Your search keyword '"Elango, Ramu"' showing total 7 results

1. Molecular insights into the coding region mutations of low-density lipoprotein receptor adaptor protein 1 (LDLRAP1) linked to familial hypercholesterolemia.

Author

Shaik NA, Al-Qahtani F, Nasser K, Jamil K, Alrayes NM, Elango R, Awan ZA, and Banaganapalli B

Subjects

Adaptor Proteins, Signal Transducing chemistry, Amino Acid Substitution, Computational Biology methods, Databases, Genetic, Genotype, Humans, Models, Molecular, Mutation, Missense, Phenotype, Protein Binding, ROC Curve, Structure-Activity Relationship, Adaptor Proteins, Signal Transducing genetics, Genetic Association Studies methods, Genetic Predisposition to Disease, Hyperlipoproteinemia Type II diagnosis, Hyperlipoproteinemia Type II genetics, Mutation, Open Reading Frames

Abstract

Background: Familial hypercholesterolemia (FH) is a lipid disorder caused by pathogenic mutations in LDLRAP1 gene. The present study has aimed to deepen our understanding about the pathogenicity predictions of FH causative genetic mutations, as well as their relationship to phenotype changes in LDLRAP1 protein, by utilizing multidirectional computational analysis., Methods: FH linked LDLRAP1 mutations were mined from databases, and the prediction ability of several pathogenicity classifiers against these clinical variants, was assessed through different statistical measures. Furthermore, these mutations were 3D modelled in protein structures to assess their impact on protein phenotype changes., Results: Our findings suggest that Polyphen-2, when compared with SIFT, M-CAP and CADD tools, can make better pathogenicity predictions for FH causative LDLRAP1 mutations. Through, 3D simulation and superimposition analysis of LDLRAP1 protein structures, it was found that missense mutations do not create any gross changes in the protein structure, although they could induce subtle structural changes at the level of amino acid residues. Near native molecular dynamic analysis revealed that missense mutations could induce variable degrees of fluctuation differences guiding the protein flexibility. Stability analysis showed that most missense mutations shifts the free energy equilibrium and hence they destabilize the protein. Molecular docking analysis demonstrates the molecular shifts in hydrogen and ionic bonds and Van der waals bonding properties, which further cause differences in the binding energy of LDLR-LDLRAP1 proteins., Conclusions: The diverse computational approaches used in the present study may provide a new dimension for exploring the structure-function relationship of the novel and deleterious LDLRAP1 mutations linked to FH., (© 2020 John Wiley & Sons, Ltd.)

Published

2020

2. Protein phenotype diagnosis of autosomal dominant calmodulin mutations causing irregular heart rhythms.

Author

Shaik NA, Awan ZA, Verma PK, Elango R, and Banaganapalli B

Subjects

Arrhythmias, Cardiac metabolism, Arrhythmias, Cardiac physiopathology, Binding Sites, Calcium metabolism, Calmodulin genetics, Calmodulin metabolism, Cations, Divalent, Databases, Protein, EF Hand Motifs, Gene Expression, Genes, Dominant, Genotype, Humans, Machine Learning, Phenotype, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Isoforms chemistry, Protein Isoforms genetics, Protein Isoforms metabolism, Protein Structure, Tertiary, ROC Curve, Arrhythmias, Cardiac genetics, Calcium chemistry, Calmodulin chemistry, Molecular Docking Simulation, Mutation

Abstract

The life-threatening group of irregular cardiac rhythmic disorders also known as Cardiac Arrhythmias (CA) are caused by mutations in highly conserved Calmodulin (CALM/CaM) genes. Herein, we present a multidimensional approach to diagnose changes in phenotypic, stability, and Ca 2+ ion binding properties of CA-causing mutations. Mutation pathogenicity was determined by diverse computational machine learning approaches. We further modeled the mutations in 3D protein structure and analyzed residue level phenotype plasticity. We have also examined the influence of torsion angles, number of H-bonds, and free energy dynamics on the stability, near-native simulation dynamic potential of residue fluctuations in protein structures, Ca 2+ ion binding potentials, of CaM mutants. Our study recomends to use M-CAP method for measuring the pathogenicity of CA causing CaM variants. Interestingly, most CA-causing variants we analyzed, exists in either third (V/H-96, S/I-98, V-103) or fourth (G/V-130, V/E/H-132, H-134, P-136, G-141, and L-142) EF-hands located in carboxyl domains of the CaM molecule. We observed that the minor structural fluctuations caused by these variants are likely tolerable owing to the highly flexible nature of calmodulin's globular domains. However, our molecular docking results supports that these variants disturb the affinity of CaM toward Ca 2+ ions and corroborate previous findings from functional studies. Taken together, these computational findings can explain the molecular reasons for subtle changes in structure, flexibility, and stability aspects of mutant CaM molecule. Our comprehensive molecular scanning approach demonstrates the utility of computational methods in quick preliminary screening of CA- CaM mutations before undertaking time consuming and complicated functional laboratory assays., (© 2018 Wiley Periodicals, Inc.)

