Browsing by Author "Gopal Gupta"

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Array-based DNA methylation profiling reveals peripheral blood differential methylation in male infertility
(Elsevier Inc., 2019) Saumya Sarkar; Kumar Mohanty Sujit; Vertika Singh; Rajesh Pandey; Sameer Trivedi; Kiran Singh; Gopal Gupta; Singh Rajender
Objective: To study peripheral blood DNA differential methylation in oligozoospermic infertile men in comparison with normozoospermic fertile controls. Design: Case-control study. Setting: Reproductive biology laboratory. Patients(s): Azoospermic and oligozoospermic infertile patients (n = 6) and normozoospermic fertile controls (n = 6) in the discovery phase, and oligo/asthenozoospermic infertile men (n = 11) and normozoospermic fertile controls (n = 10) in the validation phase. Intervention(s): Blood samples drawn from all participants, DNA isolation and methylation analysis. Main Outcome Measure(s): DNA methylation values analyzed using genomewide methylation 450K BeadChip array, followed by deep sequencing of selected regions for methylation analysis in the neighborhood regions of differentially methylated CpGs. Result(s): We found 329 differentially methylated CpG spots, out of which 245 referred to the genes, representing 170 genes. Deep-sequencing analysis confirmed the methylation pattern suggested by 450K array. A thorough literature search suggested that 38 genes play roles in spermatogenesis (PDHA2, PARP12, FHIT, RPTOR, GSTM1, GSTM5, MAGI2, BCAN, DDB2, KDM4C, AGPAT3, CAMTA1, CCR6, CUX1, DNAH17, ELMO1, FNDC3B, GNRHR, HDAC4, IRS2, LIF, SMAD3, SOD3, TALDO1, TRIM27, GAA, PAX8, RNF39, HLA-C, HLA-DRB6), are testis enriched (NFATC1, NMNAT3, PIAS2, SRPK2, WDR36, WWP2), or show methylation differences between infertile cases and controls (PTPRN2, RPH3AL). Conclusion(s): We found a statistically significant correlation between peripheral blood DNA methylation and male infertility, raising the hope that epigenome-based blood markers can be used for screening male infertility risk. The study also identified new candidates for spermatogenesis and fertility. © 2019 American Society for Reproductive Medicine
Azoospermic infertility is associated with altered expression of DNA repair genes
(Elsevier B.V., 2019) Vertika Singh; Deepika Jaiswal; Kanhaiya Singh; Sameer Trivedi; Neeraj K Agrawal; Gopal Gupta; Singh Rajender; Kiran Singh
Compelling evidence suggest that germs cells are predominantly sensitive to DNA damaging agents in comparison to other cells. High fidelity DNA repair in testicular cells thus becomes indispensable to preserve the genomic integrity for passing on to the progeny. Compromised DNA repair machinery in the testicular cells may result in impaired spermatogenesis and infertility. It remains unclear if the alterations in the expression of DNA repair genes correlate with azoospermia and male infertility. In the present study, 54 non-obstructive azoospermic infertile patients with hypospermatogenesis (HS, n = 26), maturation arrest (MA, n = 15), Sertoli cell only syndrome (SCOS, n = 13) and 14 controls with obstructive azoospermia, but normal spermatogenesis were recruited. Expression profiling of 84 DNA repair genes in testicular biopsy samples was performed using PCR array. Out of 84 genes, 27, 64 and 28 genes showed >5 fold down-regulation in the HS, MA and SCOS groups, respectively. On the basis of differential expression and their functional significance in spermatogenesis, ten genes (MSH2, BRIP1, CCNH, LIG4, MGMT, NTHL1, PMS1, DMC1, POLB and XPA) were selected for validation of transcript levels in a higher number of cases using RT-PCR, which corroborated the findings of array. Four genes (MSH2, LIG4, PMS1 and DMC1) were analyzed for protein levels using immunohistochemistry, which further validated the loss of DNA repair gene expression. Caspase-3 immunostaining showed that the loss of DNA repair correlated with increased testicular apoptosis in patients. Maturation arrest showed the highest apoptotic index with maximum number of downregulated genes. We conclude that the loss of DNA repair genes expression in testis correlates with increased apoptosis, azoospermia and infertility. © 2019 Elsevier B.V.
