Determinants of specificity in two-component signal transduction

Maintaining the faithful flow of information through signal transduction pathways is critical to the survival and proliferation of organisms. This problem is particularly challenging as many signaling proteins are part of large, paralogous families that are highly similar at the sequence and structural levels, increasing the risk of unwanted cross-talk. To detect environmental signals and process information, bacteria rely heavily on two-component signaling systems comprised of sensor histidine kinases and their cognate response regulators. Although most species encode dozens of these signaling pathways, there is relatively little cross-talk, indicating that individual pathways are well insulated and highly specific. Here, we review the molecular mechanisms that enforce this specificity. Further, we highlight recent studies that have revealed how these mechanisms evolve to accommodate the introduction of new pathways by gene duplication.Howard Hughes Medical Institute (Early Career Scientist)National Science Foundation (U.S.) (NSF CAREER award (MCB-0844442))National Science Foundation (U.S.) (NSF Graduate Research Fellowship

Genome-wide association meta-analyses and fine-mapping elucidate pathways influencing albuminuria

Abstract: Increased levels of the urinary albumin-to-creatinine ratio (UACR) are associated with higher risk of kidney disease progression and cardiovascular events, but underlying mechanisms are incompletely understood. Here, we conduct trans-ethnic (n = 564,257) and European-ancestry specific meta-analyses of genome-wide association studies of UACR, including ancestry- and diabetes-specific analyses, and identify 68 UACR-associated loci. Genetic correlation analyses and risk score associations in an independent electronic medical records database (n = 192,868) reveal connections with proteinuria, hyperlipidemia, gout, and hypertension. Fine-mapping and trans-Omics analyses with gene expression in 47 tissues and plasma protein levels implicate genes potentially operating through differential expression in kidney (including TGFB1, MUC1, PRKCI, and OAF), and allow coupling of UACR associations to altered plasma OAF concentrations. Knockdown of OAF and PRKCI orthologs in Drosophila nephrocytes reduces albumin endocytosis. Silencing fly PRKCI further impairs slit diaphragm formation. These results generate a priority list of genes and pathways for translational research to reduce albuminuria

Genome-wide association meta-analyses and fine-mapping elucidate pathways influencing albuminuria

Increased levels of the urinary albumin-to-creatinine ratio (UACR) are associated with higher risk of kidney disease progression and cardiovascular events, but underlying mechanisms are incompletely understood. Here, we conduct trans-ethnic (n = 564,257) and European-ancestry specific meta-analyses of genome-wide association studies of UACR, including ancestry- and diabetes-specific analyses, and identify 68 UACR-associated loci. Genetic correlation analyses and risk score associations in an independent electronic medical records database (n = 192,868) reveal connections with proteinuria, hyperlipidemia, gout, and hypertension. Fine-mapping and trans-Omics analyses with gene expression in 47 tissues and plasma protein levels implicate genes potentially operating through differential expression in kidney (including TGFB1, MUC1, PRKCI, and OAF), and allow coupling of UACR associations to altered plasma OAF concentrations. Knockdown of OAF and PRKCI orthologs in Drosophila nephrocytes reduces albumin endocytosis. Silencing fly PRKCI further impairs slit diaphragm formation. These results generate a priority list of genes and pathways for translational research to reduce albuminuria

Pervasive degeneracy and epistasis in a protein-protein interface

Thesis: Ph. D., Massachusetts Institute of Technology, Computational and Systems Biology Program, 2014.Cataloged from PDF version of thesis.Includes bibliographical references.Signal transduction pathways rely on transient yet specific protein-protein interactions. How a limited set of amino acids can enforce cognate protein interactions while excluding undesired pairings remains poorly understood, even in cases where the contacting residues have been identified on both protein partners. To tackle this challenge, I performed structure-guided and library-based mutagenesis studies of bacterial two-component signaling pathways. These pathways, typically consisting of a histidine kinase and a response regulator, are an ideal model system for studying protein-protein interactions as they rely almost exclusively on molecular recognition for specificity. The kinase uses a limited set of residues to recognize the regulator in both phosphorylation and dephosphorylation reactions, and to prevent docking with all noncognate regulators. In this thesis I characterized the extent to which interface residues in two-component signaling proteins can be modified without changing the overall behavior of the pathway. In collaboration with another research group I have performed a mutagenesis study of a two-component system from Thermotoga maritima that has proven amenable to structural analysis. By solving the cocrystal structure of a histidine kinase and response regulator containing interface residues from a different interacting pair, we learned the biophysical basis for accommodating these new residues. To understand how many different residue combinations can support a functional interaction, I comprehensively mapped the sequence space of the interface formed by Escherichia coli histidine kinase PhoQ and its partner PhoP. I used a robust high-throughput assay to screen a library of 204 (160,000) PhoQ variants in which I had completely randomized the four key specificity-determining residues. Using deep sequencing, I identified -1,600 (1 %) variants that can phosphorylate and dephosphorylate PhoP as well as the wild-type PhoQ. Strikingly, PhoQ can interact with PhoP via many sets of interfacial residues that are completely different from the wild type. This combinatorial approach to mapping sequence space revealed interdependencies between individual amino acids, illustrating its power relative to screens that only examine substitutions at individual sites. This thesis provides a framework for mapping the sequence space of histidine kinases and has broad implications for understanding protein-protein interaction specificity and the evolution of bacterial signaling pathways.by Anna Igorevna Podgornaia.Ph. D

Structural basis of a rationally rewired protein-protein interface critical to bacterial signaling

Two-component signal transduction systems typically involve a sensor histidine kinase that specifically phosphorylates a single, cognate response regulator. This protein-protein interaction relies on molecular recognition via a small set of residues in each protein. To better understand how these residues determine the specificity of kinase-substrate interactions, we rationally rewired the interaction interface of a Thermotoga maritima two-component system, HK853-RR468, to match that found in a different two-component system, Escherichia coli PhoR-PhoB. The rewired proteins interacted robustly with each other, but no longer interacted with the parent proteins. Analysis of the crystal structures of the wild-type and mutant protein complexes and a systematic mutagenesis study reveal how individual mutations contribute to the rewiring of interaction specificity. Our approach and conclusions have implications for studies of other protein-protein interactions and protein evolution and for the design of novel protein interfaces. © 2013 Elsevier Ltd.This work was supported by an NSF CAREER award (MCB-0844442) to M.T.L., grants BIO2010-15424 from the Ministerio de Ciencia e Innovación and ACOMP2013/031 from Generalitat Valenciana to A.M., and NSF Graduate Research Fellowship to A.I.P. P.C. is recipient of a postdoctoral junior grant “Juan de la Cierva” from the Ministry of Economy and Competitiveness. The research leading to these results has received funding from the European Community's Seventh Framework Programme (FP7/2007-2013) under BioStruct-X (grant agreement number 283570).Peer Reviewe

Identification and experimental validation of splicing regulatory elements in Drosophila melanogaster reveals functionally conserved splicing enhancers in metazoans

It has been established that alternative and constitutive splicing decisions are dictated in part by cis-acting RNA sequences known as splicing enhancers or inhibitors. Both types of elements can be found either in exons or introns. Here, the authors have used computational methods to identify predicted intronic and exonic splicing enhancers in Drosophila. Many of these were previously shown to be enhancers of vertebrates. The evolutionary implications of these findings are discussed