Human Genetics And Molecular Medicine - Research Publications

Permanent URI for this collectionhttps://kr.cup.edu.in/handle/32116/107

Browse

Has files: NoSubject: search.filters.subject.Human

Search Results

Now showing 1 - 5 of 5
  • No Thumbnail Available
    Item
    The mitochondrial unfolded protein response: Role in cellular homeostasis and disease
    (Bentham Science Publishers B.V., 2017) De, I.; Dogra, N.; Singh, S.
    Mitochondria are the sole semiautonomous organelles of the human cell and play a very important role in not only energy production but also in apoptosis, metabolism and cell signaling. They are also known to be major producers of ROS and RNS free radicals during ATP production. These free radicals in excessive amount may damage the mitochondrial DNA as well as proteome resulting in accumulation of misfolded proteins which may prove deleterious to their functioning and are known to be involved in disease pathology. To maintain healthy proteome, mitochondria have developed as quality control machinery in semiautonomous manner, where cellular proteins such as proteases and heat shock proteins are used for quality control. The present review discusses various aspects of mitochondrial protein quality control operating at outer or inner membrane as well as intermembranal space. The various pathways involved in mitochondrial unfolded protein response have been discussed along with their implications in cancer and various neurodegenerative diseases. ? 2017 Bentham Science Publishers.
  • No Thumbnail Available
    Item
    PPARG and ADIPOQ gene polymorphisms increase type 2 diabetes mellitus risk in Asian Indian Sikhs: Pro12Ala still remains as the strongest predictor
    (2010) Sanghera, D.K.; Demirci, F.Y.; Been, L.; Ortega, L.; Ralhan, S.; Wander, G.S.; Mehra, N.K.; Singh, J.; Aston, C.E.; Mulvihill, J.J.; Kamboh, I.M.
    We have examined the association of 14 tagging single nucleotide polymorphisms (tagSNPs) in peroxisome proliferator activated receptor-? transcripts 1 and 2 (PPARG1 and 2) and 5 tagSNPs in adiponectin (ADIPOQ) genes for their effect on type 2 diabetes mellitus (T2D) risk in Asian Indian Sikhs. A total of 554 T2D cases and 527 normoglycemic controls were examined for association with T2D and other subphenotypes of T2D. With the exception of a strong association of PPARG2/Pro12Ala with T2D (odds ratio, 0.13; 95% confidence interval, 0.03-0.56; P = .0007), no other tagSNP in the PPARG locus revealed any significant association with T2D in this population. Similarly, none of the tagSNPs in the ADIPOQ gene was associated with T2D susceptibility in single-site analysis. However, haplotype analysis provided strong evidence of association of these loci with T2D. Three-site haplotype analysis in the PPARG locus using the 2 marginally associated SNPs (P/rs11715073 and P/rs3892175) in combination with Pro12 Ala (P/rs1801282) revealed a strong association of 1 "risk" (CGC) (P = .003, permutation P = .015) and 1 "protective" (CAC) (P = .001, permutation P = .005) haplotype associated with T2D. However, the major effect still appears to be driven by Pro12Ala, as the association of these haplotypes did not remain significant when analyzed conditional upon Pro12Ala (P = .262). In addition, 2-site haplotype analysis in the ADIPOQ locus using only 2 marginally associated SNPs (AD/rs182052 and AD/rs7649121) revealed a significant protective association of the GA haplotype with T2D (P = .009, permutation P = .026). Multiple linear regression analysis also revealed significant association of an ADIPOQ variant (AD/rs12495941) with total body weight (P = .010), waist (P = .024), and hip (P = .021), although these associations were not significant after adjusting for multiple testing. Our new findings strongly suggest that the genetic variation in PPARG and ADIPOQ loci could contribute to the risk for the development of T2D in Indian Sikhs. Identification of causal SNPs in these important biological and positional candidate genes would help determine the true physiologic significance of these loci in T2D and obesity. ? 2010 Elsevier Inc. All rights reserved.
  • No Thumbnail Available
    Item
    Genetic signatures in ischemic stroke: Focus on aspirin resistance
    (Bentham Science Publishers B.V., 2017) Vasudeva, Kanika; Chaurasia, Pratibha; Singh, Sulena; Munshi, Anjana
    Background and Objective: Stroke is one of the leading causes of death. There has been compelling evidence that stroke has a genetic component. Genetic variants not only influence susceptibility to stroke but have also been found to alter the response to pharmacological agents and influence the clinical outcome of the disease. Stroke patients are treated with antiplatelet drugs like aspirin and clopidogrel to prevent a secondary stroke. In spite of the fact that many new antiplatelet drugs have been developed, aspirin is still considered as a golden standard for the antiplatelet therapy. Aspirin achieves its action by inhibiting platelet cyclooxygenase (COX) system involved in the formation of thromboxane A2 (TXA2). TXA2 triggers reactions leading to platelet activation and aggregation. This Non-steroidal anti-inflammatory drug (NSAID) acts by inhibiting this mediator. Despite the demonstrated benefits of aspirin, many patients develop secondary stroke or other vascular events, an observation that has led to the concept of aspirin resistance. Studies have