Myelin protein zero (MPZ) gene encodes MPZ protein is a vital component of the myelin sheath. Mutationsassociated with MPZ gene leads to severe de-hypomyelination Dejerine-Sottas syndrome type B (DSSB) also termed as Charcot-Marie-Tooth disease (CMT) type 3. In this work, we employed a set of various in silico prediction methods to screen 97 nsSNPs associated with MPZ gene. Based on this, we identified the nsSNPs to be most deleterious and pathogenic associated with DSSB. To get more insight into the mutational effect at three-dimensional structural level, we modeled the homology structure of native type as well as I30T and I30M mutant of MPZ protein using Modeler 9.13 software. Molecular dynamics simulation was initiated to explain the impact of the mutation on its structure and function. The obtained results depict that the protein with I30T mutation had variable structural conformation and dynamic behavior than native and mutant I30M of MPZ protein. We hope our computational insight might be helpful in rationalizing the deleterious mutations in DSSB and the advancement of novel pharmacological strategy.

George Priya Doss C

Department of Integrative Biology

School of Bio Sciences and Technology

Vellore Campus

Agrahari A

Vellore Institute of Technology (VIT) is a private university located in&nbsp;Tamil Nadu, India. Founded in 1984, as Vellore Engineering College, the institution offers 20 undergraduate, 34 postgraduate, four integrated and four research programs. It has campuses in Vellore, Amravati, Bhopal and Chennai.

VIT is one of the top ranked private universities in India according to NIRF, THE and QS Rankings.&nbsp;Govt. of India has recognized&nbsp;VIT, Vellore as an&nbsp;Institution of Eminence. This has allowed VIT to take independent quality initiatives and move up in world ranking.

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VIT University

Journal of Theoretical Biology

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The impact of missense mutation in PIGA associated to paroxysmal nocturnal hemoglobinuria and multiple congenital anomalies-hypotonia-seizures syndrome 2: A computational study

The nucleotide salvage pathway is used to recycle degraded nucleotides (purines and pyrimidines); one of the enzymes that helps to recycle purines is hypoxanthine guanine phosphoribosyl transferase 1 (HGPRT1). Therefore, defects in this enzyme lead to the accumulation of DNA and nucleotide lesions and hence replication errors and genetic disorders. Missense mutations in hypoxanthine phosphoribosyl transferase 1 (HPRT1) are associated with deficiencies such as Lesch–Nyhan disease and chronic gout, which have manifestations such as arthritis, neurodegeneration, and cognitive disorders. In the present study, we collected 88 non-synonymous single nucleotide polymorphisms (nsSNPs) from the UniProt, dbSNP, ExAC, and ClinVar databases. We used a series of sequence-based and structure-based in silico tools to prioritize and characterize the most pathogenic and stabilizing or destabilizing nsSNPs. Moreover, to obtain the structural impact of the pathogenic mutations, we mapped the mutations to the crystal structure of the HPRT protein. We further subjected these mutant proteins to a 50 ns molecular dynamics simulation (MDS). The MDS trajectory showed that all mutant proteins altered the structural conformation and dynamic behavior of the HPRT protein and corroborated its association with LND and gout. This study provides essential information regarding the use of HPRT protein mutants as potential targets for therapeutic development. © 2019 Elsevier Ltd

Computers in Biology and Medicine

Understanding the structure-function relationship of HPRT1 missense mutations in association with Lesch–Nyhan disease and HPRT1-related gout by in silico mutational analysis

The NF1 gene encodes for neurofibromin protein, which is ubiquitously expressed, but most highly in the central nervous system. Non-synonymous SNPs (nsSNPs) in the NF1 gene were found to be associated with Neurofibromatosis Type 1 disease, which is characterized by the growth of tumors along nerves in the skin, brain, and other parts of the body. In this study, we used several in silico predictions tools to analyze 16 nsSNPs in the RAS-GAP domain of neurofibromin, the K1444N (K1423N) mutation was predicted as the most pathogenic. The comparative molecular dynamic simulation (MDS; 50 ns) between the wild type and the K1444N (K1423N) mutant suggested a significant change in the electrostatic potential. In addition, the RMSD, RMSF, Rg, hydrogen bonds, and PCA analysis confirmed the loss of flexibility and increase in compactness of the mutant protein. Further, SASA analysis revealed exchange between hydrophobic and hydrophilic residues from the core of the RAS-GAP domain to the surface of the mutant domain, consistent with the secondary structure analysis that showed significant alteration in the mutant protein conformation. Our data concludes that the K1444N (K1423N) mutant lead to increasing the rigidity and compactness of the protein. This study provides evidence of the benefits of the computational tools in predicting the pathogenicity of genetic mutations and suggests the application of MDS and different in silico prediction tools for variant assessment and classification in genetic clinics.

