A structural model of the E. coli PhoB Dimer in the transcription initiation complex

IF 2.222 Q3 Biochemistry, Genetics and Molecular Biology
Chang-Shung Tung, Benjamin H McMahon
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引用次数: 7

Abstract

There exist > 78,000 proteins and/or nucleic acids structures that were determined experimentally. Only a small portion of these structures corresponds to those of protein complexes. While homology modeling is able to exploit knowledge-based potentials of side-chain rotomers and backbone motifs to infer structures for new proteins, no such general method exists to extend our understanding of protein interaction motifs to novel protein complexes.

We use a Motif Binding Geometries (MBG) approach, to infer the structure of a protein complex from the database of complexes of homologous proteins taken from other contexts (such as the helix-turn-helix motif binding double stranded DNA), and demonstrate its utility on one of the more important regulatory complexes in biology, that of the RNA polymerase initiating transcription under conditions of phosphate starvation. The modeled PhoB/RNAP/σ-factor/DNA complex is stereo-chemically reasonable, has sufficient interfacial Solvent Excluded Surface Areas (SESAs) to provide adequate binding strength, is physically meaningful for transcription regulation, and is consistent with a variety of known experimental constraints.

Based on a straightforward and easy to comprehend concept, "proteins and protein domains that fold similarly could interact similarly", a structural model of the PhoB dimer in the transcription initiation complex has been developed. This approach could be extended to enable structural modeling and prediction of other bio-molecular complexes. Just as models of individual proteins provide insight into molecular recognition, catalytic mechanism, and substrate specificity, models of protein complexes will provide understanding into the combinatorial rules of cellular regulation and signaling.

Abstract Image

转录起始复合物中大肠杆菌PhoB二聚体的结构模型
存在>78000个蛋白质和/或核酸结构通过实验确定。这些结构中只有一小部分与蛋白质复合物的结构相对应。虽然同源建模能够利用基于知识的侧链旋转体和骨干基序的潜力来推断新蛋白质的结构,但没有这样的通用方法可以将我们对蛋白质相互作用基序的理解扩展到新的蛋白质复合物。我们使用Motif Binding Geometries (MBG)方法,从其他情况下的同源蛋白复合物数据库(如螺旋-转-螺旋基序结合双链DNA)中推断蛋白质复合物的结构,并证明其在生物学中更重要的调控复合物之一上的应用,即在磷酸盐饥饿条件下启动转录的RNA聚合酶。模拟的PhoB/RNAP/σ-因子/DNA复合物具有立体化学合理性,具有足够的界面溶剂排除表面积(SESAs)以提供足够的结合强度,对转录调控具有物理意义,并且符合各种已知的实验约束。基于一个简单易懂的概念,“折叠相似的蛋白质和蛋白质结构域可以相似地相互作用”,建立了转录起始复合物中PhoB二聚体的结构模型。这种方法可以扩展到其他生物分子复合物的结构建模和预测。正如单个蛋白质的模型提供了对分子识别、催化机制和底物特异性的深入了解,蛋白质复合物的模型将提供对细胞调节和信号传导的组合规则的理解。
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来源期刊
BMC Structural Biology
BMC Structural Biology 生物-生物物理
CiteScore
3.60
自引率
0.00%
发文量
0
期刊介绍: BMC Structural Biology is an open access, peer-reviewed journal that considers articles on investigations into the structure of biological macromolecules, including solving structures, structural and functional analyses, and computational modeling.
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