Organisms are adapted to the relentless cycles of day and night, because they evolved timekeeping systems called circadian clocks, which regulate biological activities with ~24-h rhythms. The clock of cyanobacteria is driven by a three-protein oscillator comprised of KaiA, KaiB, and KaiC, which together generate a circadian rhythm of KaiC phosphorylation. We show that KaiB flips between two distinct three-dimensional folds, and its rare transition to an active state provides a time delay that is required to match the timing of the oscillator to that of earth’s rotation. Once KaiB switches folds, it binds phosphorylated KaiC and captures KaiA, initiating a phase transition of the circadian cycle, and regulates components of the clock-output pathway, providing the link that joins the timekeeping and signaling functions of the oscillator.
EYE2 is a key protein in connecting the positioning information of the microtubule rootlet cytoskeleton and channelrhodopsin 1 (ChR1) photoreceptor to the formation and positioning of the eyespot pigment granules in the chloroplast of Chlamydomonas. EYE3, a ser/thr kinase of the ABC1 family, is found in pigment granules and is required for their biogenesis.
The response regulator RpaB (regulator of phycobilisome associated B), part of an essential two-component system conserved in cyanobacteria that responds to multiple environmental signals, has recently been implicated in the control of cell dimensions and of circadian rhythms of gene expression in the model cyanobacterium Synechococcus elongatus PCC 7942. However, little is known of the molecular mechanisms that underlie RpaB functions. In this study we show that the regulation of phenotypes by RpaB is intimately connected with the activity of RpaA (regulator of phycobilisome associated A), the master regulator of circadian transcription patterns. RpaB affects RpaA activity both through control of gene expression, a function requiring an intact effector domain, and via altering RpaA phosphorylation, a function mediated through the N-terminal receiver domain of RpaB. Thus, both phosphorylation cross-talk and coregulation of target genes play a role in the genetic interactions between the RpaA and RpaB pathways. In addition, RpaB∼P levels appear critical for survival under light:dark cycles, conditions in which RpaB phosphorylation is environmentally driven independent of the circadian clock. We propose that the complex regulatory interactions between the essential and environmentally sensitive NblS-RpaB system and the SasA-RpaA clock output system integrate relevant extra-and intracellular signals to the circadian clock.signaling network | transcription regulation | chronobiology
Highlights d PA induces virulence-associated changes in CD-associated AIEC d PA-induced phenotype is reproducible in recently isolated clinical strains d Phenotypic changes are transcriptional in nature and reversible d Strains exposed to PA outcompete wild-type strains in a ''humanized'' murine model
Using circulating plasma hormone estimations, ovulation was monitored in bitches. The results obtained indicate that the timing of ovulation bears little relationship to alterations in sexual behaviour. The bitches were killed and reproductive tracts were removed at various intervals after ovulation and ova or embryos were recovered. The embryo stages were assessed visually and some were investigated histologically. Embryonic development, to early blastocyst stage, took place within the oviducts during the first 12 days after ovulation and there was a marked increase in size between the early and late blastocyst. A culture system using cells from the uterine tube supported the development of one 1-cell embryo to the morula stage.
The mechanisms by which cellular oscillators keep time and transmit temporal information are poorly understood. In cyanobacteria, the timekeeping aspect of the circadian oscillator, composed of the KaiA, KaiB, and KaiC proteins, involves a cyclic progression of phosphorylation states at Ser431 and Thr432 of KaiC. Elucidating the mechanism that uses this temporal information to modulate gene expression is complicated by unknowns regarding the number, structure, and regulatory effects of output components. To identify oscillator signaling states without a complete description of the output machinery, we defined a simple metric, Kai-complex output activity (KOA), that represents the difference in expression of reporter genes between strains that carry specific variants of KaiC and baseline strains that lack KaiC. In the absence of the oscillator, expression of the class 1 paradigm promoter P kaiBC was locked at its usual peak level; conversely, that of the class 2 paradigm promoter P purF was locked at its trough level. However, for both classes of promoters, peak KOA in wild-type strains coincided late in the circadian cycle near subjective dawn, when KaiC-pST becomes most prevalent (Ser431 is phosphorylated and Thr432 is not). Analogously, peak KOA was detected specifically for the phosphomimetic of KaiC-pST (KaiC-ET). Notably, peak KOA required KaiB, indicating that a KaiBC complex is involved in the output activity. We also found evidence that phosphorylated RpaA (regulator of phycobilisome associated) represses an RpaA-independent output of KOA. A simple mathematical expression successfully simulated two key features of the oscillator-the time of peak KOA and the peak-to-trough amplitude changes.bioluminescence | chronobiology | transcription regulation C ircadian biological clocks are recognized as endogenous 24-h timers that evolved through the selective fitness advantage they confer in anticipation of daily environmental variations and that generate rhythms in metabolic and behavioral processes (1-3). Both the ability to keep 24-h time and the mechanism by which such a clock regulates cellular processes are only partially understood in any organism. In the oxygenic photosynthetic bacteria known as cyanobacteria, the oscillator mechanism is a posttranslational protein interaction loop, and the nature of its temporal output signal is more easily addressable than in eukaryotic models. The recent report of a posttranslational circadian system that is shared among the kingdoms of life suggests a more universal role of posttranslational oscillators in nature (4, 5). Among the prokaryotic cyanobacteria, Synechococcus elongatus PCC 7942 is the prevalent model system for circadian studies due to its genetic manipulability and small (2.7 Mb) fully sequenced genome (6). The ability to monitor the circadian regulation of gene expression in vivo, achieved by fusing the promoter of a gene of interest to a bioluminescence reporter gene (7,8), provides a tool for investigating the circadian clock and its connections with m...
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