• 미생물학회지
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• 제46권4호
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• pp.313-318
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• 2010

D. radiodurans RecA 단백질은 DNA에 결합한 DNA-단백질 복합체만이 ATPase 활성을 나타내며. 보통의 낮은 염 농도조건에서는 DNA가 존재하지 않으면 RecA 단백질에 의한 ATP 가수분해는 거의 일어나지 않았으나 이러한 ATP 가수분해현상은 높은 농도의 염을 첨가하게 되면 1,000배 활성화 되었으며 1.6 M KCl이 존재할 때 ATP 혹은 dATP를 가수분해 하였다. DNA가 존재하지 않을 때 염에 의해 촉진되는 활성은 RecA 단백질 농도에 비례하였고, 더 높은 염농도에서 더 높은 ATP 가수분해 활성이 나타났다. 이러한 활성화 현상을 다양한 종류의 이온 형태에서 분석하였을 때 1.6 M Cl 음이온이 존재할 때 양이온의 형태에 따른 활성화 정도는 $K^+{\geq}Na^+$> $NH_4^+$의 경향을 보였으며, 1.6 M의 K 양이온 존재할 때 음이온의 형태에 따른 활성화는 glutamate > $Cl^-$ > acetate > $PO_4^-$의 순서로 높게 나타났다. 고농도의 염이 존재하는 조건에서 DNA 비의존성 ATPase의 활성은 비교적 넓은 범위 최적 조건인 pH7과 pH 8 사이에서 최대 활성을 보였고, 기질에 대한 친화도면에서도 외가닥 DNA 의존성 활성보다는 이중가닥 DNA 의존성 활성형태를 보였다. 고농도의 염이 첨가되고 DNA가 존재하지 않을 때 RecA 단백질에 의한 ATP 가수분해를 위한 RecA 단백질의 활성 종 형태는 최소 3개의 RecA 단백질이 결합되어 있는 과량체로 작용하는 것으로 나타났다.

• Bulletin of the Korean Chemical Society
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• 제35권10호
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• pp.3005-3008
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• 2014

Human ChlR1 protein (hChlR1), a member of the cohesion establishment factor family, plays an important role in the segregation of sister chromatids for maintenance of genome integrity. We previously reported that hChlR1 interacts with hFen1 and stimulates its nuclease activity on the flap-structured DNA substrate covered with RPA. To elucidate the relationship between hChlR1 and Okazaki fragment processing, the effect of hChlR1 on in vitro nuclease activities of hFen1 and hDna2 was examined. Independent of ATPase activity, hChlR1 stimulated endonuclease activity of hFen1 but not that of hDna2. Our findings suggest that the acceleration of Okazaki fragment processing near cohesions may aid in reducing the size of the replication machinery, thereby facilitating its entry through the cohesin ring.

• Molecules and Cells
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• 제40권12호
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• pp.925-934
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• 2017

The Cdc6 protein is essential for the initiation of chromosomal replication and functions as a licensing factor to maintain chromosome integrity. During the S and G2 phases of the cell cycle, Cdc6 has been found to inhibit the recruitment of pericentriolar material (PCM) proteins to the centrosome and to suppress centrosome over-duplication. In this report, we analyzed the correlation between these two functions of Cdc6 at the centrosome. Cdc6 depletion increased the population of cells showing centrosome over-duplication and premature centrosome separation; Cdc6 expression reversed these changes. Deletion and fusion experiments revealed that the 18 amino acid residues (197-214) of Cdc6, which were fused to the Cdc6-centrosomal localization signal, suppressed centrosome over-duplication and premature centrosome separation. Cdc6 mutant proteins that showed defective ATP binding or hydrolysis did not exhibit a significant difference in suppressing centrosome over-duplication, compared to the wild type protein. In contrast to the Cdc6-mediated inhibition of PCM protein recruitment to the centrosome, the independence of Cdc6 on its ATPase activity for suppressing centrosome over-duplication, along with the difference between the Cdc6 protein regions participating in the two functions, suggested that Cdc6 controls centrosome duplication in a manner independent of its recruitment of PCM proteins to the centrosome.