Novel MYBPC3 Mutations in Indian Population with Cardiomyopathies.

Background: Mutations in Myosin Binding Protein C (MYBPC3) are one of the most frequent causes of cardiomyopathies in the world, but not much data are available in India. Methods: We carried out targeted direct sequencing of MYBPC3 in 115 hypertrophic (HCM) and 127 dilated (DCM) cardiomyopathies against 197 ethnically matched healthy controls from India. Results: We detected 34 single nucleotide variations in MYBPC3, of which 19 were novel. We found a splice site mutation [(IVS6+2T) T>G] and 16 missense mutations in Indian cardiomyopathies [5 in HCM; E258K, T262S, H287L, R408M, V483A: 4 in DCM; T146N, V321L, A392T, E393K and 7 in both HCM and DCM; L104M, V158M, S236G, R272C, T290A, G522E, A626V], but those were absent in 197 normal healthy controls. Interestingly, we found 7 out of 16 missense mutations (V158M, E258K, R272C, A392T, V483A, G522E, and A626V) in MYBPC3 were altering the evolutionarily conserved native amino acids, accounted for 8.7% and 6.3% in HCM and DCM, respectively. The bioinformatic tools predicted that those 7 missense mutations were pathogenic. Moreover, the co-segregation of those 7 mutations in families further confirmed their pathogenicity. Remarkably, we also identified compound mutations within the MYBPC3 gene of 6 cardiomyopathy patients (5%) with more severe disease phenotype; of which, 3 were HCM (2.6%) [(1. K244K + E258K + (IVS6+2T) T>G); (2. L104M + G522E + A626V); (3. P186P + G522E + A626V]; and 3 were DCM (2.4%) [(1. 5'UTR + A392T; 2. V158M+G522E; and 3.V158M + T262T + A626V]. Conclusion: The present comprehensive study on MYBPC3 has revealed both single and compound mutations in MYBPC3 and their association with disease in Indian Population with Cardiomyopathies. Our findings may perhaps help in initiating diagnostic strategies and eventually recognizing the targets for therapeutic interventions.

Novel Mutations in ß-MYH7 Gene in Indian Patients With Dilated Cardiomyopathy.

BACKGROUND: Heart failure is a hallmark of severe hypertrophic cardiomyopathy and dilated cardiomyopathy (DCM). Several mutations in the ß-MYH7 gene lead to hypertrophic cardiomyopathy. Recently, causative mutations in the ß-MYH7 gene have also been detected in DCM from different populations. METHODS: Here, we sequenced the ß-MYH7 gene in 137 Indian DCM patients and 167 ethnically matched healthy controls to detect the frequency of mutations and their association. RESULTS: Our study revealed 27 variations, of which 7 mutations (8.0%) were detected exclusively in Indian DCM patients for the first time. These included 4 missense mutations-Arg723His, Phe510Leu, His358Leu, and Ser384Tyr (2.9%); a frameshift mutation-Asn676_T-del (1.5%); and 2 splice-site mutations (IVS17+2T) T>G and (IVS19-1G) G>A (3.6%). Remarkably, all 4 missense mutations altered evolutionarily conserved amino acids. All 4 missense mutations were predicted to be pathogenic by 2 bioinformatics tools-polymorphism phenotyping v2 (PolyPhen-2) and sorting intolerant from tolerant (SIFT). In addition, the 4 homology models of ß-MYH7-p.Leu358, p.Tyr384, p.Leu510, and p.His723-displayed root-mean-square deviations of ∼2.55 Å, ∼1.24 Å, ∼3.36 Å, and ∼3.86 Å, respectively. CONCLUSIONS: In the present study, we detected numerous novel, unique, and rare mutations in the ß-MYH7 gene exclusively in Indian DCM patients (8.0%). Here, we demonstrated how each mutant (missense) uniquely disrupts a critical network of non-bonding interactions at the mutation site (molecular level) and may contribute to development of dilated cardiomyopathy (DCM). Therefore, our findings may provide insight into the understanding of the molecular bases of disease and into diagnosis along with promoting novel therapeutic strategies (through personalized medicine).

