In silico analysis of the V66M variant of human BDNF in psychiatric disorders: An approach to precision medicine.

Clara Carolina Silva De Oliveira,Deborah Antunes,Joelma Freire De Mesquita,Jamile Yvis Santos De Alcantara,Ernesto Raul Caffarena,Gabriel Rodrigues Coutinho Pereira,Alexandre G De Brevern

doi:10.1371/journal.pone.0215508

Abstract

Brain-derived neurotrophic factor (BDNF) plays an important role in neurogenesis and synapse formation. The V66M is the most prevalent BDNF mutation in humans and impairs the function and distribution of BDNF. This mutation is related to several psychiatric disorders. The pro-region of BDNF, particularly position 66 and its adjacent residues, are determinant for the intracellular sorting and activity-dependent secretion of BDNF. However, it has not yet been fully elucidated. The present study aims to analyze the effects of the V66M mutation on BDNF structure and function. Here, we applied nine algorithms, including SIFT and PolyPhen-2, for functional and stability prediction of the V66M mutation. The complete theoretical model of BNDF was generated by Rosetta and validated by PROCHECK, RAMPAGE, ProSa, QMEAN and Verify-3D algorithms. Structural alignment was performed using TM-align. Phylogenetic analysis was performed using the ConSurf server. Molecular dynamics (MD) simulations were performed and analyzed using the GROMACS 2018.2 package. The V66M mutation was predicted as deleterious by PolyPhen-2 and SIFT in addition to being predicted as destabilizing by I-Mutant. According to SNPeffect, the V66M mutation does not affect protein aggregation, amyloid propensity, and chaperone binding. The complete theoretical structure of BDNF proved to be a reliable model. Phylogenetic analysis indicated that the V66M mutation of BDNF occurs at a non-conserved position of the protein. MD analyses indicated that the V66M mutation does not affect the BDNF flexibility and surface-to-volume ratio, but affects the BDNF essential motions, hydrogen-bonding and secondary structure particularly at its pre and pro-domain, which are crucial for its activity and distribution. Thus, considering that these parameters are determinant for protein interactions and, consequently, protein function; the alterations observed throughout the MD analyses may be related to the functional impairment of BDNF upon V66M mutation, as well as its involvement in psychiatric disorders.

Highlights

Psychiatric disorders are polygenic and multifactorial brain syndromes [1] characterized by clinically significant behavioral, psychological or biological dysfunction [2]
The results indicated that the V66M mutation does not alter these characteristics
Phylogenetic analysis indicated that position 66 of brain-derived neurotrophic factor (BDNF) is not conserved; it is fundamental for the intracellular sorting and activity-dependent secretion of the protein

Summary

Introduction

Psychiatric disorders are polygenic and multifactorial brain syndromes [1] characterized by clinically significant behavioral, psychological or biological dysfunction [2]. There is no consensus on the cause of psychiatric disorders [1,7], most studies suggest they are caused by neurotransmitters deregulation, genetic abnormalities, and defects in the structure or function of the brain [7]. In this context, non-synonymous mutations in the BDNF gene are implicated in the development of psychiatric disorders because they affect the function and distribution of brain-derived neurotrophic factor (BDNF), which is crucial for central nervous system development, neurogenesis and neuronal plasticity [8]

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Results

Discussion

Conclusion