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Cyanobacterial clock proteins

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KaiA domain
crystal structure of circadian clock protein kaia from synechococcus elongatus
Identifiers
SymbolKaiA
PfamPF07688
InterProIPR011648
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary
KaiB domain
solution structure of the n-terminal domain of synechococcus elongatus sasa (average minimized structure)
Identifiers
SymbolKaiB
PfamPF07689
Pfam clanCL0172
InterProIPR011649
CDDcd02978
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary
KaiC
crystal structure of full length circadian clock protein kaic with phosphorylation sites
Identifiers
SymbolKaiC
PfamPF06745
Pfam clanCL0023
InterProIPR014774
CDDcd01124
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary

In molecular biology, the cyanobacterial clock proteins are the main circadian regulator in cyanobacteria. The cyanobacterial clock proteins comprise three proteins: KaiA, KaiB and KaiC. The kaiABC complex may act as a promoter-nonspecific transcription regulator that represses transcription, possibly by acting on the state of chromosome compaction. This complex is expressed from a KaiABC operon.

See also: bacterial circadian rhythms

In the complex, KaiA enhances the phosphorylation status of kaiC. In contrast, the presence of kaiB in the complex decreases the phosphorylation status of kaiC, suggesting that kaiB acts by antagonising the interaction between kaiA and kaiC. The activity of KaiA activates kaiBC expression, while KaiC represses it.

Also in the KaiC family is RadA/Sms, a highly conserved eubacterial protein that shares sequence similarity with both RecA strand transferase and lon protease. The RadA/Sms family are probable ATP-dependent proteases involved in both DNA repair and degradation of proteins, peptides, glycopeptides. They are classified in as non-peptidase homologues and unassigned peptidases in MEROPS peptidase family S16 (lon protease family, clan SJ). RadA/Sms is involved in recombination and recombinational repair, most likely involving the stabilisation or processing of branched DNA molecules or blocked replication forks because of its genetic redundancy with RecG and RuvABC.[1]

Structure

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The overall fold of the KaiA monomer is that of a four-helix bundle, which forms a dimer in the known structure.[2] KaiA functions as a homodimer. Each monomer is composed of three functional domains: the N-terminal amplitude-amplifier domain, the central period-adjuster domain and the C-terminal clock-oscillator domain. The N-terminal domain of KaiA, from cyanobacteria, acts as a pseudo-receiver domain, but lacks the conserved aspartyl residue required for phosphotransfer in response regulators.[3] The C-terminal domain is responsible for dimer formation, binding to KaiC, enhancing KaiC phosphorylation and generating the circadian oscillations.[4] The KaiA protein from Anabaena sp. (strain PCC 7120) lacks the N-terminal CheY-like domain.

KaiB adopts an alpha-beta meander motif and is found to be a dimer or a tetramer.[2][5]

KaiC belongs to a larger family of proteins; it performs autophosphorylation and acts as its own transcriptional repressor. It binds ATP.[6]

Alternate arrangements

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History of discovery

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Due to the lack of a nucleus in these organisms, there was doubt as to whether or not cyanobacteria would be able to express circadian rhythms. Kondo et al. were the first to definitively demonstrate that cyanobacteria do in fact have circadian rhythms. In a 1993 experiment, they used a luciferase reporter inserted into the genetically tractable Synechococcus sp., which was grown in a 12:12 light-dark cycle to ensure “entrainment”. There were two sets of bacteria so that one was in light while the other was in darkness during this entrainment period. Once the bacteria entered the stationary phase, they were transferred into test tubes kept in constant light, except for 5-minute recording periods every 30 minutes, in which the tubes were kept in darkness to measure their levels of bioluminescence. They found that the level of bioluminescence cycled at a near 24-hour period, and that the two groups oscillated with opposite phases. This led them to conclude that the Synechococcus sp. genome was regulated by a circadian clock. (1)