Metabolic Brain Disease

Computational insights of K1444N substitution in GAP-related domain of NF1 gene associated with neurofibromatosis type 1 disease: a molecular modeling and dynamics approach

Charcot-Marie-Tooth disease (CMT) is one of the most commonly inherited congenital neurological disorders, affecting approximately 1 in 2500 in the US. About 80 genes were found to be in association with CMT. The phosphoribosyl pyrophosphate synthetase 1 (PRPS1) is an essential enzyme in the primary stage of de novo and salvage nucleotide synthesis. The mutations in the PRPS1 gene leads to X-linked Charcot-Marie-Tooth neuropathy type 5 (CMTX5), PRS super activity, Arts syndrome, X-linked deafness-1, breast cancer, and colorectal cancer. In the present study, we obtained 20 missense mutations from UniProt and dbSNP databases and applied series of comprehensive in silico prediction methods to assess the degree of pathogenicity and stability. In silico tools predicted four missense mutations (D52H, M115 T, L152P, and D203H) to be potential disease causing mutations. We further subjected the four mutations along with native protein to 50 ns molecular dynamics simulation (MDS) using Gromacs package. The resulting trajectory files were analyzed to understand the stability differences caused by the mutations. We used the Root Mean Square Deviation (RMSD), Radius of Gyration (Rg), solvent accessibility surface area (SASA), Covariance matrix, Principal Component Analysis (PCA), Free Energy Landscape (FEL), and secondary structure analysis to assess the structural changes in the protein upon mutation. Our study suggests that the four mutations might affect the PRPS1 protein function and stability of the structure. The proposed study may serve as a platform for drug repositioning and personalized medicine for diseases that are caused by the PRPS1 deficiency. © 2017, Springer Science+Business Media, LLC.

A profound computational study to prioritize the disease-causing mutations in PRPS1 gene

X-linked Charcot-Marie-Tooth type 1 X (CMTX1) disease is a subtype of Charcot-Marie-Tooth (CMT), which is mainly caused by mutations in the GJB1 gene. It is also known as connexin 32 (Cx32) that leads to Schwann cell abnormalities and peripheral neuropathy. CMTX1 is considered as the second most common form of CMT disease. The aim of this study is to computationally predict the potential impact of different single amino acid substitutions at position 75 of Cx32, from arginine (R) to proline (P), glutamine (Q) and tryptophan (W). This position is known to be highly conserved among the family of connexin. To understand the structural and functional changes due to these single amino acid substitutions, we employed a homology-modeling technique to build the three-dimensional structure models for the native and mutant proteins. The protein structures were further embedded into a POPC lipid bilayer, inserted into a water box, and subjected to molecular dynamics simulation for 50 ns. Our results show that the mutants R75P, R75Q and R75W display variable structural conformation and dynamic behavior compared to the native protein. Our data proves useful in predicting the potential pathogenicity of the mutant proteins and is expected to serve as a platform for drug discovery for patients with CMT. © 2017 Elsevier Ltd

Substitution impact of highly conserved arginine residue at position 75 in GJB1 gene in association with X-linked Charcot–Marie-tooth disease: A computational study

Recent developments in high-throughput discovery and genotyping have generated a tremendous amount of information about the existence of single amino acid polymorphisms (SAPs). Detailed understanding of the SAPs that affect protein structure and function can provide us valuable insight into disease genotype-phenotype correlations. Functional variants of biological importance are likely to be missed in large-scale analysis. Over the past decade, numerous efforts are underway in understanding and characterizing the potential consequences of variants in assessing the risk associated with vitelliform macular dystrophy (VMD). Yet, in spite of this success, we conducted a first SAP analysis via evolutionary-based in silico pipeline to unravel functional SAPs from a pool, containing both functional and neutral ones. Furthermore, based on the prediction scores, a ranking system was developed to prioritize the functional SAPs in order to minimize the number of SAPs screened for further genotyping. © 2014 Elsevier Inc.

Advances in Protein Chemistry and Structural Biology

Application of Evolutionary Based in Silico Methods to Predict the Impact of Single Amino Acid Substitutions in Vitelliform Macular Dystrophy

Single amino acid substitutions (SAPs) belong to a class of SNPs in the coding region, which alter the protein function during the translation process. Storage of more information regarding SAPs in public databases will soon become a major hurdle in characterizing the functional SAPs. In such a demanding era, biology has to rely on bioinformatics, which can work its way through to solve the problems at hand by cutting huge amount of time and resources that are otherwise wasted. Here, we describe an overview of the existing repositories of variant databases and computational methods in predicting the effects of functional SAPs on protein stability, structure, function, drug response, and protein dynamics. This chapter will inspire many biologists with a greater promise in identifying the functional SAPs at the structural level, thereby understanding the molecular effects that are critical for personalized medicine diagnosis, prognosis, and treatment for diseases. © 2014 Elsevier Inc.

Journal	Data powered by TypesetJournal of Theoretical Biology
Publisher	Data powered by TypesetElsevier BV
ISSN	0022-5193
Open Access	No