INTRODUCTION: L'insuffisance cardiaque est une caractéristique de la cardiomyopathie hypertrophique grave et de la cardiomyopathie dilatée (CMD). Plusieurs mutations dans le gène ß-MYH7 conduisent à la cardiomyopathie hypertrophique. Récemment, les mutations causales dans le gène ß-MYH7 ont également été détectées au sein de différentes populations atteintes de CMD. MÉTHODES: Ici, nous avons séquencé le gène ß-MYH7 de 137 patients indiens atteints de CMD et de 167 témoins sains appariés selon l'origine ethnique pour détecter la fréquence des mutations et leur association. RÉSULTATS: L'étude nous a permis de révéler 27 variations, dont sept mutations (8,0 %) étaient exclusivement détectées chez les patients indiens atteints de CMD pour la première fois. Parmi ces mutations, nous avons observé quatre mutations faux-sens­Arg723His, Phe510Leu, His358Leu et Ser384Tyr (2,9 %), une mutation par déphasage­Asn676_T-del (1,5 %) et deux mutations des sites d'épissage (IVS17+2T) T>G et (IVS19-1G) G>A (3,6 %). Étonnamment, les quatre mutations faux-sens changeaient les acides aminés évolutivement conservés. Selon deux outils bioinformatiques­PolyPhen-2 (de l'anglais, polymorphism phenotyping v2) et SIFT (de l'anglais, sorting intolerant from tolerant), les quatre mutations faux-sens devaient être pathogènes. De plus, les quatre modélisations de ß-MYH7 par homologie­p.Leu358, p.Tyr384, p.Leu510 et p.His723­affichaient de façon respective des écarts quadratiques moyens de ∼2,55 Å, ∼1,24 Å, ∼3,36 Å et ∼3,86 Å. CONCLUSIONS: Dans la présente étude, nous avons détecté de nombreuses nouvelles mutations, uniques et rares, dans le gène ß-MYH7, exclusivement chez les patients indiens atteints de CMD (8,0 %). Ici, nous avons démontré comment chaque mutant (faux-sens) perturbe de manière unique un réseau essentiel d'interactions non liantes au site de mutation (moléculaire) et peut contribuer à la survenue de la CMD. Par conséquent, les conclusions de notre étude peuvent donner un aperçu des bases moléculaires de la maladie et du diagnostic tout en favorisant la promotion de nouvelles stratégies thérapeutiques (par la médecine personnalisée).

Ribosomal protein S6 kinase beta-1 gene variants cause hypertrophic cardiomyopathy.

BACKGROUND: Hypertrophic cardiomyopathy (HCM) is a genetic heart muscle disease with preserved or increased ejection fraction in the absence of secondary causes. Mutations in the sarcomeric protein-encoding genes predominantly cause HCM. However, relatively little is known about the genetic impact of signalling proteins on HCM. METHODS AND RESULTS: Here, using exome and targeted sequencing methods, we analysed two independent cohorts comprising 401 Indian patients with HCM and 3521 Indian controls. We identified novel variants in ribosomal protein S6 kinase beta-1 (RPS6KB1 or S6K1) gene in two unrelated Indian families as a potential candidate gene for HCM. The two unrelated HCM families had the same heterozygous missense S6K1 variant (p.G47W). In a replication association study, we identified two S6K1 heterozygotes variants (p.Q49K and p.Y62H) in the UK Biobank cardiomyopathy cohort (n=190) compared with matched controls (n=16 479). These variants are neither detected in region-specific controls nor in the human population genome data. Additionally, we observed an S6K1 variant (p.P445S) in an Arab patient with HCM. Functional consequences were evaluated using representative S6K1 mutated proteins compared with wild type in cellular models. The mutated proteins activated the S6K1 and hyperphosphorylated the rpS6 and ERK1/2 signalling cascades, suggesting a gain-of-function effect. CONCLUSIONS: Our study demonstrates for the first time that the variants in the S6K1 gene are associated with HCM, and early detection of the S6K1 variant carriers can help to identify family members at risk and subsequent preventive measures. Further screening in patients with HCM with different ethnic populations will establish the specificity and frequency of S6K1 gene variants.

Intramuscular Immunization of Streptococcus pyogenes SF370 protein extract and identification of multiple virulence factors through proteomic profiling in RHD induced Balb/c mice.

Group A streptococcus (GAS) and autoimmunity are associated with heart related mitral valve damage, in adults. In this study Balb/c mice were intramuscularly immunized with S. pyogenes SF370 for 4 weeks. Prior to euthanization, physiological parameters like body weight and electrical signalling of the heart were recorded. After euthanization, the heart tissue homogenate was prepared and proteomic alterations were studied using SDS-PAGE and 2D electrophoresis. The expression levels of inflammatory genes like TNFα, IFNγ and TGF-ß were quantified using real time PCR. Insilico analysis was performed to identify the functions of hypothetical proteins and virulence factors involved in the induction of rheumatic carditis. The results showed a reduction in body weight, ulceration, inflammation, cardiac lesions and prolonged PR interval in mice immunized with S. pyogenes SF370, as a result of RHD. The heart related proteins like α-actinin, fatty acid binding protein-heart, myosin light chain 3, hemoglobin subunit alpha, myoglobin regulatory light chain 2, (ventricular/cardiac muscle isoform), myosin-6, troponin-1 were found to be up-regulated when compared with the control. The functional annotation of S. pyogenes (SF370) was carried out by retrieving 1696 identified proteins and 653 hypothetical protein sequences in NCBI genome database. The conserved domain was identified for 505 proteins. The pfam database documented that the super families of 279 sequences and 40 signal peptides enabled the classification of proteins in different categories like biological (20%), cellular (22%) and molecular functions (36%). Putative transcription repair coupling factor and putative lysine aminopeptidase N terminal are the two virulence factors identified by VICMPRED in S. pyogenes SF370. The two identified virulence factors are involved in altering the mice heart proteome and thereby controlling the streptococcus pyogenes infection. Thus, the results of the present study reveals the role of immunogenic proteins in induction of rheumatic carditis and to elucidate the molecular mechanisms leading to autoimmune reactions in Balb/c mice.

