Inferring interaction partners from protein sequences using mutual information

Anne-Florence Raphaëlle Bitbol
2018
Article

Résumé

Functional protein-protein interactions are crucial in most cellular processes. They enable multi-protein complexes to assemble and to remain stable, and they allow signal transduction in various pathways. Functional interactions between proteins result in coevolution between the interacting partners, and thus in correlations between their sequences. Pairwise maximum-entropy based models have enabled successful inference of pairs of amino-acid residues that are in contact in the three-dimensional structure of multi-protein complexes, starting from the correlations in the sequence data of known interaction partners. Recently, algorithms inspired by these methods have been developed to identify which proteins are functional interaction partners among the paralogous proteins of two families, starting from sequence data alone. Here, we demonstrate that a slightly higher performance for partner identification can be reached by an approximate maximization of the mutual information between the sequence alignments of the two protein families. Our mutual information-based method also provides signatures of the existence of interactions between protein families. These results stand in contrast with structure prediction of proteins and of multi-protein complexes from sequence data, where pairwise maximum-entropy based global statistical models substantially improve performance compared to mutual information. Our findings entail that the statistical dependences allowing interaction partner prediction from sequence data are not restricted to the residue pairs that are in direct contact at the interface between the partner proteins.

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https://infoscience.epfl.ch/record/276043?ln=fr

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Anne-Florence Raphaëlle Bitbol
2018
Article

Résumé

Official source

https://infoscience.epfl.ch/record/276043?ln=fr

À propos de ce résultat

Concepts associés (16)

Concepts associés

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Publications associées (14)

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Publications associées (14)

Inferring interaction partners from protein sequences

Anne-Florence Raphaëlle Bitbol

Specific protein-protein interactions are crucial in the cell, both to ensure the formation and stability of multiprotein complexes and to enable signal transduction in various pathways. Functional interactions between proteins result in coevolution between the interaction partners, causing their sequences to be correlated. Here we exploit these correlations to accurately identify, from sequence data alone, which proteins are specific interaction partners. Our general approach, which employs a pairwise maximum entropy model to infer couplings between residues, has been successfully used to predict the 3D structures of proteins from sequences. Thus inspired, we introduce an iterative algorithm to predict specific interaction partners from two protein families whose members are known to interact. We first assess the algorithm's performance on histidine kinases and response regulators from bacterial two-component signaling systems. We obtain a striking 0.93 true positive fraction on our complete dataset without any a priori knowledge of interaction partners, and we uncover the origin of this success. We then apply the algorithm to proteins from ATP-binding cassette (ABC) transporter complexes, and obtain accurate predictions in these systems as well. Finally, we present two metrics that accurately distinguish interacting protein families from noninteracting ones, using only sequence data.

Proceedings of the National Academy of Sciences2016

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Author summary Many biologically important protein-protein interactions are conserved over evolutionary time scales. This leads to two different signals that can be used to computationally predict interactions between protein families and to identify specific interaction partners. First, the shared evolutionary history leads to highly similar phylogenetic relationships between interacting proteins of the two families. Second, the need to keep the interaction surfaces of partner proteins biophysically compatible causes a correlated amino-acid usage of interface residues. Employing simulated data, we show that the shared history alone can be used to detect partner proteins. Similar accuracies are achieved by algorithms comparing phylogenetic relationships and by methods based on Direct Coupling Analysis (DCA), which are primarily known for their ability to detect the second type of signal. Using natural sequence data, we show that in cases with shared evolutionary history but without known physical interactions, both methods work with similar accuracy, while for some physically interacting systems, DCA and mutual information outperform phylogenetic methods. We propose methods allowing both to predict interactions between protein families and to find interacting partners among paralogs. Determining which proteins interact together is crucial to a systems-level understanding of the cell. Recently, algorithms based on Direct Coupling Analysis (DCA) pairwise maximum-entropy models have allowed to identify interaction partners among paralogous proteins from sequence data. This success of DCA at predicting protein-protein interactions could be mainly based on its known ability to identify pairs of residues that are in contact in the three-dimensional structure of protein complexes and that coevolve to remain physicochemically complementary. However, interacting proteins possess similar evolutionary histories. What is the role of purely phylogenetic correlations in the performance of DCA-based methods to infer interaction partners? To address this question, we employ controlled synthetic data that only involve phylogeny and no interactions or contacts. We find that DCA accurately identifies the pairs of synthetic sequences that share evolutionary history. While phylogenetic correlations confound the identification of contacting residues by DCA, they are thus useful to predict interacting partners among paralogs. We find that DCA performs as well as phylogenetic methods to this end, and slightly better than them with large and accurate training sets. Employing DCA or phylogenetic methods within an Iterative Pairing Algorithm (IPA) allows to predict pairs of evolutionary partners without a training set. We further demonstrate the ability of these various methods to correctly predict pairings among real paralogous proteins with genome proximity but no known direct physical interaction, illustrating the importance of phylogenetic correlations in natural data. However, for physically interacting and strongly coevolving proteins, DCA and mutual information outperform phylogenetic methods. We finally discuss how to distinguish physically interacting proteins from proteins that only share a common evolutionary history.

