Project description:We developed a cellular model to study sex differences in humans. Using somatic cells from a mosaic Kleinefelter patient, we generated isogenic human induced pluripotent stem cell lines with different sex chromosome complements – 47,XXY / 46,XX / 46,XY and 45,X0. 46, XX and 46, XY hiPSCs were differentiated to neural progenitor cells and compared.

Project description:We developed a cellular model to study sex differences in humans. Using somatic cells from a mosaic Kleinefelter patient, we generated isogenic human induced pluripotent stem cell lines with different sex chromosome complements – 47,XXY / 46,XX / 46,XY and 45,X0.

Project description:Objective: Klinefelter Syndrome (KS) is the most common sexual chromosome abnormality (47,XXY; 46,XY/47XXY) and represents the first genetic cause of male infertility. The mechanisms leading to KS testis degeneration are still unclear and no therapy is so far available for affected patients. The present study is aimed to unravel information about molecules playing a key role in the disruption of the spermatogenesis in mosaic oligospermic KS patients. Design: Gene expression profiles analysis of KS mosaic oligospermic testis versus normal testis, could provide useful information about the molecular basis of the alteration of the spermatogenesis. Materials and Methods: Transcriptome analysis was performed carrying out gene expression profile by a whole genome microarray approach on testis biopsies obtained from 3 oligopermic mosaic KS men and from 3 controls, for a total of 6 experiments. T-test and False Discovery Rate were used to evaluate differentially expressed genes. Identified transcripts were analysed by Ingenuity Pathways Analysis software to disclose genes biological functions. Results: Data analysis revealed the differentially up- and down-expression, in mosaic KS testis versus the control ones, of respectively 303 and 747 genes related to Endocrine system disorders, Lipid metabolism, Reproductive disease, cell and organ morphology, and cell death. Conclusions: Taken together these data show the presence of several de-regulated genes involved in mosaic KS testis failure. Data show the defects in sperm production and development and defects within the somatic component of the testis. This information, associated with an early diagnosis could help to unravel possible therapeutic targets for testis failure prevention and limitation.

Project description:Klinefelter syndrome (KS) is the most common male chromosomal abnormality (47,XXY). Males with KS suffers from numerous comorbidities. Gene expression data integrated with other data types can increase the knowledge and clinically handling of KS males. Gene expression microarray from eight human Klinefelter syndrome patients (47,XXY) and eight human controls. The age of the Klinefelter syndrome patients varied, which was corrected for in the pre-processing as described in the paper and also in the 'normalization data transformation protocol' of this submission.

Project description:Detection of genomic rearrangements from a single cell instead of a population of cells is an emerging research technique with important applications in the study of human fertility, constitutional chromosomal disorders, and tumor progression. Here, we develop a method to improve the detection of single-cell genome-wide copy number variation. At this study, 7 amplified single cell DNA samples derived from EBV-line [47,XY,+21], [46,XY,der(20),t(18;20)(p11.21;p13)], [46,XX,del(18)(p11.21->pter)], [46,X,der(X),t(X;14)(q21.1;q12.2)] were analyzed by Agilent 244K array CGH. For these single cell Agilent 244K array CGH analyses: non-amplified genomic DNA extracted from the blood of a Klinefelter patient (XXY) was used as a reference sample. As a validation, the corresponding non-amplified genomic DNA samples were analyzed by 250K Nsp I SNP arrays (platform GPL3718). Non-amplified genomic DNA extracted from the blood of a Klinefelter patient (XXY) was used as a reference sample for BAC array CGH

Project description:Klinefelter syndrome (KS) is the most prevalent aneuploidy in males and is characterized by one or more supernumerary X chromosomes. Here, using a paradigmatic cohort of KS-inducible pluripotent stem cells (iPSCs) carrying 49-XXXXY, 48-XXXY, and 47-XXY karyotypes, we identified genes within the pseudoautosomal region 1 (PAR1) region as the most susceptible to dosage-dependent transcriptional dysregulation and therefore potentially responsible for the progressively worsening phenotype in higher grade X aneuploidies. By contrast, biallelically expressed non-PAR escape genes displayed high interclonal and interpatient variability in iPSCs and differentiated derivatives, suggesting that these genes could be associated with variable KS traits. By interrogating KS-iPSCs at single-cell resolution, we showed that PAR1 and non-PAR escape genes were not only resilient to X-inactive specific transcript (XIST)-mediated inactivation but also that their transcriptional regulation was disjointed from the absolute XIST expression level. Finally, we explored the transcriptional effects of X chromosome overdosage on autosomes and identified the transcription factor nuclear respiratory factor 1 as the master regulator of zinc finger protein X-linked. Our findings provided the first evidence of an X-dosage-sensitive autosomal transcription factor regulating an X-linked gene in low- and high-grade X aneuploidies.