Genome-wide differential methylation analyses identifies methylation signatures of male infertility
(Oxford University Press, 2018) Kumar Mohanty Sujit; Saumya Sarkar; Vertika Singh; Rajesh Pandey; Neeraj Kumar Agrawal; Sameer Trivedi; Kiran Singh; Gopal Gupta; Singh Rajender
STUDY QUESTION: Do methylation changes in sperm DNA correlate with infertility? STUDY ANSWER: Loss of spermatogenesis and fertility was correlated with 1680 differentially-methylated CpGs (DMCs) across 1052 genes. WHAT IS KNOWN ALREADY: Methylation changes in a number of genes have been correlated with reduced sperm count and motility. STUDY DESIGN, SIZE, DURATION: This case-control study used spermatozoal DNA from 38 oligo-/oligoastheno-zoospermic infertile patients and 26 normozoospermic fertile men. PARTICIPANTS/MATERIALS, SETTINGS, METHODS: Genome-wide methylation analysis was undertaken using 450 K BeadChip on spermatozoal DNA from six infertile and six fertile men to identify DMCs. This was followed by deep sequencing of spermatozoal DNA from 32 infertile patients and 20 fertile controls. MAIN RESULTS AND THE ROLE OF CHANCE: A total of 1680 DMCs were identified, out of which 1436 were hypermethylated and 244 were hypomethylated. Classification of DMCs according to the genes identified BCAN, CTNNA3, DLGAP2, GATA3, MAGI2 and TP73 among imprinted genes, SPATA5, SPATA7, SPATA16 and SPATA22 among spermatogenesis-associated genes, KDM4C and JMJD1C, EZH2 and HDAC4 among genes which regulate methylation and gene expression, HLA-C, HLA-DRB6 and HLA-DQA1 among complementation and immune response genes, and CRISPLD1, LPHN3 and CPEB2 among other genes. Genes showing significant differential methylation in deep sequencing, i.e. HOXB1, GATA3, EBF3, BCAN and TCERG1L, are strong candidates for further investigations. The role of chance was ruled out by deep sequencing of select genes. LARGE-SCALE DATA: N/A. LIMITATIONS, REASON FOR CAUTION: Genome-wide analyses are fairly accurate, but may not be exactly validated in replication studies across all DMCs. We used the 't' test in the genome-wide methylation analysis, whereas other tests could provide a more robust and powerful analysis. WIDER IMPLICATIONS OF THE FINDINGS: DMCs can serve as markers for inclusion in infertility screening panels, particularly those in the genes showing differential methylation consistent with previous studies. The genes validated by deep sequencing are strong candidates for investigations of their roles in spermatogenesis.STUDY FUNDING/COMPETING INTEREST(S): The study was funded by the Council of Scientific and Industrial Research (CSIR), Govt. of India with grant number BSC0101 awarded to Rajender Singh. None of the authors has any competing interest to declare. © The Author(s) 2018. Published by Oxford University Press on behalf of the European Society of Human Reproduction and Embryology. All rights reserved.
Gr/gr deletions on Y-chromosome correlate with male infertility: An original study, meta-analyses, and trial sequential analyses
(Nature Publishing Group, 2016) Sandeep Kumar Bansal; Deepika Jaiswal; Nishi Gupta; Kiran Singh; Rima Dada; Satya Narayan Sankhwar; Gopal Gupta; Singh Rajender
We analyzed the AZFc region of the Y-chromosome for complete (b2/b4) and distinct partial deletions (gr/gr, b1/b3, b2/b3) in 822 infertile and 225 proven fertile men. We observed complete AZFc deletions in 0.97% and partial deletions in 6.20% of the cases. Among partial deletions, the frequency of gr/gr deletions was the highest (5.84%). The comparison of partial deletion data between cases and controls suggested a significant association of the gr/gr deletions with infertility (P = 0.0004); however, the other partial deletions did not correlate with infertility. In cohort analysis, men with gr/gr deletions had a relatively poor sperm count (54.20 ± 57.45 million/ml) in comparison to those without deletions (72.49 ± 60.06), though the difference was not statistically significant (p = 0.071). Meta-analysis also suggested that gr/gr deletions are significantly associated with male infertility risk (OR = 1.821, 95% CI = 1.39-2.37, p = 0.000). We also performed trial sequential analyses that strengthened the evidence for an overall significant association of gr/gr deletions with the risk of male infertility. Another meta-analysis suggested a significant association of the gr/gr deletions with low sperm count. In conclusion, the gr/gr deletions show a strong correlation with male infertility risk and low sperm count, particularly in the Caucasian populations.
