 320 nm to 550 nm (5 nm bandwidth) in increments of 2 nm. To measure the nucleotide exchange rate, the maximum change in fluorescence intensity at 440 nm (ΔF440 nm) was followed for a total time of 1,800 s in 15 s increments with anti-photobleaching mode on FluoroMax-4 spectrofluorometer (Horiba Scientific) equipped with a water bath to control the temperature. There are two tryptophan residues within 5 Å from the nucleotide-binding site in the KaiCIIRS domain and no tryptophan residue close to the nucleotide-binding site in the KaiCIRS domain, so the nucleotide exchange observed in the experiments are for the KaiCIIRS domain. To ensure that the exchange rate observed in the experiments are from nucleotide exchange in the KaiCIIRS domain, KaiCIRS (which only contains the CI domain) was tested; no change in fluorescence was observed following the addition of mant-ATP (Extended Data Fig. 8h).
The experiments for KaiCSE alone and with KaiCSE mixed in and for KaiASE were performed in a similar way, except that KaiCSE and KaiASE were dialysed in 20 mM MOPS (pH 8.0), 150 mM NaCl, 2mM TCEP, 10 mM MgCl2 and 50 μM ATP overnight at 4 °C. KaiASE was incubated with KaiCSE for 1 h at 30 °C before adding 250 μM mant-ATP.
For the nucleotide preference experiment, KaiCRS-S413E/S414E and KaiCRS-S413A/S414A were dialysed in 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP, 10 mM MgCl2 and 20 μM ADP overnight at 4 °C. KaiCRS-S413E/S414E or KaiCRS-S413A/S414A (3.5 μM) was first mixed with mant-ATPγS or mant-ADP (150 μM), and the kinetic trace at 440 nm was recorded at 30 °C. After the fluorescence trace at 440 nm reached a plateau, which indicates that the nucleotide analogue was fully bound to the protein, a 27-fold excess of ATP (4 mM) was added to displace the bound nucleotide analogue, and the decay of fluorescence intensity was recorded at 440 nm at 30 °C. The experiments were run in triplicate, and results were averaged and fitted to a single exponential decay.
Analysis was performed by fitting individual traces to an exponential equation using KinTek Explorer software67,68], and error bars denote the standard errors as obtained from triplicate experiments. KaleidaGraph (v.4.5.3; Synergy) was used for data plotting.
32P-labelled KaiCRS was prepared by mixing unphosphorylated KaiCRS (10 μM) with 0.46 μM [γ-32P]ATP (3,000 Ci mmol–1, PerkinElmer) and 500 μM ATP in 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP and 10 mM MgCl2 at 35 °C for 30 min and then immediately switched to 4 °C to prevent dephosphorylation of KaiCRS. The 32P-labelled KaiCRS sample was passed through Zeba spin desalting columns (Thermo Fisher Scientific) pre-equilibrated with 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP and 10 mM MgCl2 twice at 4 °C. The sample was incubated with buffer containing 1 mM ADP overnight at 4 °C to obtain 32P-labelled KaiCRS bound with ADP. The sample was passed through a final Zeba desalting column pre-equilibrated with 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP and 10 mM MgCl2 at 4 °C, and the solution was then incubated with 8 mM ADP in the presence or absence of KaiBRS at 4 °C for 1 h. The samples were then diluted in 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP and 10 mM MgCl2 preincubated at 30 °C to obtain a final concentration of 32P-labelled KaiCRS (5 μM), KaiBRS (20 μM) and ADP (4 mM). The reactions were incubated at 30 °C, and at different time points, aliquots were taken (1.5 μl). The reactions were stopped by adding 1.5 μl Laemmli sample buffer (62.5 mM Tris (pH 6.8), 2% SDS, 25% glycerol and 0.01% bromophenol blue) supplemented with 5% (v/v) 2-mercaptoethanol.
The samples were spotted onto a TLC plate (PEI-cellulose F plates, Merck) and quickly dried with a blow-dryer for 30 s. The TLC plates were run first with distilled water as a mobile phase. After TLC plates were completely dried, 0.75 M KH2PO4 was used as the mobile phase to separate 32P-labelled KaiCRS, [γ-32P]ATP and inorganic phosphate (32P), as previously shown29. The phosphor-screens were scanned on an Amersham Typhoon (GE Healthcare) at a resolution of 100 μm. ImageQuant TL 7.0 software was used for analysis.
Fluorescence anisotropy competition experiments were carried out using a FluoroMax-4 spectrofluorometer (Horiba Scientific) at 30 °C. Excitation and emission wavelengths for KaiBRS labelled with 6-iodoacetamidofluorescein (6-IAF, Thermo Fisher Scientific) at Cys29 were set at 492 nm (5 nm bandwidth) and 520 nm (5 nm bandwidth), respectively, with fixed G factor (G factor of KaiBRS–6IAF alone) to eliminate instrumental bias. The average anisotropy and standard error were calculated from ten replicate measurements.
KaiBRS–6IAF was prepared by mixing degassed KaiBRS (100 μM) with 20-fold excess of 6-IAF (stock 10 mM in 50% DMSO) in 20 mM Tris-base (pH 7.0), 50 mM NaCl and 1 mM TCEP (degassed). The reaction was incubated at room temperature for 4 h and dialysed against 20 mM Tris-base (pH 7.0), 50 mM NaCl and 1 mM TCEP in a 3.5 kDa dialysis cassette overnight at 4 °C to remove unreacted 6-IAF and small amounts of DMSO. The crosslinked sample was passed through a 0.22 μm Spin-X centrifuge tube filter and loaded onto Superdex-75 10/300 GL pre-equilibrated with 20 mM MOPS (pH 7.0), 50 mM NaCl and 1 mM TCEP with a 0.2 ml min–1 flow rate to remove leftover unreacted 6-IAF. The sample was aliquoted and flash-frozen in liquid nitrogen and stored at −80 °C until use. All the crosslinked reactions were performed in the dark.
For the fluorescence anisotropy competitive binding experiment, KaiBRS–6IAF (0.2–0.4 μM) was first incubated with wild-type or mutant KaiCRS (1 μM, 60% increase in anisotropy in comparison to KaiBRS–6IAF alone) in 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP and 10 mM MgCl2 in the presence of 4 mM ADP or 4 mM ATP with an ATP-recycling system (2 U ml–1 pyruvate kinase and 10 mM phosphoenolpyruvate), then unlabelled KaiBRS (0–50 μM) was added to the samples. The samples were incubated at 30 °C for 4 h or 12 h before measurement.
