Quantifying the rhythm of KaiB-C interaction for in vitro cyanobacterial circadian clock

Quantifying the rhythm of KaiB-C interaction for in vitro cyanobacterial circadian clock

An oscillator consisting of KaiA, KaiB, and KaiC proteins comprises the core of cyanobacterial circadian clock. While one key reaction in this process--KaiC phosphorylation--has been extensively investigated and modeled, other key processes, such as the interactions among Kai proteins, are not under...

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Veröffentlicht in:PloS one 2012-08, Vol.7 (8), p.e42581-e42581
Hauptverfasser: Ma, Lan, Ranganathan, Rama
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Sprache:eng
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Analysis
Bacterial Proteins - metabolism
Biology
Circadian Clocks - physiology
Circadian rhythm
Circadian Rhythm - physiology
Circadian Rhythm Signaling Peptides and Proteins - metabolism
Circadian rhythms
Computer Simulation
Cyanobacteria
Cyanobacteria - metabolism
Delay
Energy transfer
Experiments
Feedback
Feedback loops
Fluorescence
Fluorescence resonance energy transfer
Gene expression
Kinases
Kinetics
Mathematical models
Mathematics
Medicine
Microscopy
Models, Biological
Negative feedback
Periodic variations
Periodicity
Phosphorylation
Protein Binding
Proteins
Reaction kinetics
Serine
Synechococcus elongatus
Tagging
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description An oscillator consisting of KaiA, KaiB, and KaiC proteins comprises the core of cyanobacterial circadian clock. While one key reaction in this process--KaiC phosphorylation--has been extensively investigated and modeled, other key processes, such as the interactions among Kai proteins, are not understood well. Specifically, different experimental techniques have yielded inconsistent views about Kai A, B, and C interactions. Here, we first propose a mathematical model of cyanobacterial circadian clock that explains the recently observed dynamics of the four phospho-states of KaiC as well as the interactions among the three Kai proteins. Simulations of the model show that the interaction between KaiB and KaiC oscillates with the same period as the phosphorylation of KaiC, but displays a phase delay of ∼8 hr relative to the total phosphorylated KaiC. Secondly, this prediction on KaiB-C interaction are evaluated using a novel FRET (Fluorescence Resonance Energy Transfer)-based assay by tagging fluorescent proteins Cerulean and Venus to KaiC and KaiB, respectively, and reconstituting fluorescent protein-labeled in vitro clock. The data show that the KaiB∶KaiC interaction indeed oscillates with ∼24 hr periodicity and ∼8 hr phase delay relative to KaiC phosphorylation, consistent with model prediction. Moreover, it is noteworthy that our model indicates that the interlinked positive and negative feedback loops are the underlying mechanism for oscillation, with the serine phosphorylated-state (the "S-state") of KaiC being a hub for the feedback loops. Because the kinetics of the KaiB-C interaction faithfully follows that of the S-state, the FRET measurement may provide an important real-time probe in quantitative study of the cyanobacterial circadian clock.
doi_str_mv 10.1371/journal.pone.0042581
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While one key reaction in this process--KaiC phosphorylation--has been extensively investigated and modeled, other key processes, such as the interactions among Kai proteins, are not understood well. Specifically, different experimental techniques have yielded inconsistent views about Kai A, B, and C interactions. Here, we first propose a mathematical model of cyanobacterial circadian clock that explains the recently observed dynamics of the four phospho-states of KaiC as well as the interactions among the three Kai proteins. Simulations of the model show that the interaction between KaiB and KaiC oscillates with the same period as the phosphorylation of KaiC, but displays a phase delay of ∼8 hr relative to the total phosphorylated KaiC. Secondly, this prediction on KaiB-C interaction are evaluated using a novel FRET (Fluorescence Resonance Energy Transfer)-based assay by tagging fluorescent proteins Cerulean and Venus to KaiC and KaiB, respectively, and reconstituting fluorescent protein-labeled in vitro clock. The data show that the KaiB∶KaiC interaction indeed oscillates with ∼24 hr periodicity and ∼8 hr phase delay relative to KaiC phosphorylation, consistent with model prediction. Moreover, it is noteworthy that our model indicates that the interlinked positive and negative feedback loops are the underlying mechanism for oscillation, with the serine phosphorylated-state (the "S-state") of KaiC being a hub for the feedback loops. 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While one key reaction in this process--KaiC phosphorylation--has been extensively investigated and modeled, other key processes, such as the interactions among Kai proteins, are not understood well. Specifically, different experimental techniques have yielded inconsistent views about Kai A, B, and C interactions. Here, we first propose a mathematical model of cyanobacterial circadian clock that explains the recently observed dynamics of the four phospho-states of KaiC as well as the interactions among the three Kai proteins. Simulations of the model show that the interaction between KaiB and KaiC oscillates with the same period as the phosphorylation of KaiC, but displays a phase delay of ∼8 hr relative to the total phosphorylated KaiC. Secondly, this prediction on KaiB-C interaction are evaluated using a novel FRET (Fluorescence Resonance Energy Transfer)-based assay by tagging fluorescent proteins Cerulean and Venus to KaiC and KaiB, respectively, and reconstituting fluorescent protein-labeled in vitro clock. The data show that the KaiB∶KaiC interaction indeed oscillates with ∼24 hr periodicity and ∼8 hr phase delay relative to KaiC phosphorylation, consistent with model prediction. Moreover, it is noteworthy that our model indicates that the interlinked positive and negative feedback loops are the underlying mechanism for oscillation, with the serine phosphorylated-state (the "S-state") of KaiC being a hub for the feedback loops. Because the kinetics of the KaiB-C interaction faithfully follows that of the S-state, the FRET measurement may provide an important real-time probe in quantitative study of the cyanobacterial circadian clock.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>22900029</pmid><doi>10.1371/journal.pone.0042581</doi><tpages>e42581</tpages><oa>free_for_read</oa></addata></record>
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subjects Analysis
Bacterial Proteins - metabolism
Biology
Circadian Clocks - physiology
Circadian rhythm
Circadian Rhythm - physiology
Circadian Rhythm Signaling Peptides and Proteins - metabolism
Circadian rhythms
Computer Simulation
Cyanobacteria
Cyanobacteria - metabolism
Delay
Energy transfer
Experiments
Feedback
Feedback loops
Fluorescence
Fluorescence resonance energy transfer
Gene expression
Kinases
Kinetics
Mathematical models
Mathematics
Medicine
Microscopy
Models, Biological
Negative feedback
Periodic variations
Periodicity
Phosphorylation
Protein Binding
Proteins
Reaction kinetics
Serine
Synechococcus elongatus
Tagging
title Quantifying the rhythm of KaiB-C interaction for in vitro cyanobacterial circadian clock
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