Jezewska Maria J, Marcinowicz Agnieszka, Lucius Aaron L, Bujalowski Wlodzimierz
Department of Human Biological Chemistry and Genetics, Sealy Center for Structural Biology, The University of Texas Medical Branch at Galveston, 301 University Boulevard, Galveston, TX 77555-1053, USA.
J Mol Biol. 2006 Feb 10;356(1):121-41. doi: 10.1016/j.jmb.2005.10.061. Epub 2005 Nov 10.
Interactions of polymerase X from African swine fever virus with single-stranded DNA (ssDNA) have been studied, using quantitative fluorescence titration and analytical ultracentrifugation techniques. Experiments were performed with a fluorescent etheno-derivative of ssDNA oligomers. Studies of unmodified ssDNA oligomers were carried out using the competition titration method. The total site-size of the pol X-ssDNA complex is 16(+/-1) nucleotide residues. The large total ssDNA-binding site has a complex heterogeneous structure. It contains the proper ssDNA-binding site that encompasses only 7(+/-1) residues. As the length of the ssDNA increases, the enzyme engages an additional binding area in interactions with the DNA, at a distance of approximately 7-8 nucleotides from the proper site, which is located asymmetrically within the polymerase molecule. As a result, the net ion release accompanying the interactions with the DNA, increases from approximately 1 for the proper DNA-binding site to approximately 6 for the total DNA-binding site. Unlike in the case of the mammalian polymerase beta that belongs to the same polymerase X family, the DNA-binding areas within the total DNA-binding site of pol X are not autonomous. Consequently, the enzyme does not form different binding modes with different numbers of occluded nucleotide residues, although the interacting areas are structurally separated. The statistical thermodynamic model that accounts for the engagement of the proper and the total DNA-binding site in interactions with the DNA provides an excellent description of the binding process. Pol X binds the ssDNA without detectable cooperativity and with very modest base specificity.
利用定量荧光滴定和分析超速离心技术,对非洲猪瘟病毒聚合酶X与单链DNA(ssDNA)的相互作用进行了研究。实验使用了ssDNA寡聚物的荧光乙烯衍生物。未修饰的ssDNA寡聚物的研究采用竞争滴定法进行。pol X-ssDNA复合物的总结合位点大小为16(±1)个核苷酸残基。大的总ssDNA结合位点具有复杂的异质结构。它包含一个仅包含7(±1)个残基的合适的ssDNA结合位点。随着ssDNA长度的增加,酶在与DNA相互作用时会在距合适位点约7-8个核苷酸的距离处结合一个额外的结合区域,该区域不对称地位于聚合酶分子内。结果,与DNA相互作用时伴随的净离子释放从合适的DNA结合位点的约1增加到总DNA结合位点的约6。与属于同一聚合酶X家族的哺乳动物聚合酶β不同,pol X总DNA结合位点内的DNA结合区域不是自主的。因此,尽管相互作用区域在结构上是分开的,但酶不会与不同数量的封闭核苷酸残基形成不同的结合模式。考虑到合适的和总DNA结合位点与DNA相互作用的统计热力学模型对结合过程提供了很好的描述。Pol X结合ssDNA时没有可检测到的协同作用,且碱基特异性非常低。