Function in vitro

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The circadian oscillators in eukaryotes that have been studied function using a negative feedback loop in which proteins inhibit their own transcription in a cycle that takes approximately 24 hours. This is known as a transcription-translation-derived oscillator (TTO).(2) Without a nucleus, prokaryotic cells must have a different mechanism of keeping circadian time. In 1998, Ishiura et al. determined that the KaiABC protein complex was responsible for the circadian negative feedback loop in Synechococcus by mapping 19 clock mutants to the genes for these three proteins.(3) An experiment by Nakajima et al., in 2005, was able to demonstrate the circadian oscillation of the Synechococcus KaiABC complex in vitro. They did this by adding KaiA, KaiB, KaiC, and ATP into a test tube in the approximate ratio recorded in vivo. They then measured the levels of KaiC phosphorylation and found that it demonstrated circadian rhythmicity for three cycles without damping. This cycle was also temperature compensating. They also tested incubating mutant KaiC protein with KaiA, KaiB, and ATP. They found that the period of KaiC phosphorylation matched the intrinsic period of the cyanobacterium with the corresponding mutant genome. These results led them to conclude that KaiC phosphorylation is the basis for circadian rhythm generation in Synechococcus. (2)

Cyanobacterial clocks as model systems

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Cyanobacteria are the simplest organisms that have been observed demonstrating circadian rhythms.(2)(3) The primitiveness and simplicity make the KaiC phosphorylation model invaluable to circadian rhythm research. While it is much simpler than models for eukaryotic circadian rhythm generators, the principles are largely the same. In both systems the circadian period is dependent on the interactions between proteins within the cell, and when the genes for those proteins are mutated, the expressed period changes. (1)(2) This model of circadian rhythm generation also has implications for the study of circadian “evolutionary biology”. Given the simplicity of cyanobacteria and of this circadian system, it may be safe to assume that eukaryotic circadian oscillators are derived from a system similar to that present in cyanobacterium. (1)


References

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  1. ^ Beam CE, Saveson CJ, Lovett ST (December 2002). "Role for radA/sms in recombination intermediate processing in Escherichia coli". J. Bacteriol. 184 (24): 6836–44. doi:10.1128/jb.184.24.6836-6844.2002. PMC 135464. PMID 12446634.
  2. ^ a b Garces RG, Wu N, Gillon W, Pai EF (April 2004). "Anabaena circadian clock proteins KaiA and KaiB reveal a potential common binding site to their partner KaiC". EMBO J. 23 (8): 1688–98. doi:10.1038/sj.emboj.7600190. PMC 394244. PMID 15071498.
  3. ^ Williams SB, Vakonakis I, Golden SS, LiWang AC (November 2002). "Structure and function from the circadian clock protein KaiA of Synechococcus elongatus: a potential clock input mechanism". Proc. Natl. Acad. Sci. U.S.A. 99 (24): 15357–62. doi:10.1073/pnas.232517099. PMC 137721. PMID 12438647.
  4. ^ Uzumaki T, Fujita M, Nakatsu T, Hayashi F, Shibata H, Itoh N, Kato H, Ishiura M (July 2004). "Crystal structure of the C-terminal clock-oscillator domain of the cyanobacterial KaiA protein". Nat. Struct. Mol. Biol. 11 (7): 623–31. doi:10.1038/nsmb781. PMID 15170179. S2CID 36997475.
  5. ^ Hitomi K, Oyama T, Han S, Arvai AS, Getzoff E (2005). "Tetrameric architecture of the circadian clock protein KaiB. A novel interface for intermolecular interactions and its impact on the circadian rhythm". J Biol Chem. 280 (19): 19127–35. doi:10.1074/jbc.M411284200. PMID 15716274.
  6. ^ Pattanayek R, Wang J, Mori T, Xu Y, Johnson CH, Egli M (2004). "Visualizing a circadian clock protein: crystal structure of KaiC and functional insights". Mol Cell. 15 (3): 375–88. doi:10.1016/j.molcel.2004.07.013. PMID 15304218.
This article incorporates text from the public domain Pfam and InterPro: IPR011648
This article incorporates text from the public domain Pfam and InterPro: IPR011649
This article incorporates text from the public domain Pfam and InterPro: IPR014774