The decrease in fluorescence anisotropy (FA) versus concentration of unlabelled KaiBRS was fitted to equation (1) using the Levenberg–Marquardt nonlinear fitting algorithm included in KaleidaGraph (Synergy Software) to obtain the half-maximum inhibitory concentration (IC50) value. The Kd value can then be calculated from the IC50 value using equation (2) as previously described69.
Pull-down assays probe the interaction between KaiCRS (wild type and mutants) with KaiBRS (His6-MBP-TEV-KaiBRS). The His6-MBP-TEV-KaiBRS was expressed and purified as described above but without the TEV protease cleavage step. Wild-type or mutant KaiCRS (3.5 μM) was mixed with KaiBRS-tag (3.5 μM) in 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP and 10 mM MgCl2 in the presence of 4 mM ADP or 4 mM ATP with an ATP-recycling system in a final volume of 400 μl. The samples were incubated at 25 °C for 4 h or 24 h before loading onto a 500 μl spin column with 200 μl (prepared from 400 μl of 50% slurry) Talon beads (Takara) pre-equilibrated with sample buffer. The samples were incubated with the Talon beads for 30 min with gentle shaking, after which the flow through was collected by gravity into 1 ml Eppendorf tubes. The beads were washed three times with 400 μl sample buffer by gravity, then the samples were eluted with 200 μl of 0.5 M imidazole buffer by centrifugation at 1,000g for 1 min. The protein mixture, flow through, wash and eluted samples were run on a Bis-Tris 4–12% gradient SDS–PAGE gel with a molecular weight marker. The gels were stained with Coomassie blue and were imaged on a ChemiDoc Imager (Bio-Rad). Image Lab Software (Bio-Rad) was used for analysis.
The following control experiments were performed: (1) fusion KaiBRS protein in the absence of KaiCRS; and (2) KaiCRS in the absence of fusion KaiBRS. All the fusion KaiBRS proteins came out only in the elution buffer in the first control experiment, which indicated that fusion KaiBRS binds to Talon beads and the amount of KaiBRS used did not overload the column. All KaiCRS protein came out in the flow through in the second control experiment, which indicated there is no specific binding between KaiCRS and the Talon beads.
KaiCRS and SYPRO Orange (Thermo Fisher Scientific) were used at final concentration of 3 μM and 10×, respectively. The experiments were carried out in 20 mM MOPS (pH 6.5), 50 mM NaCl, 2 mM TCEP, 10 mM MgCl2 and 4 mM ADP or ATP. The samples were prepared to a final volume of 20 μl in a MicroAmp Fast Optical 96-well reaction plate (Applied Biosystems Life Technologies), and the plate was sealed with Axygen UltraClear sealing film (Corning). The assay plate was run in a StepOne Real-Time PCR instrument (Applied Biosystems Life Technologies) with melt curve set up. The temperature was continuously increased from 25 °C to 95 °C by 0.3 °C every 15 s. The data were fit with nonlinear fitting in KaleidaGraph (Synergy Software) to a Boltzmann sigmoidal curve (equation (3)).
where Y is the fluorescence intensity at temperature T, T is the temperature in degrees Celsius, Bottom is the baseline fluorescence at low temperature, Top is the maximum fluorescence at the top of the truncated data, c is the slope or steepness of the curve, and Tm is the melting temperature of the protein.
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
Structure factors and refined models obtained using X-ray crystallography have been deposited into PDB under accession codes 8DBA (wild-type KaiCRS) and 8DB3 (KaiCRS-∆coil). Cryo-EM maps and refined models have been deposited into the Electron Microscopy Data Bank (EMDB) and PDB, respectively. The composite map and model for the KaiCRS-S413E/S414E dodecamer reconstruction are submitted under entries EMD-29505 and 8FWI, respectively. The composite map and model for the KaiCRS-S413E/S414E–KaiBRS dodecamer reconstruction are submitted under entries EMD-29506 and 8FWJ, respectively. The focused KaiCRS-S413E/S414E hexamer refinement map is available under accession EMD-29507 and the focused KaiCRS-S413E/S414E–KaiBRS hexamer refinement map is available under accession EMD-29508. The full KaiCRS-S413E/S414E dodecamer refinement is available under accession EMD-29509 and the full KaiCRS-S413E/S414E–KaiBRS dodecamer refinement is available under accession EMD-29510. Other datasets used are all publicly available in public community or discipline-specific repositories (for example, PDB identifiers 5JWQ, 1W0J, 1TF7 and 7S65). The accession codes for protein sequences, sequence alignments and phylogeny are listed in Supplementary Datasets 1 and 2.
Ishiura, M. et al. Expression of a gene cluster kaiABC as a circadian feedback process in cyanobacteria. Science 281, 1519–1523 (1998).
Article ADS CAS PubMed Google Scholar
Dvornyk, V., Vinogradova, O. & Nevo, E. Origin and evolution of circadian clock genes in prokaryotes. Proc. Natl Acad. Sci. USA 100, 2495–2500 (2003).
Article ADS CAS PubMed PubMed Central Google Scholar
Cohen, S. E. & Golden, S. S. Circadian rhythms in cyanobacteria. Microbiol. Mol. Biol. Rev. 79, 373–385 (2015).
Article CAS PubMed PubMed Central Google Scholar
Golden, S. S. Principles of rhythmicity emerging from cyanobacteria. Eur. J. Neurosci. 51, 13–18 (2020).
Article PubMed Google Scholar
Partch, C. L. Orchestration of circadian timing by macromolecular protein assemblies. J. Mol. Biol. 432, 3426–3448 (2020).
Article CAS PubMed PubMed Central Google Scholar
Rust, M. J., Markson, J. S., Lane, W. S., Fisher, D. S. & O’Shea, E. K. Ordered phosphorylation governs oscillation of a three-protein circadian clock. Science 318, 809–812 (2007).
Article ADS CAS PubMed PubMed Central Google Scholar
Holtzendorff, J. et al. Genome streamlining results in loss of robustness of the circadian clock in the marine cyanobacterium Prochlorococcus marinus PCC 9511. J. Biol. Rhythms 23, 187–199 (2008).
Article CAS PubMed Google Scholar
Axmann, I. M. et al. Biochemical evidence for a timing mechanism in Prochlorococcus. J. Bacteriol. 191, 5342–5347 (2009).
