Structure and molecular phylogeny of sasA genes in cyanobacteria: insights into evolution of the prokaryotic circadian system

Cyanobacteria are the simplest organisms known to have a circadian system. In addition to the three well-studied kai genes, kaiA, kaiB, and kaiC, an important element of this system is a two-component sensory transduction histidine kinase sasA. Using publicly available data of complete prokaryotic genomes, we performed structural and phylogenetic analyses of the sasA genes. Results show that this gene has a triple-domain structure, and the domains are under different selective constraints. The sasA gene originated in cyanobacteria probably through the fusion of the ancestral kaiB gene with a double-domain, two-component sensory transduction histidine kinase. The results of the phylogenetic analyses suggest that sasA emerged before the kaiA gene, about 3,000-2,500 MYA, and has evolved in parallel with the evolution of the kaiBC cluster. The observed concordant patterns of the sasA and kaiBC evolution suggest that these genes might compose an ancient KaiBC-SasA-based circadian system, without the kaiA gene, and that such a system still exists in some unicellular cyanobacteria.     

A kaiC-interacting sensory histidine kinase, SasA, necessary to sustain robust circadian oscillation in cyanobacteria

Both regulated expression of the clock genes kaiA, kaiB, and kaiC and interactions among the Kai proteins are proposed to be important for circadian function in the cyanobacterium Synechococcus sp. strain PCC 7942. We have identified the histidine kinase SasA as a KaiC-interacting protein. SasA contains a KaiB-like sensory domain, which appears sufficient for interaction with KaiC. Disruption of the sasA gene lowered kaiBC expression and dramatically reduced amplitude of the kai expression rhythms while shortening the period. Accordingly, sasA disruption attenuated circadian expression patterns of all tested genes, some of which became arrhythmic. Continuous sasA overexpression eliminated circadian rhythms, whereas temporal overexpression changed the phase of kaiBC expression rhythm. Thus, SasA is a close associate of the cyanobacterial clock that is necessary to sustain robust circadian rhythms.     

Functional divergence of the circadian clock proteins in prokaryotes

Cyanobacteria are only prokaryotes known so far to have a circadian system. It may be based either on two (kaiB and kaiC) or three (kaiA, kaiB and kaiC) circadian genes. The homologs of two circadian proteins, KaiB and KaiC, form four major subfamilies (K1–K4) and also occur in some other prokaryotes. Using the likelihood-ratio tests, we studied a rate shift at the functional divergence of the proteins from the different subfamilies. It appears that only two of the subfamilies (K1 and K2) perform circadian functions. We identified in total 92 sites that have significantly different rates of evolution between the clades K1/K2 and K3/K4; 67 sites (15 in KaiB and 52 in KaiC) been evolving significantly slower in K1/K2 than the overall average for the entire sequence. Many critical sites are located in the identified functionally important motifs and regions, e.g. one of the Walker’s motif As, DXXG motif, and two KaiA-binding domains of KaiC. There are also 36 sites (~5%) with rate shift between K1 and K2. The rate shift at these sites may be related to the interaction with KaiA. Rate shift analyses have identified residues whose manipulation in the Kai proteins may lead to better understanding of their functions in the two different types of the cyanobacterial circadian system.     

LdpA: a component of the circadian clock senses redox state of the cell

The endogenous 24-h (circadian) rhythms exhibited by the cyanobacterium Synechococcus elongatus PCC 7942 and other organisms are entrained by a variety of environmental factors. In cyanobacteria, the mechanism that transduces environmental input signals to the central oscillator of the clock is not known. An earlier study identified ldpA as a gene involved in light-dependent modulation of the circadian period, and a candidate member of a clock-entraining input pathway. Here, we report that the LdpA protein is sensitive to the redox state of the cell and exhibits electron paramagnetic resonance spectra consistent with the presence of two Fe4S4 clusters. Moreover, LdpA copurifies with proteins previously shown to be integral parts of the circadian mechanism. We also demonstrate that LdpA affects both the absolute level and light-dependent variation in abundance of CikA, a key input pathway component. The data suggest a novel input pathway to the circadian oscillator in which LdpA is a component of the clock protein complex that senses the redox state of a cell.     

