Abstract

Dipeptidyl peptidase 4 (DPP4) has been identified as the main receptor of MERS-CoV facilitating its cellular entry and enhancing its viral replication upon the emergence of this novel coronavirus. DPP4 receptor is highly conserved among many species, but the genetic variability among direct binding residues to MERS-CoV restrained its cellular tropism to humans, camels and bats. The occurrence of natural polymorphisms in human DPP4 binding residues is not well characterized. Therefore, we aimed to assess the presence of potential mutations in DPP4 receptor binding domain (RBD) among a population highly exposed to MERS-CoV in Morocco and predict their effect on DPP4 –MERS-CoV binding affinity through a computational approach. DPP4 synonymous and non-synonymous mutations were identified by sanger sequencing, and their effect were modelled by mutation prediction tools, docking and molecular dynamics (MD) simulation to evaluate structural changes in human DPP4 protein bound to MERS-CoV S1 RBD protein. We identified eight mutations, two synonymous mutations (A291 =, R317 =) and six non-synonymous mutations (N229I, K267E, K267N, T288P, L294V, I295L). Through docking and MD simulation techniques, the chimeric DPP4 –MERS-CoV S1 RBD protein complex models carrying one of the identified non-synonymous mutations sustained a stable binding affinity for the complex that might lead to a robust cellular attachment of MERS-CoV except for the DPP4 N229I mutation. The latter is notable for a loss of binding affinity of DPP4 with MERS-CoV S1 RBD that might affect negatively on cellular entry of the virus. It is important to confirm our molecular modelling prediction with in-vitro studies to acquire a broader overview of the effect of these identified mutations.

Highlights

  • The Middle East Respiratory Syndrome of Coronavirus (MERS-CoV) is a zoonotic enveloped single-strand positive RNA virus

  • Throughout this study, we aimed to identify a potential presence of mutations in Dipeptidyl peptidase 4 (DPP4) receptor binding domain among a population in Morocco highly exposed to dromedary camels and to MERS-CoV and predict their effect on DPP4 –MERS-CoV binding affinity through an in-silico approach

  • We report our results by addressing the effect of genetic variability of DPP4 receptor binding residues with MERS-CoV S1 receptor binding domain (RBD) protein in a human population with a significant exposure risk of infection with MERS-CoV via dromedaries

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Summary

Introduction

The Middle East Respiratory Syndrome of Coronavirus (MERS-CoV) is a zoonotic enveloped single-strand positive RNA virus. This novel emerging betacoronavirus was isolated for the first time in 2012 in a human patient with a severe pneumonia [1]. Dromedary camels have been identified as the zoonotic source for human MERS-CoV infection following close contact with these animals [3, 4]. Sporadic cases of MERS-CoV disease have so far been restricted to the Arabian peninsula [7]. MERS-CoV does appear to transmit asymptomatically in North and Sub-Saharan Africa as detected by a seroprevalence of neutralizing antibodies of 0.18% in comparison to the Arabian peninsula (0.72%) [8]. Since Africa has by far the largest numbers of dromedary camels, the lack of zoonotic disease is surprising [9]

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