Article CAS PubMed PubMed Central Google Scholar
Ma, P., Mori, T., Zhao, C., Thiel, T. & Johnson, C. H. Evolution of KaiC-dependent timekeepers: a proto-circadian timing mechanism confers adaptive fitness in the purple bacterium Rhodopseudomonas palustris. PLoS Genet. 12, e1005922 (2016).
Article PubMed PubMed Central Google Scholar
Dvornyk, V. & Knudsen, B. Functional divergence of the circadian clock proteins in prokaryotes. Genetica 124, 247–254 (2005).
Article PubMed Google Scholar
Min, H., Guo, H. & Xiong, J. Rhythmic gene expression in a purple photosynthetic bacterium, Rhodobacter sphaeroides. FEBS Lett. 579, 808–812 (2005).
Article CAS PubMed Google Scholar
Carter, A. P. et al. Structure and functional role of dynein’s microtubule-binding domain. Science 322, 1691–1695 (2008).
Article ADS CAS PubMed PubMed Central Google Scholar
Schmelling, N. M. et al. Minimal tool set for a prokaryotic circadian clock. BMC Evol. Biol. 17, 169 (2017).
Article PubMed PubMed Central Google Scholar
Aoki, S. & Onai, K. in Bacterial Circadian Programs (eds Mackey S. R. Ditty J. L. & Johnson C. H.) 259–282 (Springer, 2009).
Wiegard, A. et al. Biochemical analysis of three putative KaiC clock proteins from Synechocystis sp PCC 6803 suggests their functional divergence. Microbiology 159, 948–958 (2013).
Article CAS PubMed Google Scholar
Pattanayek, R. et al. Analysis of KaiA–KaiC protein interactions in the cyano-bacterial circadian clock using hybrid structural methods. EMBO J. 25, 2017–2028 (2006).
Article CAS PubMed PubMed Central Google Scholar
Nishiwaki-Ohkawa, T., Kitayama, Y., Ochiai, E. & Kondo, T. Exchange of ADP with ATP in the CII ATPase domain promotes autophosphorylation of cyanobacterial clock protein KaiC. Proc. Natl Acad. Sci. USA 111, 4455–4460 (2014).
Article ADS CAS PubMed PubMed Central Google Scholar
Kim, Y. I., Dong, G., Carruthers, C. W. Jr., Golden, S. S. & LiWang, A. The day/night switch in KaiC, a central oscillator component of the circadian clock of cyanobacteria. Proc. Natl Acad. Sci. USA 105, 12825–12830 (2008).
Article ADS CAS PubMed PubMed Central Google Scholar
Swan, J. A. et al. Coupling of distant ATPase domains in the circadian clock protein KaiC. Nat. Struct. Mol. Biol. 29, 759–766 (2022).
Article CAS PubMed PubMed Central Google Scholar
Egli, M. et al. Loop–loop interactions regulate KaiA-stimulated KaiC phosphorylation in the cyanobacterial KaiABC circadian clock. Biochemistry 52, 1208–1220 (2013).
Article CAS PubMed Google Scholar
Hayashi, F. et al. ATP-induced hexameric ring structure of the cyanobacterial circadian clock protein KaiC. Genes Cells 8, 287–296 (2003).
Article CAS PubMed Google Scholar
Nishiwaki, T. et al. Role of KaiC phosphorylation in the circadian clock system of Synechococcus elongatus PCC 7942. Proc. Natl Acad. Sci. USA 101, 13927–13932 (2004).
Article ADS CAS PubMed PubMed Central Google Scholar
Xu, Y. et al. Identification of key phosphorylation sites in the circadian clock protein KaiC by crystallographic and mutagenetic analyses. Proc. Natl Acad. Sci. USA 101, 13933–13938 (2004).
Article ADS CAS PubMed PubMed Central Google Scholar
Kitayama, Y., Iwasaki, H., Nishiwaki, T. & Kondo, T. KaiB functions as an attenuator of KaiC phosphorylation in the cyanobacterial circadian clock system. EMBO J. 22, 2127–2134 (2003).
Article CAS PubMed PubMed Central Google Scholar
Chang, Y. G. et al. Circadian rhythms. A protein fold switch joins the circadian oscillator to clock output in cyanobacteria. Science 349, 324–328 (2015).
Article ADS CAS PubMed PubMed Central Google Scholar
Tseng, R. et al. Structural basis of the day–night transition in a bacterial circadian clock. Science 355, 1174–1180 (2017).
Article ADS CAS PubMed PubMed Central Google Scholar
Abee, T., Hellingwerf, K. J. & Konings, W. N. Effects of potassium ions on proton motive force in Rhodobacter sphaeroides. J. Bacteriol. 170, 5647–5653 (1988).
Article CAS PubMed PubMed Central Google Scholar
Terauchi, K. et al. ATPase activity of KaiC determines the basic timing for circadian clock of cyanobacteria. Proc. Natl Acad. Sci. USA 104, 16377–16381 (2007).
Article ADS CAS PubMed PubMed Central Google Scholar
Nishiwaki, T. & Kondo, T. Circadian autodephosphorylation of cyanobacterial clock protein KaiC occurs via formation of ATP as intermediate. J. Biol. Chem. 287, 18030–18035 (2012).
Article CAS PubMed PubMed Central Google Scholar
Phong, C., Markson, J. S., Wilhoite, C. M. & Rust, M. J. Robust and tunable circadian rhythms from differentially sensitive catalytic domains. Proc. Natl Acad. Sci. USA 110, 1124–1129 (2013).
Article ADS CAS PubMed Google Scholar
Murakami, R. et al. Cooperative binding of KaiB to the KaiC hexamer ensures accurate circadian clock oscillation in cyanobacteria. Int. J. Mol. Sci. 20, 4550 (2019).
Article CAS PubMed PubMed Central Google Scholar
Snijder, J. et al. Insight into cyanobacterial circadian timing from structural details of the KaiB–KaiC interaction. Proc. Natl Acad. Sci. USA 111, 1379–1384 (2014).
Article ADS CAS PubMed PubMed Central Google Scholar
Rust, M. J., Golden, S. S. & O’Shea, E. K. Light-driven changes in energy metabolism directly entrain the cyanobacterial circadian oscillator. Science 331, 220–223 (2011).
Article ADS CAS PubMed PubMed Central Google Scholar
Truebestein, L. & Leonard, T. A. Coiled-coils: the long and short of it. Bioessays 38, 903–916 (2016).
Article CAS PubMed PubMed Central Google Scholar
Liu, J. & Rost, B. Comparing function and structure between entire proteomes. Protein Sci. 10, 1970–1979 (2001).