Casein kinase 2, circadian clocks, and the flight from mutagenic light

Circadian clocks play a fundamental role in biology and disease. Much has been learned about the molecular underpinnings of these biological clocks from genetic studies in model organisms, such as the fruit fly, Drosophila melanogaster. Here we review the literature from our lab and others that establish a role for the protein kinase CK2 in Drosophila clock timing. Among the clock genes described thus far, CK2 is unique in its involvement in plant, fungal, as well as animal circadian clocks. We propose that this reflects an ancient, conserved function for CK2 in circadian clocks. CK2 and other clock genes have been implicated in cellular responses to DNA damage, particularly those induced by ultraviolet (UV) light. The finding of a dual function of CK2 in clocks and in UV responses supports the notion that clocks evolved to assist organisms in avoiding the mutagenic effects of daily sunlight.     

Frequency doubling in the cyanobacterial circadian clock

Organisms use circadian clocks to generate 24‐h rhythms in gene expression. However, the clock can interact with other pathways to generate shorter period oscillations. It remains unclear how these different frequencies are generated. Here, we examine this problem by studying the coupling of the clock to the alternative sigma factor sigC in the cyanobacterium Synechococcus elongatus. Using single‐cell microscopy, we find that psbAI, a key photosynthesis gene regulated by both sigC and the clock, is activated with two peaks of gene expression every circadian cycle under constant low light. This two‐peak oscillation is dependent on sigC, without which psbAI rhythms revert to one oscillatory peak per day. We also observe two circadian peaks of elongation rate, which are dependent on sigC, suggesting a role for the frequency doubling in modulating growth. We propose that the two‐peak rhythm in psbAI expression is generated by an incoherent feedforward loop between the clock, sigC and psbAI. Modelling and experiments suggest that this could be a general network motif to allow frequency doubling of outputs.     

Structure and interactions of PAS kinase N-terminal PAS domain: model for intramolecular kinase regulation

PAS domains are sensory modules in signal-transducing proteins that control responses to various environmental stimuli. To examine how those domains can regulate a eukaryotic kinase, we have studied the structure and binding interactions of the N-terminal PAS domain of human PAS kinase using solution NMR methods. While this domain adopts a characteristic PAS fold, two regions are unusually flexible in solution. One of these serves as a portal that allows small organic compounds to enter into the core of the domain, while the other binds and inhibits the kinase domain within the same protein. Structural and functional analyses of point mutants demonstrate that the compound and ligand binding regions are linked, suggesting that the PAS domain serves as a ligand-regulated switch for this eukaryotic signaling system.     

The X-ray structure of the N-terminal domain of PILB from Neisseria meningitidis reveals a thioredoxin-fold

The secreted form of the PilB protein was recently shown to be bound to the outer membrane of Neisseria gonorrhoeae and proposed to be involved in survival of the pathogen to the host's oxidative burst. PilB is composed of three domains. The central and the C-terminal domains display methionine sulfoxide reductase (Msr) A and B activities respectively, i.e. the ability to reduce specifically the S and the R enantiomers of the sulfoxide function of the methionine sulfoxides, which are easily formed upon oxidation of methionine residues. The N-terminal domain of PilB (Dom1(PILB)) of N.meningitidis, which possesses a CXXC motif, was recently shown to recycle the oxidized forms of the PilB Msr domains in vitro, as the Escherichia coli thioredoxin (Trx) 1 does. The X-ray structure of Dom1(PILB) of N.meningitidis determined here shows a Trx-fold, in agreement with the biochemical properties of Dom1(PILB). However, substantial structural differences with E.coli Trx1 exist. Dom1(PILB) displays more structural homologies with the periplasmic disulfide oxidoreductases involved in cytochrome maturation pathways in bacteria. The active site of the reduced form of Dom1(PILB) reveals a high level of stabilization of the N-terminal catalytic cysteine residue and a hydrophobic environment of the C-terminal recycling cysteine in the CXXC motif, consistent with the pK(app) values measured for Cys67 (<6) and Cys70 (9.3), respectively. Compared to cytochrome maturation disulfide oxidoreductases and to Trx1, one edge of the active site is covered by four additional residues (99)FLHE(102). The putative role of the resulting protuberance is discussed in relation to the disulfide reductase properties of Dom1(PILB).     

Characterization of the rice circadian clock-associated pseudo-response regulators in Arabidopsis thaliana

Members of the small family of Arabidopsis PSEUDO-RESPONSE REGULATORS (PRR1/TOC1, PRR3, PRR5, PRR7, and PRR9) play roles close to the circadian clock in Arabidopsis thaliana. We have reported that the rice (Oryza sativa) genome also encodes a set of PRR counterparts (designated OsPRR1, OsPRR37, OsPRR59, OsPRR73, and OsPRR95 respectively). To gain new insight into the molecular functions of OsPRRs, we carried out genetic complementation analyses by introducing two representative rice genes, OsPRR1 and OsPRR37, into the corresponding Arabidopsis loss-of-function mutants (toc1 and prr7 respectively). The results showed that these OsPRR and AtPRR genes are genetically interchangeable at least in part, suggesting the conserved clock-associated function of these OsPRRs.     