2019

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Structural and functional analysis of host attachment proteins from contractile injection systems

Michel Plattner

Bacteriophages of the myoviridae family, R-type pyocin, Photorhabus virulence cassette (PVC), Serratia antifeeding prophage (Afp) and type 6 secretion system (T6SS) form a class of contractile injection systems that share common structural and functional components. The baseplate is a complex macromolecular structure that can change conformation. The tail is a rigid tube surrounded by a contractile sheath. They efficiently translocate genetic material (bacteriophages), deliver toxins into the external milieu or neighboring cells (PVC, Afp and T6SS) and efficiently kill competitor bacteria by depolarizing the membrane potential (Pyocin). The host range of bacteriophages or target spectrum of R-type pyocins, PVC, Afps is determined by filamentous tail fibers and more bulky tailspikes (TSP) that emanate from the baseplate. The recently discovered bacteriophage CBA120 encodes six putative host attachment proteins, of which four (named TSP1- TSP4) show some sequence similarity to known tailspikes. Despite four different proteins, CBA120 was found to be highly specific toward one host, namely E. coli O157:H7, a frequent contaminant of ground beef and a well-known human pathogen. In this work the crystallographic structure of TSP2, TSP3 and TSP4 are presented. In addition, functional assays suggest that CBA120 has at least three potential hosts. The structure of TSP1 was solved elsewhere but no activity was found towards E. coli O157:H7 or any other host. To better understand how the four TSP bind the phage particle, the TSP complex was formed in vitro and a new complex formation pathway was suggested. In addition to the CBA120, crystal structures of two TSP from Acinetobacter baumannii specific phages were solved. Acinetobacter baumannii is a highly drug resistant âflesh-eatingâ bacterium. Studies conducted with R-type pyocin show that its host specificity can be manipulated by changing the host attachment fiber. It was also shown that the native fiber protein could be exchanged for TSP proteins. In order to be incorporated in the pyocin particle, a new TSP can be fused to a 164 residue long N-terminal domain of the native fiber. This fragment is critical for maintaining the integrity of the baseplate and for transmitting the target surface binding signal to it. To obtain the structure of this fragment, we created a fusion of this domain with a well-crystallizable TSP. Several other proteins of the pyocin baseplate were cloned, expressed and purified. The result of these experiments was the determination of the crystal structure of the proteolytically stable fragment of PA0618, the largest protein of the pyocin baseplate. PA0618 is orthologous to T4 gp6, which is responsible of circularization of the baseplate. Taken together the structures of five previously unknown TSP and the proteolytically stable fragment of PA0618 were determined. The acquired structural information will help to better understand the relationship of peptide sequence, structure and function, in particular, the interaction of TSP and fiber proteins with polysaccharides that decorate the bacterial surface. Furthermore, all crystal structures reported here were determined by de novo phasing, and this structural information will further improve the ability to predict protein structure. Thanks to the enzymatic activity of the TSP proteins and their ability to specifically target bacterial cells, these proteins can be used in antimicrobial applications.

EPFL2018

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Structural and functional analysis of host attachment proteins from contractile injection systems

Michel Plattner

EPFL2018

2019