Article CAS PubMed PubMed Central Google Scholar
Pattanayek, R. et al. Visualizing a circadian clock protein: crystal structure of KaiC and functional insights. Mol. Cell 15, 375–388 (2004).
Article CAS PubMed Google Scholar
Krissinel, E. & Henrick, K. Inference of macromolecular assemblies from crystalline state. J. Mol. Biol. 372, 774–797 (2007).
Article CAS PubMed Google Scholar
Altschul, S. F., Gish, W., Miller, W., Myers, E. W. & Lipman, D. J. Basic local alignment search tool. J. Mol. Biol. 215, 403–410 (1990).
Article CAS PubMed Google Scholar
Katoh, K., Misawa, K., Kuma, K. & Miyata, T. MAFFT: a novel method for rapid multiple sequence alignment based on fast Fourier transform. Nucleic Acids Res. 30, 3059–3066 (2002).
Article CAS PubMed PubMed Central Google Scholar
Katoh, K. & Standley, D. M. MAFFT multiple sequence alignment software version 7: improvements in performance and usability. Mol. Biol. Evol. 30, 772–780 (2013).
Article CAS PubMed PubMed Central Google Scholar
Katoh, K. & Toh, H. Parallelization of the MAFFT multiple sequence alignment program. Bioinformatics 26, 1899–1900 (2010).
Article CAS PubMed PubMed Central Google Scholar
Stamatakis, A. RAxML version 8: a tool for phylogenetic analysis and post-analysis of large phylogenies. Bioinformatics 30, 1312–1313 (2014).
Article CAS PubMed PubMed Central Google Scholar
Fu, L., Niu, B., Zhu, Z., Wu, S. & Li, W. CD-HIT: accelerated for clustering the next-generation sequencing data. Bioinformatics 28, 3150–3152 (2012).
Article CAS PubMed PubMed Central Google Scholar
Katoh, K., Kuma, K., Toh, H. & Miyata, T. MAFFT version 5: improvement in accuracy of multiple sequence alignment. Nucleic Acids Res. 33, 511–518 (2005).
Article CAS PubMed PubMed Central Google Scholar
Le, S. Q. & Gascuel, O. An improved general amino acid replacement matrix. Mol. Biol. Evol. 25, 1307–1320 (2008).
Article CAS PubMed Google Scholar
Soubrier, J. et al. The influence of rate heterogeneity among sites on the time dependence of molecular rates. Mol. Biol. Evol. 29, 3345–3358 (2012).
Article CAS PubMed Google Scholar
Yang, Z. A space–time process model for the evolution of DNA sequences. Genetics 139, 993–1005 (1995).
Article CAS PubMed PubMed Central Google Scholar
Anisimova, M., Gil, M., Dufayard, J. F., Dessimoz, C. & Gascuel, O. Survey of branch support methods demonstrates accuracy, power, and robustness of fast likelihood-based approximation schemes. Syst. Biol. 60, 685–699 (2011).
Article PubMed PubMed Central Google Scholar
Guindon, S. et al. New algorithms and methods to estimate maximum-likelihood phylogenies: assessing the performance of PhyML 3.0. Syst. Biol. 59, 307–321 (2010).
Article CAS PubMed Google Scholar
Minh, B. Q., Nguyen, M. A. & von Haeseler, A. Ultrafast approximation for phylogenetic bootstrap. Mol. Biol. Evol. 30, 1188–1195 (2013).
Article CAS PubMed PubMed Central Google Scholar
Battye, T. G., Kontogiannis, L., Johnson, O., Powell, H. R. & Leslie, A. G. iMOSFLM: a new graphical interface for diffraction-image processing with MOSFLM. Acta Crystallogr. D 67, 271–281 (2011).
Evans, P. R. & Murshudov, G. N. How good are my data and what is the resolution? Acta Crystallogr. D 69, 1204–1214 (2013).
Bunkoczi, G. et al. Phaser.MRage: automated molecular replacement. Acta Crystallogr. D 69, 2276–2286 (2013).
Emsley, P., Lohkamp, B., Scott, W. G. & Cowtan, K. Features and development of Coot. Acta Crystallogr. D 66, 486–501 (2010).
Liebschner, D. et al. Macromolecular structure determination using X-rays, neutrons and electrons: recent developments in Phenix. Acta Crystallogr. D 75, 861–877 (2019).
McCoy, A. J. et al. Phaser crystallographic software. J. Appl. Crystallogr. 40, 658–674 (2007).
Article CAS PubMed PubMed Central Google Scholar
Lebedev, A. A. & Isupov, M. N. Space-group and origin ambiguity in macromolecular structures with pseudo-symmetry and its treatment with the program Zanuda. Acta Crystallogr. D 70, 2430–2443 (2014).
Kowiel, M., Jaskolski, M. & Dauter, Z. ACHESYM: an algorithm and server for standardized placement of macromolecular models in the unit cell. Acta Crystallogr. D 70, 3290–3298 (2014).
Szczepaniak, K., Bukala, A., da Silva Neto, A. M., Ludwiczak, J. & Dunin-Horkawicz, S. A library of coiled-coil domains: from regular bundles to peculiar twists. Bioinformatics 36, 5368–5376 (2020).
Article CAS PubMed PubMed Central Google Scholar
The PyMOL Molecular Graphics System, version 2.4 (Schrödinger, 2020).
Chovancova, E. et al. CAVER 3.0: a tool for the analysis of transport pathways in dynamic protein structures. PLoS Comput. Biol. 8, e1002708 (2012).
Article CAS PubMed PubMed Central Google Scholar
Kagawa, R., Montgomery, M. G., Braig, K., Leslie, A. G. & Walker, J. E. The structure of bovine F1-ATPase inhibited by ADP and beryllium fluoride. EMBO J. 23, 2734–2744 (2004).
Article CAS PubMed PubMed Central Google Scholar
Mastronarde, D. N. Automated electron microscope tomography using robust prediction of specimen movements. J. Struct. Biol. 152, 36–51 (2005).
Article PubMed Google Scholar
Pettersen, E. F. et al. UCSF Chimera—a visualization system for exploratory research and analysis. J. Comput. Chem. 25, 1605–1612 (2004).
Article CAS PubMed Google Scholar
Grant, T., Rohou, A. & Grigorieff, N. cisTEM, user-friendly software for single-particle image processing. eLife https://doi.org/10.7554/eLife.35383 (2018).
Schuck, P. Size-distribution analysis of macromolecules by sedimentation velocity ultracentrifugation and lamm equation modeling. Biophys. J. 78, 1606–1619 (2000).