Topology and secondary structure of the N-terminal domain of diacylglycerol kinase

Prokaryotic diacylglycerol kinase (DAGK) functions as a homotrimer of 13 kDa subunits, each of which has three transmembrane segments. This enzyme is conditionally essential to some bacteria and serves as a model system for studies of membrane protein biocatalysis, stability, folding, and misfolding. In this work, the detailed topology and secondary structure of DAGK's N-terminus up through the loop following the first transmembrane domain were probed by NMR spectroscopy. Secondary structure was mapped by measuring 13C NMR chemical shifts. Residue-to-residue topology was probed by measuring 19F NMR relaxation rates for site-specifically labeled samples in the presence and absence of polar and hydrophobic paramagnetic probes. Most of DAGK's N-terminal cytoplasmic and first transmembrane segments are alpha-helical. The first and second transmembrane helices are separated by a short loop from residues 48 to 52. The first transmembrane segment extends from residues 32 to 48. Most of the N-terminal cytoplasmic domain lies near the interface but does not extend deeply into the membrane. Finally, catalytic activities measured for the single cysteine mutants before and after chemical labeling suggest that the N-terminal cytoplasmic domain likely contains a number of critical active site residues. The results, therefore, suggest that DAGK's active site lies very near to the water/bilayer interface.     

A ligand-induced switch in the periplasmic domain of sensor histidine kinase CitA

Sensor histidine kinases of two-component signal-transduction systems are essential for bacteria to adapt to variable environmental conditions. However, despite their prevalence, it is not well understood how extracellular signals such as ligand binding regulate the activity of these sensor kinases. CitA is the sensor histidine kinase in Klebsiella pneumoniae that regulates the transport and anaerobic metabolism of citrate in response to its extracellular concentration. We report here the X-ray structures of the periplasmic sensor domain of CitA in the citrate-free and citrate-bound states. A comparison of the two structures shows that ligand binding causes a considerable contraction of the sensor domain. This contraction may represent the molecular switch that activates transmembrane signaling in the receptor.     

Genetic analysis of the catalytic domain of the chemotaxis-associated histidine kinase CheA.

Escherichia coli cells express two forms of CheA, the histidine kinase associated with chemotaxis. The long form, CheA(L), plays a critical role in chemotactic signal transduction by phosphorylating two chemotaxis-associated response regulators, CheY and CheB. CheA(L) first autophosphorylates amino acid His-48 before its phosphoryl group is transferred to these response regulators. The short form, CheA(S), lacks the amino-terminal 97 amino acids of CheA(L) and therefore does not possess the site of phosphorylation. The centrally located transmitter domain of both forms of CheA contains four regions, called N, G1, F, and G2, highly conserved among histidine kinases of the family of two-component signal transduction systems. On the basis of sequence similarity to highly conserved regions of certain eukaryotic kinases, the G1 and G2 regions are purported to be involved in the binding and hydrolysis of ATP. We report here that alleles mutated in the G1, G2, or F region synthesize CheA variants that cannot autophosphorylate in vitro and which cannot support chemotaxis in vivo. We also show that in vitro, the nonphosphorylatable CheA(S) protein mediates transphosphorylation of a CheA(L) variant defective in both G1 and G2. In contrast, CheA(L) variants defective for either G1 or G2 mediate transphosphorylation of each other poorly, if at all. These results are consistent with a mechanism by which the G1 and G2 regions of one protomer of a CheA dimer form a unit that mediates transphosphorylation of the other protomer within that dimer.     

A eukaryotic LOV-histidine kinase with circadian clock function in the picoalga Ostreococcus

