Strauss H S, Burgess R R, Record M T
Biochemistry. 1980 Jul 22;19(15):3504-15. doi: 10.1021/bi00556a015.
In this paper we obtain thermodynamic and molecular information about the specific complexes formed between Escherichia coli RNA polymerase holoenzyme and a restriction fragment of T7 D111 DNA carrying the A1 and D promoters. Specific binding was observed at both 0 and 37 degrees C over a side range of pH values and ion concentrations [Strauss, H. S., Burgess, R. R., & Record, M. T., Jr. (1980) Biochemistry (first paper of four in this issue)]. The specific complexes formed at these two temperatures may correspond to the closed and open promoter complexes discussed by Chamberlin [Chamberlin, M. J. (1976) RNA Polymerase (Losick, R., & Chamberlin, M., Eds.) pp 159-161, Cold Spring Harbor Laboratory, cold Spring Harbor, NY]. Promoter binding constants KobsdRP are obtained from competition filter binding data by using a statistical analysis and previously determined values of the nonspecific holoenzyme-DNA binding constant KobsdRD. From the magnitudes of KobsdRP at 0 and 37 degrees C, and the dependences of these binding constants on pH and ion concentrations, we conclude that, under physiological ionic conditions, both the 0 and the 37 degrees C complexes are stabilized to a large extent by the formation of ionic interactions and the accompanying release of counterions and that one or two protonation events (pK approximately 7.4) are required for complex formation in both cases. However, the 0 and 37 degrees C complexes differ in their sensitivity to ion concentrations as well as in the magnitude of KobsdRP, and we conclude that the two complexes are distinct. (More counterion release accompanies formation of the 37 degrees C complex). Comparisons of the two complexes with one another and with nonspecific holoenzyme-DNA complexes are drawn from the binding data. We have also examined the equilibrium selectivity ratio (KobsdRP/DobsdRD) and find it to be a sensitive function of temperature and ionic conditions. Selectivity of holoenzyme for promoter sites on the promoter-containing fragment is higher at 37 degrees C than at 0 degrees C under the conditions investigated. Selectivity at either temperature is increased by reducing the pH (in the range 6.1-8.6). At 37 degrees C, selectivity is increased by reducing the salt concentration. Under approximately physiological conditions (0.2 M NaCl and 0.003 M MgCl2, pH 7.4, 37 degrees C), the equilibrium selectivity ratio is found to be of order of magnitude 10(4).
在本文中,我们获得了有关大肠杆菌RNA聚合酶全酶与携带A1和D启动子的T7 D111 DNA限制片段形成的特定复合物的热力学和分子信息。在0℃和37℃下,在较宽的pH值和离子浓度范围内均观察到特异性结合[施特劳斯,H.S.,伯吉斯,R.R.,& 雷科德,M.T.,Jr.(1980年)《生物化学》(本期四篇论文中的第一篇)]。在这两个温度下形成的特定复合物可能对应于钱伯林所讨论的封闭和开放启动子复合物[钱伯林,M.J.(1976年)《RNA聚合酶》(洛西克,R.,& 钱伯林,M.编)第159 - 161页,冷泉港实验室,纽约冷泉港]。通过统计分析以及先前确定的非特异性全酶 - DNA结合常数KobsdRD的值,从竞争过滤结合数据中获得启动子结合常数KobsdRP。根据0℃和37℃下KobsdRP的大小以及这些结合常数对pH和离子浓度的依赖性,我们得出结论,在生理离子条件下,0℃和37℃的复合物在很大程度上都通过离子相互作用的形成以及伴随的抗衡离子释放而得以稳定,并且在这两种情况下复合物形成都需要一到两个质子化事件(pK约为7.4)。然而,0℃和37℃的复合物在对离子浓度的敏感性以及KobsdRP的大小方面存在差异,我们得出结论这两种复合物是不同的。(37℃复合物的形成伴随着更多抗衡离子的释放)。从结合数据中对这两种复合物彼此之间以及与非特异性全酶 - DNA复合物进行了比较。我们还研究了平衡选择性比(KobsdRP/DobsdRD),发现它是温度和离子条件的敏感函数。在所研究的条件下,全酶对含启动子片段上启动子位点的选择性在37℃时高于0℃。通过降低pH值(在6.1 - 8.6范围内),在任一温度下选择性都会增加。在37℃时,通过降低盐浓度选择性会增加。在大约生理条件(0.2M NaCl和0.003M MgCl2,pH 7.4,37℃)下,发现平衡选择性比约为10⁴数量级。