Mitochondrial genome variations in idiopathic dilated cardiomyopathy.

Idiopathic dilated cardiomyopathy (DCM) is a structural heart disease with strong genetic background. The aim of this study was to assess the role of mitochondrial DNA (mtDNA) variations and haplogroups in Indian DCM patients. Whole mtDNA analysis of 221 DCM patients revealed 48 novel, 42 disease-associated and 97 private variations. The frequency of reported variations associated with hearing impairment, DEAF, SNHL and LHON are significantly high in DCM patients than controls. Haplogroups H and HV were over represented in DCM than controls. Functional analysis of two private variations (m.8812A>G & m.10320G>A) showed decrease in mitochondrial functions, suggesting the role of mtDNA variations in DCM.

Novel nonsense mutation (p.Ile411Metfs*12) in the SLC19A2 gene causing Thiamine Responsive Megaloblastic Anemia in an Indian patient.

Thiamine-responsive megaloblastic anemia (TRMA), an autosomal recessive disorder, is caused by mutations in SLC19A2 gene encodes a high affinity thiamine transporter (THTR-1). The occurrence of TRMA is diagnosed by megaloblastic anemia, diabetes mellitus, and sensorineural deafness. Here, we report a female TRMA patient of Indian descent born to 4th degree consanguineous parents presented with retinitis pigmentosa and vision impairment, who had a novel homozygous mutation (c.1232delT/ter422; p.Ile411Metfs*12) in 5th exon of SLC19A2 gene that causes premature termination of hTHTR-1. PROSITE analysis predicted to abrogate GPCRs family-1 signature motif in the variant by this mutation c.1232delT/ter422, suggesting uncharacteristic rhodopsin function leading to cause RP clinically. Thiamine transport activity by the clinical variant was severely inhibited than wild-type THTR-1. Confocal imaging had shown that the variant p.I411Mfs*12 is targeted to the cell membrane and showed no discrepancy in membrane expression than wild-type. Our findings are the first report, to the best of our knowledge, on this novel nonsense mutation of hTHTR-1 causing TRMA in an Indian patient through functionally impaired thiamine transporter activity.

Elevated levels of circulating DNA in cardiovascular disease patients: metagenomic profiling of microbiome in the circulation.

Cardiovascular diseases (CVDs) are the leading cause of death worldwide. An expanding body of evidence supports the role of human microbiome in the establishment of CVDs and, this has gained much attention recently. This work was aimed to study the circulating human microbiome in CVD patients and healthy subjects. The levels of circulating cell free DNA (circDNA) was higher in CVD patients (n = 80) than in healthy controls (n = 40). More specifically, the relative levels of circulating bacterial DNA and the ratio of 16S rRNA/ß-globin gene copy numbers were higher in the circulation of CVD patients than healthy individuals. In addition, we found a higher circulating microbial diversity in CVD patients (n = 3) in comparison to healthy individuals (n = 3) by deep shotgun sequencing. At the phylum level, we observed a dominance of Actinobacteria in CVD patients, followed by Proteobacteria, in contrast to that in healthy controls, where Proteobacteria was predominantly enriched, followed by Actinobacteria. The circulating virome in CVD patients was enriched with bacteriophages with a preponderance of Propionibacterium phages, followed by Pseudomonas phages and Rhizobium phages in contrast to that in healthy individuals, where a relatively greater abundance of eukaryotic viruses dominated by Lymphocystis virus (LCV) and Torque Teno viruses (TTV) was observed. Thus, the release of bacterial and viral DNA elements in the circulation could play a major role leading to elevated circDNA levels in CVD patients. The increased circDNA levels could be either the cause or consequence of CVD incidence, which needs to be explored further.

RAF1 mutations in childhood-onset dilated cardiomyopathy.

Dilated cardiomyopathy (DCM) is a highly heterogeneous trait with sarcomeric gene mutations predominating. The cause of a substantial percentage of DCMs remains unknown, and no gene-specific therapy is available. On the basis of resequencing of 513 DCM cases and 1,150 matched controls from various cohorts of distinct ancestry, we discovered rare, functional RAF1 mutations in 3 of the cohorts (South Indian, North Indian and Japanese). The prevalence of RAF1 mutations was ~9% in childhood-onset DCM cases in these three cohorts. Biochemical studies showed that DCM-associated RAF1 mutants had altered kinase activity, resulting in largely unaltered ERK activation but in AKT that was hyperactivated in a BRAF-dependent manner. Constitutive expression of these mutants in zebrafish embryos resulted in a heart failure phenotype with AKT hyperactivation that was rescued by treatment with rapamycin. These findings provide new mechanistic insights and potential therapeutic targets for RAF1-associated DCM and further expand the clinical spectrum of RAF1-related human disorders.

Genome sequence of Staphylococcus arlettae strain CVD059, isolated from the blood of a cardiovascular disease patient.

We have isolated a Staphylococcus arlettae strain, strain CVD059, from the blood of a rheumatic mitral stenosis patient. Here, we report the genome sequence and potential virulence factors of this clinical isolate. The draft genome of S. arlettae CVD059 is 2,565,675 bp long with a G+C content of 33.5%.