Article ADS CAS PubMed PubMed Central Google Scholar
Johnson, K. A. Fitting enzyme kinetic data with KinTek Global Kinetic Explorer. Methods Enzymol. 467, 601–626 (2009).
Article CAS PubMed Google Scholar
Johnson, K. A., Simpson, Z. B. & Blom, T. Global Kinetic Explorer: a new computer program for dynamic simulation and fitting of kinetic data. Anal. Biochem. 387, 20–29 (2009).
Article CAS PubMed Google Scholar
Cheng, Y. & Prusoff, W. H. Relationship between the inhibition constant (KI) and the concentration of inhibitor which causes 50 per cent inhibition (I50) of an enzymatic reaction. Biochem. Pharmacol. 22, 3099–3108 (1973).
Article CAS PubMed Google Scholar
Download references
D.K. and N.G. are supported by the Howard Hughes Medical Institute (HHMI). We would like to thank M. Rigney for assistance with negative-stain data collection at the Brandeis University Electron Microscopy Facility, and Z. Yu and staff at the Janelia Research Campus cryo-EM facility for advice and assistance with data collection. The Berkeley Center for Structural Biology is supported in part by HHMI. Beamline 8.2.1 of the Advanced Light Source, a US DOE Office of Science User Facility under contract no. DE-AC02-05CH11231, is supported in part by the ALS-ENABLE programme funded by the National Institutes of Health, National Institute of General Medical Sciences, grant P30 GM124169-01. Mass spectral data were obtained at the University of Massachusetts Mass Spectrometry Core Facility (RRID:SCR_019063).
Warintra Pitsawong
Present address: Biomolecular Discovery, Relay Therapeutics, Cambridge, MA, USA
Timothy Grant
Present address: John and Jeanne Rowe Center for Research in Virology, Morgridge Institute for Research, Madison, Madison, WI, USA
Timothy Grant
Present address: Department of Biochemistry, University of Wisconsin-Madison, Madison, WI, USA
Marc Hoemberger & Renee Otten
Present address: Treeline Biosciences, Watertown, MA, USA
Nikolaus Grigorieff
Present address: Howard Hughes Medical Institute, RNA Therapeutics Institute, University of Massachusetts Chan Medical School, Worcester, MA, USA
These authors contributed equally: Warintra Pitsawong, Ricardo A. P. Pádua, Timothy Grant
Howard Hughes Medical Institute and Department of Biochemistry, Brandeis University, Waltham, MA, USA
Warintra Pitsawong, Ricardo A. P. Pádua, Marc Hoemberger, Renee Otten & Dorothee Kern
Janelia Research Campus, Howard Hughes Medical Institute, Ashburn, VA, USA
Timothy Grant & Nikolaus Grigorieff
Department of Biochemistry, Brandeis University, Waltham, MA, USA
Niels Bradshaw
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
W.P., R.A.P.P. and D.K. conceived the project and designed experiments. W.P. performed and analysed all biochemical data. W.P. and R.A.P.P. set up the crystal trays. R.A.P.P. collected and analysed the X-ray crystallographic data. W.P. prepared the samples for the cryo-EM studies and collected negative-stain images to screen for optimal sample conditions. T.G. collected and processed all cryo-EM data and reconstructed the cryo-EM maps under supervision of N.G. R.A.P.P. built and interpreted the structural models. W.P. and N.B. performed and analysed experiments with radioactively labelled KaiC. M.H. built the KaiC phylogeny tree. W.P., R.O. and D.K. wrote the paper. All authors commented on the manuscript and contributed to data interpretation.
Correspondence to Dorothee Kern.
D.K. is co-founder of Relay Therapeutics and MOMA Therapeutics. The remaining authors declare no competing interests.
Nature thanks Marta Carroni, Satchidananda Panda and the other, anonymous, reviewer(s) for their contribution to the peer review of this work.
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
(a) Phylogenetic tree of kaiC homologs, where kaiC genes that have an approximately 50 amino acids C-terminal extension are labeled in red. Rhodobacter sphaeroides strain KD131 studied here and Synechococcus elongatus PCC 7942 (widely studied in the literature) are highlighted in green and pink, respectively. The accession code and organism are shown at the tip of the branches, the numbers at each node represent the aBayes bootstrap values48, and the legend for branch length is shown (see also Supplementary Datasets 1 and 2). (b) A sequence alignment of the CII domain of the kaiC subgroups annotated with its sequence similarity. Residue Glu490, the position where the stop codon was introduced in the truncated KaiCRS-Δcoil construct, is shown in red and marked with an arrow.
(a) 10% SDS-PAGE gel of 3.5 μM KaiCRS in the presence of 4 mM ATP and using an ATP-recycling system at 30 °C. U, S, and D represent unphosphorylated, singly, and doubly phosphorylated KaiCRS, respectively. (b) Densitometric analysis of auto-phosphorylation (single + double phosphorylation) from panel (a) over time yields a rate of 6.5 ± 1.0 h−1. (c) 6.5% SDS-PAGE gel of 3.5 μM KaiCSE in the presence of 1.2 μM KaiASE and 4 mM ATP at 30 °C. U and P represent unphosphorylated and phosphorylated KaiCSE, respectively. (d) Densitometric analysis of auto-phosphorylation of KaiCSE activated by KaiASE (panel (c)) shows a rate of 0.40 ± 0.02 h−1 and is substantially slower than for KaiCRS. The standard deviation for parameters in (b) and (d) were obtained from data fitting. (e) 10% SDS-PAGE gels for experiments with 3.5 μM KaiCRS in the presence of 4 mM ATP and using an ATP-recycling system between 20 and 35 °C show that the level of phosphorylation increases with temperature. U, S, and D represent unphosphorylated, singly, and doubly phosphorylated KaiCRS, respectively. For gel source data in (a), (c), and (e), see Supplementary Figure 2. (f) Bar graphs indicating the nucleotide exchange rate in the CII domain of KaiCRS incubated with 50 μM ATP in the presence of an ATP-recycling system, and then mixed with 250 μM mant-ATP. An increase in fluorescence intensity at 440 nm was recorded and the single-exponential time traces were fitted to obtain the exchange rate constants: 3.6 ± 0.8 h−1 (20 °C), 12.2 ± 1.0 h−1 (25 °C), 18.5 ± 1.5 h−1 (30 °C), and 25.2 ± 0.2 h−1 (35 °C). Experiments were performed in triplicate and data are presented as mean values ± s.d.
