4.6 Article

Ribonuclease T2 represents a distinct circularly permutated version of the BECR RNases

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PROTEIN SCIENCE
卷 32, 期 1, 页码 -

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WILEY
DOI: 10.1002/pro.4531

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AlphaFold; ancestral topology reconstruction; BECR fold; circular permutation; evolutionary origin; fold recognition; ribonuclease T2

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This study revealed that many proteins remain unclassified in current protein databases. By reconstructing the structure of RNase T2 and comparing it with other BECR RNases, a hidden relationship was discovered. This suggests that reconstruction and modeling of ancestral topology can be an effective strategy to identify remote relationships between proteins.
Detection of homologous relationships among proteins and understanding their mechanisms of diversification are major topics in the fields of protein science, bioinformatics, and phylogenetics. Recent developments in sequence/profile-based and structural similarity-based methods have greatly facilitated the unification and classification of many protein families into superfamilies or folds, yet many proteins remain unclassified in current protein databases. As one of the three earliest identified RNases in biology, ribonuclease T2, also known as RNase I in Escherichia coli, RNase Rh in fungi, or S-RNase in plant, is thought to be an ancient RNase family due to its widespread distribution and distinct structure. In this study, we present evidence that RNase T2 represents a circularly permutated version of the BECR (Barnase-EndoU-Colicin E5/D-RelE) fold RNases. This subtle relationship cannot be detected by traditional methods such as sequence/profile-based comparisons, structure-similarity searches, and circular permutation detections. However, we were able to identify the structural similarity using rational reconstruction of a theoretical RNase T2 ancestor via a reverse circular permutation process, followed by structural modeling using AlphaFold2, and structural comparisons. This relationship is further supported by the fact that RNase T2 and other typical BECR RNases, namely Colicin D, RNase A, and BrnT, share similar catalytic site configurations, all involving an analogous set of conserved residues on the alpha 0 helix and the beta 4 strand of the BECR fold. This study revealed a hidden root of RNase T2 in bacterial toxin systems and demonstrated that reconstruction and modeling of ancestral topology is an effective strategy to identify remote relationship between proteins.

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