Published

2018

3. A Computational Protein Phenotype Prediction Approach to Analyze the Deleterious Mutations of Human MED12 Gene.

Author

Banaganapalli B, Mohammed K, Khan IA, Al-Aama JY, Elango R, and Shaik NA

Subjects

Amino Acid Substitution, Computer Simulation, Humans, Protein Domains, Structure-Activity Relationship, Mediator Complex chemistry, Mediator Complex genetics, Mediator Complex metabolism, Mutation, Proteolysis

Abstract

Genetic mutations in MED12, a subunit of Mediator complex are seen in a broad spectrum of human diseases. However, the underlying basis of how these pathogenic mutations elicit protein phenotype changes in terms of 3D structure, stability and protein binding sites remains unknown. Therefore, we aimed to investigate the structural and functional impacts of MED12 mutations, using computational methods as an alternate to traditional in vivo and in vitro approaches. The MED12 gene mutations details and their corresponding clinical associations were collected from different databases and by text-mining. Initially, diverse computational approaches were applied to categorize the different classes of mutations based on their deleterious impact to MED12. Then, protein structures for wild and mutant types built by integrative modeling were analyzed for structural divergence, solvent accessibility, stability, and functional interaction deformities. Finally, this study was able to identify that genetic mutations mapped to exon-2 region, highly conserved LCEWAV and Catenin domains induce biochemically severe amino acid changes which alters the protein phenotype as well as the stability of MED12-CYCC interactions. To better understand the deleterious nature of FS-IDs and Indels, this study asserts the utility of computational screening based on their propensity towards non-sense mediated decay. Current study findings may help to narrow down the number of MED12 mutations to be screened for mediator complex dysfunction associated genetic diseases. This study supports computational methods as a primary filter to verify the plausible impact of pathogenic mutations based on the perspective of evolution, expression and phenotype of proteins. J. Cell. Biochem. 117: 2023-2035, 2016. © 2016 Wiley Periodicals, Inc., (© 2016 Wiley Periodicals, Inc.)

Published

2016

4. Evidence for the presence of somatic mitochondrial DNA mutations in right atrial appendage tissues of coronary artery disease patients.

Author

Matam K, Shaik NA, Aggarwal S, Diwale S, Banaganapalli B, Al-Aama JY, Elango R, Rao P, and Hasan Q

Subjects

Atrial Appendage, Biopsy, Electron Transport Complex IV genetics, Female, Genes, Mitochondrial genetics, Humans, Male, Middle Aged, Mitochondria genetics, Models, Molecular, Oxidative Phosphorylation, Sequence Analysis, DNA, Coronary Artery Disease genetics, DNA, Mitochondrial genetics, Genome, Mitochondrial genetics, Mutation, Plaque, Atherosclerotic genetics

Abstract

Coronary artery disease (CAD) is a multifactorial disease with the underlying involvement of environment, life style and nuclear genetics. However, the role of extranuclear genetic material in terms of somatically acquired mutations in mitochondrial tRNA and protein coding genes in the initiation or progression of CAD is not well defined. Hence, in the present study, right atrial appendage tissues and matched blood samples of 150 CAD patients were screened for mutations in nucleotide regions encompassing the Cytochrome c oxidase subunit II (MT-CO2), tRNA lysine (MT-TK), ATP synthase F0 subunit 8 (MT-ATP8) and Cytochrome b (MT-CYB) genes of mitochondrial DNA. We have found 9 different somatic mutations in 6 % of the CAD patients. Out of these mutations, 4 each were localized in MT-TK gene (T8324A, A8326G, A8331G and A8344G) and MT-CYB genes (T15062C, C15238A, T15378G and C15491G) in addition to one mutation in non-coding region 7 (A8270T) of mitochondrial genome. In addition, we noticed that majority (85.3 %) of CAD patients showed double repeats of germ-line "CCCCCTCTA" intergenic sequence between MT-CO2 and MT-TK genes. Our in-silico investigations of missense mutations revealed that they may alter the free energy and stability of polypeptide chains of MT-CYB protein of complex III of mitochondrial respiratory chain. Based on our study findings, we hypothesize that the somatically acquired variations in MT-TK and MT-CYB genes may negatively impact the energy metabolism of cardiomyocytes in right atrial appendage tissues and contribute in the cardiac dysfunction among CAD patients. In conclusion, our findings may be likely to have potential implications in understanding the disease pathophysiology, diagnosis as well as for the better therapeutic management of CAD patients.

Published

2014

5. Structural and functional characterization of pathogenic non- synonymous genetic mutations of human insulin-degrading enzyme by in silico methods.