The marine environment has unique properties of light transmission, with an attenuation of long wavelengths within the first meters of the water column. Marine organisms have therefore evolved specific blue‐light receptors such as aureochromes to absorb shorter‐wavelength light. Here, we identify and characterize a light, oxygen, or voltage sensing (LOV) containing histidine kinase (LOV‐HK) that functions as a new class of eukaryotic blue‐light receptor in the pico‐phytoplanktonic cell Ostreococcus tauri. This LOV‐HK is related to the large family of LOV‐HKs found in prokaryotes. Phylogenetic analysis indicates that the LOV domains from LOV‐HKs, including O. tauri LOV‐HK, and phototropins (phot; plant and green algal LOV serine/threonine kinases) have different evolutionary histories. Photochemical analysis shows that the LOV domain of LOV‐HK binds a flavin cofactor and absorbs blue light with a fast photocycle compared with its prokaryotic counterparts. Ostreococcus tauri LOV‐HK expression is induced by blue light and is under circadian control. Further, both overexpression and downregulation of LOV‐HK result in arrhythmia of the circadian reporter CCA1:Luc under constant blue light. In contrast, photochemical inactivation of O. tauri LOV‐HK is without effect, demonstrating its importance for function of the circadian clock under blue light. Overexpression/downregulation of O. tauriLOV‐HK alters CCA1 rhythmicity under constant red light, irrespective of LOV‐HK’s photochemical reactivity, suggesting that O. tauri LOV‐HK also participates in regulation of the circadian clock independent of its blue‐light‐sensing property. Molecular characterization of O. tauri LOV‐HK demonstrates that this type of photoreceptor family is not limited to prokaryotes.     

Structure of the N-terminal domain of Escherichia coli glutamine synthetase adenylyltransferase

We report the crystal structure of the N-terminal domain of Escherichia coli adenylyltransferase that catalyzes the reversible nucleotidylation of glutamine synthetase (GS), a key enzyme in nitrogen assimilation. This domain (AT-N440) catalyzes the deadenylylation and subsequent activation of GS. The structure has been divided into three subdomains, two of which bear some similarity to kanamycin nucleotidyltransferase (KNT). However, the orientation of the two domains in AT-N440 differs from that in KNT. The active site of AT-N440 has been identified on the basis of structural comparisons with KNT, DNA polymerase beta, and polyadenylate polymerase. AT-N440 has a cluster of metal binding residues that are conserved in polbeta-like nucleotidyl transferases. The location of residues conserved in all ATase sequences was found to cluster around the active site. Many of these residues are very likely to play a role in catalysis, substrate binding, or effector binding.     

The hydrophilic N-terminal domain complements the membrane-anchored C-terminal domain of the sensor kinase KdpD of Escherichia coli

The putative turgor sensor KdpD is characterized by a large, N-terminal domain of about 400 amino acids, which is not found in any other known sensor kinase. Comparison of 12 KdpD sequences from various microorganisms reveals that this part of the kinase is highly conserved and includes two motifs (Walker A and Walker B) that are very similar to the classical ATP-binding sites of ATP-requiring enzymes. By means of photoaffinity labeling with 8-azido-[alpha-(32)P]ATP, direct evidence was obtained for the existence of an ATP-binding site located in the N-terminal domain of KdpD. The N-terminal domain, KdpD/1-395, was overproduced and purified. Although predicted to be hydrophilic, it was found to be membrane-associated and could be solubilized either by treatment with buffer of low ionic strength or detergent. The membrane-associated form, but not the solubilized one, retained the ability to bind 8-azido-[alpha-(32)P]ATP. Previously, it was shown that the phosphatase activity of a truncated KdpD, KdpD/Delta12-395, is deregulated in vitro (Jung, K., and Altendorf, K. (1998) J. Biol. Chem. 273, 17406-17410). Here, we demonstrated that this effect was reversed in vesicles containing both the truncated KdpD and the N-terminal domain. Furthermore, coexpression of kdpD/Delta12-395 and kdpD/1-395 restored signal transduction in vivo. These results highlight the importance of the N-terminal domain for the function of KdpD and provide evidence for an interaction of this domain and the transmitter domain of the sensor kinase.     

Animal activity around the clock with no overt circadian rhythms: patterns,mechanisms and adaptive value

Circadian rhythms are ubiquitous in many organisms. Animals that are forced to be active around the clock typically show reduced performance, health and survival. Nevertheless, we review evidence of animals showing prolonged intervals of activity with attenuated or nil overt circadian rhythms and no apparent ill effects. We show that around-the-clock and ultradian activity patterns are more common than is generally appreciated, particularly in herbivores, in animals inhabiting polar regions and habitats with constant physical environments, in animals during specific life-history stages (such as migration or reproduction), and in highly social animals. The underlying mechanisms are diverse, but studies suggest that some circadian pacemakers continue to measure time in animals active around the clock. The prevalence of around-the-clock activity in diverse animals and habitats, and an apparent diversity of underlying mechanisms, are consistent with convergent evolution. We suggest that the basic organizational principles of the circadian system and its complexity encompass the potential for chronobiological plasticity. There may be trade-offs between benefits of persistent daily rhythms versus plasticity, which for reasons still poorly understood make overt daily arrhythmicity functionally adaptive only in selected habitats and for selected lifestyles.