demonstrated that adequate antiplatelet effects are not achieved in 5-45% patients suggesting that many individuals are aspirin resistant. Aspirin resistance is multifactorial in origin. A genetic component has also been suggested, and variants in more than a dozen genes involved in absorption, distribution, metabolism, excretion (ADME) and pharmacodynamics of aspirin have been shown to be responsible for aspirin resistance. In addition, the patients on aspirin treatment also face adverse drug reactions on account of genetic variation. Conclusion: The present review has been compiled with an aim to revisit all the studies related to genetic variation contributing to aspirin resistance as well as adverse drug reactions. The output of high throughput genomic technology like genome wide association studies and others has also been discussed. ? 2017 Bentham Science Publishers.
  • No Thumbnail Available
    Item
    Association of GABRA6 1519 T>C (rs3219151) and Synapsin II (rs37733634) gene polymorphisms with the development of idiopathic generalized epilepsy
    (Elsevier, 2014) Prasad, D.K.V.; Shaheen, U.; Satyanarayana, U.; Prabha, T.S.; Jyothy, A.; Munshi, A.
    The idiopathic generalized epilepsy (IGE) is a neurological disorder which accounts for approximately 30% of all epilepsy cases. Patients identified with IGE syndromes have pharmacoresponsive epilepsies without abnormal neurological symptoms, structural brain lesions and are of unknown origin. A genetic etiology to IGEs has been proposed. Gamma amino butyric acid (GABA), a major inhibitory neurotransmitter acts by binding to transmembrane GABAA and GABAB receptors of both pre- and postsynaptic neurons. Synapsin II (SynII), a neuron specific phosphoprotein plays a major role in synaptogenesis and neurotransmitter release. The present study was carried out with an aim to evaluate the association of GABRA6 (rs3219151) T>C and Syn II (rs37733634) A>G gene polymorphisms with IGE. Molecular analysis revealed that the frequency of 'CC' genotype and 'C'allele of GABRA6 (rs3219151) T>C gene polymorphism was significantly higher in IGE patients compared to healthy controls [CC vs. TT, ?2=26; p<0.001; Odds ratio=3.6 (95% CI; 2.1-5.9); C vs T, ?2=24.7; p<0.001; Odds ratio=1.78 (95% CI; 1.4-2.2)]. The frequency of 'GG' genotype and 'G' allele of the intronic polymorphism A>G in Syn II gene was also found to be significantly associated with the disease when compared to controls [GG vs AA, ?2=64.52; p<0.001; Odds ratio=7.37 (95% CI; 4.4-12.3); G vs. A, ?2=65.78; p<0.001; Odds ratio=2.57 (95% CI; 2.0-3.2)]. The generalized multifactor dimensionality reduction method was employed to detect gene-gene interactions. The gene-gene interaction at two loci involving GABRA6 and Syn II revealed a significant association [?2=36.6, p<0.001, Odds ratio=3.17 (95% CI; 2.2-4.6)] with IGE. Therefore, the present study clearly indicates that both GABRA6 (rs3219151) T>C and Syn II (rs37733634) A>G polymorphisms are important risk factors for the development of IGE in the South Indian population from Andhra Pradesh. The gene-gene interaction studies demonstrated significant interactive effects of these two loci in the development of the disease. ? 2014 Elsevier B.V.
  • No Thumbnail Available
    Item
    A novel 7 bp deletion in PRPF31 associated with autosomal dominant retinitis pigmentosa with incomplete penetrance in an Indian family
    (2012) Saini, S.; Robinson, P.N.; Singh, J.R.; Vanita, V.
    To localize and identify the gene linked with non-syndromic autosomal dominant retinitis pigmentosa (adRP) with high but not complete penetrance in an Indian family. A detailed family history and clinical data were recorded. A genome-wide scan by 2-point linkage analysis using nearly 400 fluorescently labeled microsatellite markers in combination with multipoint lod score and haplotype analysis was carried out. Mutation screening was performed in the candidate gene by bidirectional sequence analysis of the amplified products. A maximum 2-point lod score of 3.553 at theta = 0.0 was obtained with marker D19S572. Haplotype analysis placed the RP locus distal to marker D19S572, in close proximity to the gene for pre-mRNA processing factor 31 (PRPF31) at 19q13.42. Mutation screening in all 14 exonic regions and adjacent flanking intronic sequences of PRPF31 revealed a novel 7 bp deletion, c.59_65del7 (p.Gly20AlafsX43), in the first coding exon of PRPF31. This leads to a premature termination codon (PTC) in the next exon, 43 amino acids downstream. The observed 7 bp deletion in PRPF31 was identified in all the tested 10 affected members and in an unaffected individual, consistent with a high, but not the complete penetrance of c.59_65del7 (p.Gly20AlafsX43). This deletion was not observed in other tested six unaffected family members or in 100 ethnically matched control subjects. The present study describes mapping of a locus for non-syndromic adRP at 19q13.42 (RP11 locus) in a family of Indian origin and identifies a novel deletion, c.59_65del7, in PRPF31 within the mapped interval. Since the mutant PRPF31 is truncated relatively close to the N-terminus of the protein, haploinsufficiency rather than aberrant protein formation is likely to be the underlying mechanism of the disease. The present findings further substantiate the role of PRPF31 that encodes a component of the spliceosome complex in relation to ADRP. ? 2012 Elsevier Ltd.