(a) Oligomerization analysis of KaiCRS (dodecamer, green line) and truncated KaiCRS-Δcoil (hexamer, cyan line) by analytical gel-filtration chromatography. The protein size markers are indicated at the top. (b) Comparison of the elution profiles of KaiCRS-Δcoil (cyan line) and KaiCSE (purple line) from size-exclusion chromatography shows a hexameric state for both KaiCRS-Δcoil and KaiCSE. (c) Oligomeric states of KaiCRS (dodecamer, green line), KaiCRS-Δcoil (hexamer, cyan line), and KaiCSE (hexamer, purple line) were also measured by analytical ultracentrifugation (sedimentation velocity at 30,000 rpm and 20 °C) and the results agree with the data shown in panels (a) and (b). The graph in panel (c) represents the sedimentation coefficient distribution [c(s)]. (d) The change in fluorescence at 440 nm (ΔF440nm) represents the nucleotide exchange between ATP and mant-ATP at 30 °C for KaiCRS (green trace, 18.0 ± 1.5 h−1) and KaiCRS-Δcoil (cyan trace, 19.1 ± 0.8 h−1). Representative traces are shown and the fitted parameters (mean ± s.d.) were obtained from three replicate measurements. (e) Zn2+ Phos-tagTM SDS-PAGE gel shows the level of phosphorylation over time of KaiCRS (upper gel) and KaiCRS-Δcoil (lower gel) at 35 °C. P and U represent phosphorylated and unphosphorylated protein, respectively. (f) Phosphorylation level over time of KaiCRS (green circles, 7.4 ± 0.3 h−1) and KaiCRS-Δcoil (cyan circles, 5.5 ± 0.4 h−1) analyzed by densitometric analysis of Zn2+ Phos-tagTM SDS-PAGE gel in (e). (g) First derivative of thermal-stability curves measured for unphosphorylated KaiCRS bound with ADP (brown line) and phosphorylated KaiCRS bound with ATP (green line). The extracted temperatures of denaturation are 50 °C (unphosphorylated KaiCRS in the presence of 1 mM ADP) and 58 °C (phosphorylated KaiCRS in the presence of 1 mM ATP), respectively. (h) Dodecameric state of unphosphorylated KaiCRS (40 μM) bound with ADP measured by size-exclusion chromatography. (i) SDS-PAGE gel shows dephosphorylation of Ser413 over time at 30 °C in the presence of 4 mM ADP (U and pSer413 represent unphosphorylated and Ser413-phosphorylated KaiCRS, respectively) with the corresponding kinetics shown in the right panel (confirmed by MS/MS) with a rate constant of 11.5 ± 0.8 h−1. This result suggests that the coiled-coil domain promotes KaiCRS dephosphorylation. For gel source data in (e) and (i), see Supplementary Figure 2. The standard deviation for parameters in (f) and (i) were obtained from data fitting.
The workflow (see description in Methods section) demonstrates a typical image (scale bar: 60 nm) and representative good class averages. The ab initio and final reconstructions are shown. Shown alongside the final reconstruction is the angular plot demonstrating the distribution of particle views and the Fourier shell correlation curve used for the global resolution estimation (a) KaiCRS-S413E/S414E alone and (b) KaiCRS-S413E/S414E:KaiBRS complex. To validate the final combined dodecamer structures, the data were reprocessed for the full dodecamer. The figure shows representative good class averages, the final reconstruction, angular distribution and Fourier shell correlation curve for the (c) KaiCRS-S413E/S414E alone and (d) KaiCRS-S413E/S414E:KaiBRS complex dodecamers. (e) Comparison of the C1 and D6 reconstructions of KaiCRS-S413E/S414E alone and KaiCRS-S413E/S414E:KaiBRS, and Fourier shell correlation curves for the C1 reconstructions. The C1/D6 comparisons do not reveal discernable differences, suggesting that these complexes have D6 symmetry.
(a) Structural comparison between KaiCRS (green) and KaiCRS-S413E/S414E (orange, single-chain for clarity) reveals that the coiled-coil in the phosphomimetic structure points outwards, with an angle of about 20° relative to the KaiCRS coiled-coil. (b) The conformational change in the coiled-coil domain affects the dimer interface due to partner swaps with the opposite hexamer (see also Fig. 2). From an “outside perspective”: the C-terminal helix in KaiCRS interacts with the right chain from the opposite hexamer, whereas in KaiCRS-S413E/S414E the interaction is with the chain on the left. (c) Coiled-coil diagrams describe the heptad register shift that accompanies this structural rearrangement. (d) Based on the overlay of our structures, we propose the following model for the phosphorylation/dephosphorylation events. First, the phosphorylation cycle starts with the transfer of the γ-phosphate of ATP to the hydroxyl group of Ser414 (1; green arrow) in unphosphorylated KaiCRS (green) or KaiCRS-Δcoil (cyan). Secondly, pSer414 of KaiCRS-Δcoil (purple, singly phosphorylated) moves away from the active site placing the hydroxyl group of Ser413 closer to the γ-phosphate of ATP for the second phosphorylation (2; purple arrow). Thirdly, the doubly phosphomimetic state (KaiCRS-S413E/S414E, orange) reveals that the phosphoryl group of pSer414 moves back towards the active site for dephosphorylation (3; orange arrow). Lastly, we hypothesize that the indole group of Trp419 “pushes” pSer413 into the active site for the second dephosphorylation event (dashed arrow), in agreement with the slower dephosphorylation rate observed in the KaiCRS-Δcoil construct (cf. Fig. 2d).
