Conversion between two conformational states of KaiC is induced by ATP hydrolysis as a trigger for cyanobacterial circadian oscillation

Oyama, Katsuaki; Azai, Chihiro; Nakamura, Kaori; Tanaka, Syun; Terauchi, Kazuki

doi:10.1038/srep32443

Cited by 33 publications

(75 citation statements)

References 35 publications

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“…These results suggest that KaiC WT 6mer was more stable than KaiC DD 6mer . It is consistent with a previous report showing that nonphosphorylated KaiC 6mer was more stable than phosphorylated KaiC 6mer (Oyama, Azai, Nakamura, Tanaka, & Terauchi, 2016).…”

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confidence: 94%

Atomic force microscopy analysis of SasA‐KaiC complex formation involved in information transfer from the KaiABC clock machinery to the output pathway in cyanobacteria

et al. 2018

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The cyanobacterial clock oscillator is composed of three clock proteins: KaiA, KaiB and KaiC. SasA, a KaiC-binding EnvZ-like orthodox histidine kinase involved in the main clock output pathway, exists mainly as a trimer (SasA ) and occasionally as a hexamer (SasA ) in vitro. Previously, the molecular mass of the SasA-KaiC complex, where KaiC is a mutant KaiC with two Asp substitutions at the two phosphorylation sites, has been estimated by gel-filtration chromatography to be larger than 670 kDa. This value disagrees with the theoretical estimation of 480 kDa for a SasA -KaiC hexamer (KaiC ) complex with a 1:1 molecular ratio. To clarify the structure of the SasA-KaiC complex, we analyzed KaiC with 0.1 mmol/L ATP and 5 mmol/L MgCl (Mg-ATP), SasA and a mixture containing SasA and KaiC with Mg-ATP by atomic force microscopy (AFM). KaiC images were classified into two types with height distribution corresponding to KaiC monomer (KaiC ) and KaiC , respectively. SasA images were classified into two types with height corresponding to SasA and SasA , respectively. The AFM images of the SasA-KaiC mixture indicated not only KaiC , KaiC , SasA and SasA , but also wider area "islands," suggesting the presence of a polymerized form of the SasA-KaiC complex.

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confidence: 94%

Atomic force microscopy analysis of SasA‐KaiC complex formation involved in information transfer from the KaiABC clock machinery to the output pathway in cyanobacteria

et al. 2018

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“…The digestion of 0.23 nmol of the Aβ fibrils using 22.5 pmol of nattokinase at 37°C, exhibited a time‐dependent increase up to 6 h, beyond which the effect of time remained insignificant (Figure b). In addition to nattokinase, neprilysin and matrix metalloprotease also degrade the Aβ fibrils . Thus, these enzymes are applicable for the degradation of Aβ fibrils in this method.…”

Section: Resultsmentioning

confidence: 99%

“…Figure 3 displays changes in the Aβ 42 fibrils content at the cathode end of the non-denaturing agarose gel electrophoresis for: (a) 0.23 nmol of Aβ 42 fibrils incubated with 0, 4.5, 9.0, 22.5, and 45 pmol of nattokinase at 37 • C for 24 h, and (Figure 3b). In addition to nattokinase, neprilysin and matrix metalloprotease also degrade the Aβ fibrils [12][13][14]. Thus, these enzymes are applicable for the degradation of Aβ fibrils in this method.…”

Section: Separation and Degradation Of A Fibrilsmentioning

confidence: 99%

Analysis of the degradation of amyloid beta fibrils after separation via the combination of non‐denaturing agarose electrophoresis and Congo red dye staining

Kawano

Nakanishi

Zako

et al. 2019

Separation Science Plus

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A combinational method for the separation and the degradation of amyloid‐β fibrils in the biological samples is developed to suppress the amyloid‐β fibrils content. The complexes of the Congo red dye and amyloid‐β fibrils migrate to the anode in a non‐denaturing agarose electrophoresis owing to its negative charge, thus separating the complex containing amyloid‐β fibrils from the human plasma proteins and the amyloid‐β monomer. The separated amyloid‐β fibrils exhibited birefringence under a polarizing microscope and immunoreactivity to the anti‐amyloid‐β antibody. The digestion of 0.23 nmol of the amyloid‐β fibrils using nattokinase at 37°C for 24 h increased with the amount of enzyme up to 9 pmol, beyond which the digestion was independent of the enzyme concentration. The digestion of 0.23 nmol of the amyloid‐β fibrils with 22.5 pmol of nattokinase at 37°C increased with time up to 6 h, following which, it became independent of time. The extraction of the separated amyloid‐β fibrils from the agarose gel accompanied the removal of major plasma proteins from the spiked plasma and amyloid‐β fibrils. The combination of the non‐denaturing agarose gel electrophoresis and the dye staining would be applicable to examine formation and degradation processes of amyloid‐β fibrils after their separation from the biological samples.

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“…Plasmids for the overexpression of the two CII KaiC variants, CII KaiC DE and CII KaiC AA , were constructed independently of the plasmid for CII KaiC as follows. The region corresponding to the KaiC CII domain (Leu249‐Ser519) was amplified by PCR using two plasmids as templates that were used for the overexpression of KaiC‐DE and KaiC‐AA proteins in the previous work . The PCR fragments were cloned into the Bsa I site of pASK‐IBA‐5plus to overexpress CII KaiC DE and CII KaiC AA as N‐terminal Strep‐tag fusion proteins.…”

Section: Methodsmentioning

confidence: 99%

Phosphorylation at Thr432 induces structural destabilization of the CII ring in the circadian oscillator KaiC

et al. 2017

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KaiC is the central oscillator protein in the cyanobacterial circadian clock. KaiC oscillates autonomously between phosphorylated and dephosphorylated states on a 24-h cycle in vitro by mixing with KaiA and KaiB in the presence of ATP. KaiC forms a C 6 -symmetrical hexamer, which is a double ring structure of homologous N-terminal and C-terminal domains termed CI and CII, respectively. Here, through the characterization of an isolated CII domain protein, CII KaiC , we show that phosphorylation of KaiC Thr432 destabilizes the hexameric state of the CII ring to a monomeric state. The results suggest that the stable hexameric CI ring acts as a molecular bundle to hold the CII ring, which undergoes dynamic structural changes upon phosphorylation.

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Conversion between two conformational states of KaiC is induced by ATP hydrolysis as a trigger for cyanobacterial circadian oscillation

Cited by 33 publications

References 35 publications

Atomic force microscopy analysis of SasA‐KaiC complex formation involved in information transfer from the KaiABC clock machinery to the output pathway in cyanobacteria

Atomic force microscopy analysis of SasA‐KaiC complex formation involved in information transfer from the KaiABC clock machinery to the output pathway in cyanobacteria

Analysis of the degradation of amyloid beta fibrils after separation via the combination of non‐denaturing agarose electrophoresis and Congo red dye staining

Phosphorylation at Thr432 induces structural destabilization of the CII ring in the circadian oscillator KaiC

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