Increased DNA methylation in the spermatogenesis-associated (SPATA) genes correlates with infertility
(Blackwell Publishing Ltd, 2020) Kumar Mohanty Sujit; Vertika Singh; Sameer Trivedi; Kiran Singh; Gopal Gupta; Singh Rajender
Background: Spermatogenesis-associated (SPATA) family of genes plays important roles in spermatogenesis, sperm maturation or fertilization. The knockout studies in mice have demonstrated that SPATA genes are crucial for fertility. Gene expression and genetic polymorphism studies have further suggested their correlation with infertility; however, methylation analysis of SPATA genes in human male infertility has not yet been undertaken. Objectives: To analyze the methylation status of SPATA4, SPATA5 and SPATA6 genes in oligozoospermic male infertility. Materials and methods: In the present study, we have analyzed DNA methylation pattern in the promoter regions of SPATA4, SPATA5 and SPATA6 genes in oligozoospermic patients and compared it with normozoospermic fertile controls. Semen samples were obtained from 30 oligozoospermic infertile and 19 normozoospermic fertile controls, and DNA methylation levels of the target gene promoters were analyzed by amplicon based deep sequencing methylation analysis using MiSeq. Results: SPATA4 (P < 0.0008), SPATA5 (P = 0.009) and SPATA6 (Promoter, P < 0.0005; Exon 1, P = 0.0128) genes were significantly hypermethylated in oligozoospermic patients in comparison to controls. This is the first study reporting a higher methylation in the promoters of SPATA4, SPATA5 and SPATA6 in oligozoospermic infertile individuals in comparison to the normozoospermic fertile controls. Discussion: Altered methylation of SPATA genes would affect pathways involved in sperm production or affect various processes linked to sperm fertility. Conclusion: In conclusion, hypermethylation in the SPATA4, SPATA5 and SPATA6 genes correlates with oligozoospermic infertility. © 2019 American Society of Andrology and European Academy of Andrology
SNPs in ERCC1, ERCC2, and XRCC1 genes of the DNA repair pathway and risk of male infertility in the Asian populations: association study, meta-analysis, and trial sequential analysis
(Springer New York LLC, 2019) Vertika Singh; Sandeep Kumar Bansal; D.V.S. Sudhakar; Neelabh; Arijit Chakraborty; Sameer Trivedi; Gopal Gupta; Kumarasamy Thangaraj; Singh Rajender; Kiran Singh
Purpose: We investigated if substitutions in the ERCC1, ERCC2, and XRCC1 genes of the DNA repair pathway correlate with non-obstructive azoospermia and male infertility. Methods: A total of 548 azoospermic infertile males and 410 fertile controls were genotyped for XRCC1 399A > G, 280G > A, and ERCC1 C > A 3′ UTR and 541 azoospermic infertile males and 416 fertile controls were genotyped for ERCC2 751A > C using iPLEX Gold Assay. Meta-analyses were performed on XRCC1 399A > G (1022 cases and 1004 controls), ERCC1 C > A 3′ UTR (879 cases and 1059 controls), and ERCC2 751A > C (914 cases and 850 controls) polymorphisms to quantitatively estimate the significance of the association between these polymorphisms and the risk of infertility. Results: Statistically significant association between ERCC2 751A > C SNP and male infertility was found using the codominant model (p = 0.03). Results of meta-analysis suggested a lack of correlation with male infertility risk, which could be due to pooling of studies from different ethnic populations. Due to limited the number of studies, a stratified analysis for different ethnic groups could not be performed. Conclusion (s): In conclusion, AA genotype of 751A > C SNP in ERCC2 correlated with a higher risk of male infertility and may contribute to an increased risk of azoospermia and male infertility in Indian men. © 2018, Springer Science+Business Media, LLC, part of Springer Nature.
SPATA16 promoter hypermethylation and downregulation in male infertility
(John Wiley and Sons Inc, 2022) Kumar Mohanty Sujit; Saini Pallavi; Vertika Singh; Syed Waseem Andrabi; Sameer Trivedi; Satya Narayan Sankhwar; Gopal Gupta; Singh Rajender
Spermatogenesis associated 16 (SPATA16) gene plays an important role in acrosome formation. In this study, we analysed SPATA16 promoter methylation in 29 oligozoospermic infertile and 16 normozoospermic fertile sperm samples and in testicular biopsy from 16 non-obstructive azoospermic and 2 obstructive azoospermic individuals. Next, we analysed SPATA16 level in sperm from 8 oligozoospermic infertile, 6 normozoospermic fertile, 9 IVF failed normozoospermic and 10 IVF successful normozoospermic samples by immunoblotting. This was followed by the analysis of SPATA16 expression in testicular biopsy from azoospermic individuals (n = 8) in comparison to normozoospermic individuals (n = 2). Oligozoospermic infertile sperm samples showed significantly higher methylation in the SPATA16 promoter region. Similarly, testicular biopsy from azoospermic men also showed significantly higher level of DNA methylation. Sub-group analysis of infertile sperm and testicular biopsy samples showed a direct correlation between DNA methylation and the degree of spermatogenic impairment. Oligozoospermic infertile samples and IVF failed samples showed reduced SPATA16 expression in comparison to normozoospermic fertile and IVF successful samples, respectively. Human biopsy analysis showed a significant decrease in SPATA16 expression in hypospermatogenesis, maturation arrest and Sertoli cell only syndrome. In conclusion, hypermethylation in SPATA16 promoter shows a highly significant correlation with infertility, which is consistent with its down-regulation in infertility. © 2022 Wiley-VCH GmbH.