Author

Shaik NA, Kaleemuddin M, Banaganapalli B, Khan F, Shaik NS, Ajabnoor G, Al-Harthi SE, Bondagji N, Al-Aama JY, and Elango R

Subjects

Humans, Protein Structure, Secondary, Substrate Specificity, Alzheimer Disease genetics, Computer Simulation, Diabetes Mellitus, Type 2 genetics, Insulysin genetics, Models, Molecular, Mutation genetics

Abstract

Insulin-degrading enzyme (IDE) is a key protease involved in degrading insulin and amyloid peptides in human body. Several non-synonymous genetic mutations of IDE gene have been recently associated with susceptibility to both diabetes and Alzheimer's diseases. However, the consequence of these mutations on the structure of IDE protein and its substrate binding characteristics is not well elucidated. The computational investigation of genetic mutation consequences on structural level of protein is recently found to be an effective alternate to traditional in vivo and in vitro approaches. Hence, by using a combination of empirical rule and support vector machine based in silico algorithms, this study was able to identify that the pathogenic nonsynonymous genetic mutations corresponding to p.I54F, p.P122T, p.T533R, p.P581A and p.Y609A have more potential role in structural and functional deviations of IDE activity. Moreover, molecular modeling and secondary structure analysis have also confirmed their impact on the stability and secondary properties of IDE protein. The molecular docking analysis of IDE with combinational substrates has revealed that peptide inhibitors compared to small non-peptide inhibitor molecules possess good inhibitory activity towards mutant IDE. This finding may pave a way to design novel potential small peptide inhibitors for mutant IDE. Additionally by un-translated region (UTR) scanning analysis, two regulatory pathogenic genetic mutations i.e., rs5786997 (3' UTR) and rs4646954 (5' UTR), which can influence the translation pattern of IDE gene through sequence alteration of upstream-Open Reading Frame and Internal Ribosome Entry Site elements were identified. Our findings are expected to help in narrowing down the number of IDE genetic variants to be screened for disease association studies and also to select better competitive inhibitors for IDE related diseases.

Published

2014

6. Diagnostic Revolution Post-Human Genome Sequence Project: High-Throughput Technologies and Bioinformatics

Author

Shaik, Noor Ahmad, Banaganapalli, Babajan, Al-Aama, Jumana Y., Elango, Ramu, Shaik, Noor Ahmad, editor, Hakeem, Khalid Rehman, editor, Banaganapalli, Babajan, editor, and Elango, Ramu, editor

Published

2019

7. Whole exome sequencing of a consanguineous family identifies the possible modifying effect of a globally rare AK5 allelic variant in celiac disease development among Saudi patients.

Author

Al-Aama, Jumana Yousuf, Shaik, Noor Ahmad, Banaganapalli, Babajan, Salama, Mohammed A., Rashidi, Omran, Sahly, Ahmed N., Mohsen, Mohammed O., Shawoosh, Harbi A., Shalabi, Hebah Ahmad, Edreesi, Mohammad Al, Alharthi, Sameer E., Wang, Jun, Elango, Ramu, and Saadah, Omar I.

Subjects

CELIAC disease, NUCLEOSIDE diphosphate kinases, EXOMES, GENETIC mutation, GENETICS, DISEASE risk factors

Abstract

Celiac disease (CD), a multi-factorial auto-inflammatory disease of the small intestine, is known to occur in both sporadic and familial forms. Together HLA and Non-HLA genes can explain up to 50% of CD’s heritability. In order to discover the missing heritability due to rare variants, we have exome sequenced a consanguineous Saudi family presenting CD in an autosomal recessive (AR) pattern. We have identified a rare homozygous insertion c.1683_1684insATT, in the conserved coding region of AK5 gene that showed classical AR model segregation in this family. Sequence validation of 200 chromosomes each of sporadic CD cases and controls, revealed that this extremely rare (EXac MAF 0.000008) mutation is highly penetrant among general Saudi populations (MAF is 0.62). Genotype and allelic distribution analysis have indicated that this AK5 (c.1683_1684insATT) mutation is negatively selected among patient groups and positively selected in the control group, in whom it may modify the risk against CD development [p<0.002]. Our observation gains additional support from computational analysis which predicted that Iso561 insertion shifts the existing H-bonds between 400th and 556th amino acid residues lying near the functional domain of adenylate kinase. This shuffling of amino acids and their H-bond interactions is likely to disturb the secondary structure orientation of the polypeptide and induces the gain-of-function in nucleoside phosphate kinase activity of AK5, which may eventually down-regulates the reactivity potential of CD4+ T-cells against gluten antigens. Our study underlines the need to have population-specific genome databases to avoid false leads and to identify true candidate causal genes for the familial form of celiac disease. [ABSTRACT FROM AUTHOR]

Published

2017