The evolutionary history of topological variations in the CPA/AT transporters.

Govindarajan Sudha,Claudio Bassot,Arne Elofsson,Nanjiang Shu,Yan Huang,John Lamb

doi:10.1371/journal.pcbi.1009278

Govindarajan Sudha, Claudio Bassot + Show 4 more

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https://doi.org/10.1371/journal.pcbi.1009278

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Abstract

CPA/AT transporters are made up of scaffold and a core domain. The core domain contains two non-canonical helices (broken or reentrant) that mediate the transport of ions, amino acids or other charged compounds. During evolution, these transporters have undergone substantial changes in structure, topology and function. To shed light on these structural transitions, we create models for all families using an integrated topology annotation method. We find that the CPA/AT transporters can be classified into four fold-types based on their structure; (1) the CPA-broken fold-type, (2) the CPA-reentrant fold-type, (3) the BART fold-type, and (4) a previously not described fold-type, the Reentrant-Helix-Reentrant fold-type. Several topological transitions are identified, including the transition between a broken and reentrant helix, one transition between a loop and a reentrant helix, complete changes of orientation, and changes in the number of scaffold helices. These transitions are mainly caused by gene duplication and shuffling events. Structural models, topology information and other details are presented in a searchable database, CPAfold (cpafold.bioinfo.se).

Highlights

Proteins belonging to the Putative Sulfate Exporter (PSE) family (Pfam) CPA/AT clan transport: ions, amino acids, and other charged compounds [1,2,3,4]
We explore the evolutionary mechanisms that have shaped the topological variations providing a deeper understanding of membrane protein structure and evolution
Proteins belonging to the Pfam CPA/AT clan transport: ions, amino acids, and other charged compounds [1,2,3,4]

Summary

Introduction

Proteins belonging to the Pfam CPA/AT clan (monovalent cation-proton antiporter/anion transporters) transport: ions, amino acids, and other charged compounds [1,2,3,4] Due to their functional importance, these transporters are ubiquitously present in all three kingdoms of life [3, 5,6,7]. In humans, these transporters are associated with pathological conditions such as intestinal bile acid malabsorption, ischemic and reperfusion injury, heart failure and cancer [8, 9]. PDB structures are available only for five families in the Pfam CPA/AT clan, with topologies starting from 10 transmembrane helices (TM) in the SBF family [13] to TM in Na+/H+ Antiporter 1 and OAD beta [14, 15], and TM of Na+/H+ Exchanger and 2HCT [6, 16]

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