(a) 10% SDS-PAGE gel of 3.5 μM KaiCRS and 3.5 μM KaiBRS in the presence of 4 mM ATP and 10 mM 2-phosphoenolpyruvate at 30 °C shows that the auto-phosphorylation cycle restarts upon regeneration of ATP by the addition of 2 U ml−1 pyruvate kinase at the 24-hour time mark. (b) 10% SDS-PAGE gel of 3.5 μM KaiCRS without (upper panel) and with (lower panel) 3.5 μM KaiBRS in the presence of 4 mM ATP with an ATP-recycling system added from the beginning showing that under these conditions KaiB does not accelerate dephosphorylation. For gel source data in (a) and (b), see Supplementary Figure 2. (c) Representative curves for ADP production of KaiCRS (3.5 μM) alone and (d) in the presence of KaiBRS (3.5 μM) in 4 mM ATP measured by HPLC. The data were analysed as described in the Methods section and result in ATPase activities of 108 ± 10 day−1 KaiC−1 (with KaiBRS = 176 ± 29 day−1 KaiC−1) at 20 °C, 163 ± 16 day−1 KaiC−1 (with KaiBRS = 1052 ± 143 day−1 KaiC−1) at 25 °C, 208 ± 19 day−1 KaiC−1 (with KaiBRS = 1557 ± 172 day−1 KaiC−1) at 30 °C, and 300 ± 21 day−1 KaiC−1 (with KaiBRS = 2584 ± 245 day−1 KaiC−1) at 35 °C. The temperature coefficient, Q10, was calculated using the data obtained at 25 °C and 35 °C and yields a value of ~ 1.9. The standard deviations of ATPase activity at each temperature (right panels) were obtained from three replicate measurements and data are presented as mean values ± s.d. (e) The comparison of ADP production of KaiCRS in the absence (orange circles, data from panel (c)) and presence (orange diamonds, data from panel (d)) of KaiBRS at 30 °C indicate a 7.5-fold increase in ATPase activity for the complex. The binding of KaiBRS accelerates the ATPase activity of KaiCRS in both the CI and CII domains (see also Extended Data Fig. 8b, c). (f) The SDS-PAGE gel of KaiCRS (10 μg) and KaiBRS (10 μg) shows that both proteins were purified to homogeneity and the measured ATPase activity is, therefore, not due to impurities. (g) ADP production of KaiBRS in 4 mM ATP at 30 °C shows, as expected, no ATPase activity for KaiBRS alone and confirms the increase in ATPase activity shown in panel (d) is due to complex formation. The standard deviation for the representative curves shown in panels (c-d, left), e, and g was set to 6% assuming the largest systematic error originates from the injector.
(a) Possible mechanisms how KaiBRS could accelerate KaiCRS dephosphorylation at nighttime. Binding of KaiBRS on the CIRS domain directly accelerates the phosphoryl transfer from pSer to bound ADP to generate transiently bound ATP. The cartoon represents the interface between two monomers in the CIIRS domain. (b) Autoradiograph of separation of 32P-KaiCRS at Ser413, transiently formed 32P-ATP, and free 32Pi via thin-layer chromatography (TLC) with 4 mM ADP at 30 °C, with the corresponding kinetics shown in (c) where gray circle, purple triangle, and cyan diamonds represent the relative concentrations of phosphorylated 32P-KaiCRS, 32P-ATP, and free 32Pi, respectively. (d) Comparison of transient 32P-ATP formation and decay in the absence (open triangle) and presence (solid triangle) of KaiBRS and free 32P formation in the absence (open circles) and presence of KaiBRS (solid circles). Faster decay of transient 32P-ATP together with higher free 32P production in the presence of KaiBRS indicated that KaiBRS accelerates hydrolysis in KaiCRS. (e) SDS-PAGE gel (10%) of dephosphorylation of phosphorylated 3.5 μM KaiCRS at Ser413 without (upper gel) and with (lower gel) 3.5 μM KaiBRS in the presence of 4 mM ADP at 30 °C (for gel source data, see Supplementary Figure 2). (f) Densitometric analysis of data in panel (e) shows the decay of total KaiCRS phosphorylation in the absence (gray circles) and presence (red diamonds) of KaiBRS and yields rates of 11.5 ± 0.8 h−1 and 11.0 ± 0.8 h−1, respectively. This result indicates that binding of KaiBRS does not accelerate the phosphoryl-transfer step in KaiCRS.
(a) Second possible mechanism to explain how KaiBRS accelerates KaiCRS dephosphorylation at nighttime: binding of KaiBRS to the CIRS domain could increase the hydrolysis rate in the CIIRS domain and, thereby, prevent the phosphoryl transfer back from transiently formed or external ATP back to serine residues. (b) Representative curves for ADP production of phosphorylated KaiCRS with catalytic mutations in the CI domain (KaiCRS-E62Q/E63Q, 3.5 μM) in the absence (dark green circles) and presence (light green circles) of 3.5 μM KaiBRS at 30 °C with 4 mM ATP was quantified using HPLC. From these data an ATPase activity in the CII domain of 112 ± 8 day−1 KaiC−1 and 195 ± 16 day−1 KaiC−1 in the presence of KaiBRS was determined. (c) Representative curves for ADP production measured by HPLC as in panel (b) of KaiCRS but with catalytic mutations in the CII domain (KaiCRS-E302Q/E303Q, 3.5 μM) in the absence (dark pink circles) and presence (light pink diamonds) of 3.5 μM KaiBRS. The corresponding ATPase activities in the CI domain are 110 ± 12 day−1 KaiC−1 in the absence and 320 ± 22 day−1 KaiC−1 in the presence of KaiBRS. (d) Representative curves for ADP production of KaiCIRS-E62Q/E63Q (construct of only CI domain with catalytic mutations) in 4 mM ATP at 30 °C shows no ATPase activity indicating that Glu62 and Glu63 are the only two residues that are responsible for ATPase activity in CI domain of KaiCRS and confirms the ATPase activity shown in panel b is due to ATPase activity in CII domain of KaiCRS. The standard deviation for the representative curves shown in panels (b-d) was set to 6% assuming the largest systematic error originates from the injector. The experiments in panel (b-d) were performed in triplicate and ATPase rate given in the legend for panels (b) and (c) are presented as mean values ± s.d. (e) Third possible mechanism to explain how KaiBRS accelerates KaiCRS dephosphorylation at nighttime: binding of KaiBRS to the CIRS domain could promote faster nucleotide exchange in the CIIRS domain to displace transient ATP by ADP. (f) Time course of fluorescence intensity at 440 nm due to binding of mant-ATP to KaiCRS-S413E bound with ATP in the absence (solid blue trace) and presence (red dotted trace) of KaiBRS. KaiCRS-S413E (3.5 μM) was pre-incubated with 3.5 μM KaiBRS for 16 h at 20, 25, 30, and 35 °C in the presence of 50 μM ATP and an ATP-recycling system and then mixed with 250 μM mant-ATP. The observed exchange rates at each temperature are listed in the table (g). (h) Nucleotide exchange of KaiCIRS (i.e., only CIRS domain) cannot be measured since there is no tryptophan residue in close proximity of the nucleotide binding site. In summary, KaiBRS accelerates KaiCRS dephosphorylation by increasing the hydrolysis rate in the CI and CII domains and does not affect the nucleotide exchange rate. Representative traces are shown in (f) and (h) and the fitted parameters (g; mean ± s.d.) were obtained from three replicate measurements.