Project description:Objective: Klinefelter Syndrome (KS) is the most common sexual chromosome abnormality (47,XXY) and represents the first genetic cause of male infertility. The mechanisms leading to KS testis degeneration are still unclear and no therapy is so far available for affected patients. The present study is aimed to unravel information about molecules playing a key role in the disruption of the spermatogenesis. Design: Gene expression profiles analysis of KS azoospermic testis versus normal testis, could provide useful information about the molecular basis of the alteration of the spermatogenesis. Materials and Methods: Transcriptome analysis was performed carrying out gene expression profile by a whole genome microarray approach on testis biopsies obtained from 6 azoospermic non-mosaic KS men and from 3 controls, for a total of 12 experiments. T-test and False Discovery Rate were used to evaluate differentially expressed genes. Identified transcripts were analysed by Ingenuity Pathways Analysis software to disclose genes biological functions. Results: Data analysis revealed the differentially up- and down-expression, in KS testis versus the control ones, of 656 and 247 genes related to Endocrine system development and function, Lipid metabolism, Reproductive disease, Free radical scavenging, and Cell death. Conclusions: Take together these data show the presence of several genes involved in testis microenvironment deregulation leading to the spermatogenesis failure. This information, associated with an early diagnosis could help to unravel possible therapeutic targets for testis failure prevention and limitation. Gene expression profile of 6 azoospermic KS testicular biopsies versus 3 pooled control testicular biposies form patients with normal spermatogenesis. A total of 12 experiments was carried out including biological and technical replicates.

Project description:Objective: Klinefelter Syndrome (KS) is the most common sexual chromosome abnormality (47,XXY) and represents the first genetic cause of male infertility. The mechanisms leading to KS testis degeneration are still unclear and no therapy is so far available for affected patients. The present study is aimed to unravel information about molecules playing a key role in the disruption of the spermatogenesis. Design: Gene expression profiles analysis of KS azoospermic testis versus normal testis, could provide useful information about the molecular basis of the alteration of the spermatogenesis. Materials and Methods: Transcriptome analysis was performed carrying out gene expression profile by a whole genome microarray approach on testis biopsies obtained from 6 azoospermic non-mosaic KS men and from 3 controls, for a total of 12 experiments. T-test and False Discovery Rate were used to evaluate differentially expressed genes. Identified transcripts were analysed by Ingenuity Pathways Analysis software to disclose genes biological functions. Results: Data analysis revealed the differentially up- and down-expression, in KS testis versus the control ones, of 656 and 247 genes related to Endocrine system development and function, Lipid metabolism, Reproductive disease, Free radical scavenging, and Cell death. Conclusions: Take together these data show the presence of several genes involved in testis microenvironment deregulation leading to the spermatogenesis failure. This information, associated with an early diagnosis could help to unravel possible therapeutic targets for testis failure prevention and limitation.

Project description:Patients with Klinefelter Syndrome have the karyotype 47,XXY. These men are suffering from hypergonadotropic hypogonadism and are infertile. It is debated whether the different hormonal constitution observed in these patients or different gene expression With the Microarray analysis we could identify genes on the X-chromosomes that are upregulated in KS-patietns compared to healthy male controls. But also autosomal genes were found to be differentially regulated.

Project description:Klinefelter’s Syndrome (KS) is one of the common chromosome aneuploidy diseases in males with unexplained physiological mechanism. iPSCs, are similar to ESCs in terms of indefinitive self-renewal and pluripotency, provided an alternative choice for modeling disease to facilitate the disease research in vitro. We used microarray to detect the global reprogramming of KS and normal fibroblast cells to iPSCs. Also we used microarray to explore the possible molecular varieties between KS patient and normal person in the early development. Fibroblast cells from both normal person and KS patient were reprogrammed into iPSCs by ectopic expression of OCT4, SOX2, KLF4 and C-MYC. The expression profiles of normal and KS fibroblast cells, a line of normal iPSCs and two lines of KS iPSCs as well as a line of human ESCs were detected.