(a) Size-exclusion chromatography of KaiBRS (blue) shows that it is monomeric in solution in contrast to KaiBSE (gray), which elutes as a tetramer. Molecular-weight standards are shown above the chromatogram. (b) Structural comparison of KaiBTE (gray, PDB 5jwq26) and KaiBRS (blue) when bound to their corresponding KaiC hexamers. The PISA software package37 determines that for the KaiBCTE complex the interface between the KaiBTE monomers is 255 Å2, whereas the average interface between KaiBRS monomers is only 45 Å2 in the KaiBCRS complex. (c) To understand how KaiBRS binding to KaiCRS-CI domain increases the hydrolysis rate, we investigated whether conformational changes modulated substrate access to the active site. The CAVER software61 was used to calculate tunnels (gray mesh) leading into the active site of the CI domain of KaiCRS-S413E/S414E alone (orange) and the KaiCRS-S413E/S414E:KaiBRS complex (yellow:blue) with varying probe radii. In both structures, the active site was occupied by ADP:Mg2+ (sticks and green sphere, respectively). The crystal structure of bovine F1-ATPase in complex with a transition-state analogue (PDB 1w0j, chain D)62 was used as a reference to determine the position of the catalytic water molecule in the active site (shown as a red sphere). The calculated tunnels connect bulk solvent to the catalytic water when KaiBRS is bound for probe radii larger than the default value of 0.9 Å, but never in its absence. These results suggest that KaiBRS facilitates the access of water into the active site of KaiCRS-CI via long-range conformational changes and thus enhances ATP hydrolysis.
(a) Size-exclusion chromatography of 50 μM KaiCRS-CI (CIRS domain) in the absence (black line, hexamer) and presence (gray line, monomer) of 50 μM KaiBRS in 1 mM ATP buffer. (b) Size-exclusion chromatography of 50 μM KaiCRS-Δcoil in the presence of 50 μM KaiBRS (purple). The reference sample (50 μM KaiCRS-Δcoil) is a hexamer in solution (cyan) and after the addition of 50 μM KaiBRS the mixture was incubated at 30 °C for 3.5 h (purple) before running the samples again on a Superdex-200 10/300 GL column at 4 °C. These data show that binding of KaiBRS results in (i) disassembly of the hexameric KaiCRS-Δcoil structure into its monomers and (ii) aggregation as detected by the elution in the void volume of the column (v0). (c) Thermal denaturation profiles for KaiCRS-S413E/S414E in the presence of 1 mM ADP are shown from dark to light blue for increasing concentrations of KaiBRS (between 0 – 4 μM). The black line represents KaiBRS alone (15 μM), which shows no fluorescence signal as it does not bind to SYPRO Orange due to a lack of a hydrophobic core. The Tm decreases upon the addition of KaiBRS, indicating that binding of KaiBRS destabilizes the KaiCRS dodecamer. Likely due to loosening up of interface and the KaiCRS structure, thereby allowing for the formation of a tunnel that connects bulk solvent to the position of the hydrolytic water in the active site (see Extended Data Fig. 9). (d) SDS-PAGE analysis showing the control experiment for pull-down assay. The first four lanes after the molecular weight marker are KaiBRS-Tag samples (red arrow) and show that KaiBRS-Tag binds tightly to the column. The last four lanes are control pull-down assay experiments for KaiCRS (green arrow) and show that KaiCRS alone is unable to bind to the column. The lanes represent the initial sample used in pull-down assay (Before), flow-through after loading sample onto the column (FT), flow-through after washing the column three times with the binding buffer (Wash #3), and sample after elution with imidazole (Elute). (e) SDS-PAGE analysis of pull-down assay to measure the complex formation between KaiBRS-Tag and wild-type KaiCRS, KaiCRS-S413E/S414E, or KaiCRS-S413A/S414A in the presence of 4 mM ADP or ATP (with an ATP-recycling system). For gel source data, see Supplementary Figure 2. (f) Percentage of wild-type KaiCRS bound to KaiBRS-Tag protein for different ATP-to-ADP ratios (4 mM total nucleotide concentration) at 25 °C as measured from pull-down assays. (g) Fluorescence anisotropy at 30 °C of unlabeled KaiBRS competitively replacing the fluorophore-labeled KaiBRS (KaiBRS-6IAF) from KaiCRS-S413E/S414E in the presence of 4 mM ADP (red circles, KD value of 0.79 ± 0.06 μM) and 4 mM ATP with an ATP-recycling system (orange triangles). In the latter experiment no change in anisotropy is observed, indicating that only a small fraction of KaiBRS-6IAF is bound under these conditions. The average anisotropy and standard error were calculated from ten replicate measurements. (h) The mant-ATPγS or mant-ADP release is shown as bar graphs with observed rates of 4.8 ± 0.2 h−1 and 43.6 ± 3.0 h−1 for mant-ATPγS and mant-ADP releasing from KaiCRS-S413E/S414E, respectively, and 21.0 ± 3.0 h−1 and 65 ± 15 h−1 for mant-ATPγS and mant-ADP releasing from KaiCRS-S413A/S414A, respectively. The result shows that CII domain of KaiCRS prefers binding of ATP over ADP. Experiments in panels (f) and (h) were performed in triplicate and data are presented as mean values ± s.d.
Supplementary Figs. 1 and 2 and Supplementary Tables 1 and 2.
Visualization of conformational changes in the CII domain of KaiCRS after phosphorylation through the long-range allosteric network. The trajectory was made by linear interpolation between unphosphorylated KaiCRS and the phosphomimetic variant (KaiCRS-S413E/S414E) using the morph tool in UCSF Chimera 1.15 (ref. 64); the movie was rendered in PyMOL (v.2.6.0)60.
Initial multiple-sequence alignment and phylogenetic tree for KaiC.
Final multiple-sequence alignment and phylogenetic tree including only species that contain KaiB and KaiC.
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
Reprints and Permissions
Pitsawong, W., Pádua, R.A.P., Grant, T. et al. From primordial clocks to circadian oscillators. Nature 616, 183–189 (2023). https://doi.org/10.1038/s41586-023-05836-9
Download citation
Received: 29 May 2022
Accepted: 13 February 2023
Published: 22 March 2023
Issue Date: 06 April 2023
DOI: https://doi.org/10.1038/s41586-023-05836-9
Anyone you share the following link with will be able to read this content:
Sorry, a shareable link is not currently available for this article.
Provided by the Springer Nature SharedIt content-sharing initiative
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.