Project description:Cellular source and mechanisms of high transcriptome complexity in the mammalian testis (RNA-Seq organs)

Project description:Cellular source and mechanisms of high transcriptome complexity in the mammalian testis (RNA-Seq cells)

Project description:Understanding  the  extent  of  genomic  transcription  and  its  functional  relevance  is  a  central  goal  in  genomics research. However, detailed genome‐wide investigations of transcriptome complexities in major mammalian organs  and  their  underlying  cellular  sources,  transcriptional  mechanisms,  and  functional  relevance  have been  scarce.  Here  we  first  show,  using  extensive  RNA‐seq  data,  that  transcription  of  both  functional  and nonfunctional  genomic  elements  is  substantially  more  widespread  in  the  testis  than  in  other  organs  across representative mammals. By scrutinizing the transcriptomes of all main testicular cell types in the mouse, we then  reveal  that meiotic  spermatocytes  and  especially  post‐meiotic  round  spermatids  have  remarkably diverse  transcriptomes,  which  explains  the  high  transcriptome  complexity  of  the  testis  as  a  whole.  The widespread  transcriptional  activity  in  spermatocytes  and  spermatids  encompasses  protein‐coding  genes  and long  noncoding  RNA  genes  but  also  poorly  conserved  intergenic  sequences,  suggesting  that  much  of  it  is  not of  immediate  functional  relevance.  Rather,  our  analyses  of  genome‐wide  epigenetic  data  show  that  this prevalent  transcription,  which  apparently  promoted  the  birth  of  new  genes  during  evolution,  results  from  a highly  permissive  chromatin  state  during  and  after  meiosis  that  may  ultimately  facilitate  the  replacement  of histones by protamines during late spermatogenesis. To study the cellular source and mechanisms of high transcriptome complexity in the mammalian testis, we generated strand-specific deep coverage RNA‐Seq data for purified sertoli cells, spermatogonia, spermatocytes, spermatids and spermatozoa as well as for brain, liver and the whole testis from the mouse. We prepared 8 sequencing libraries for the polyadenylated RNA fraction of each sample and sequenced each library in 3 lanes of the Illumina Genome Analyser IIx platform, yielding a total of >60 millions strand-specific reads of 76 base pairs per sample. In addition, we generated ChIP-Seq data for the H3K4me2 modification as well as RRBS data for brain, liver, testis, spermatocytes and spermatids. RNA-seq, ChIP-seq and RRBS data were generated from the same individual or pool of individuals, in the case of purified cells. ChIP-Seq data for the H3K4me2 modification as well as RRBS data for brain, liver, testis, spermatocytes and spermatids

Project description:Understanding  the  extent  of  genomic  transcription  and  its  functional  relevance  is  a  central  goal  in  genomics research. However, detailed genome‐wide investigations of transcriptome complexities in major mammalian organs  and  their  underlying  cellular  sources,  transcriptional  mechanisms,  and  functional  relevance  have been  scarce.  Here  we  first  show,  using  extensive  RNA‐seq  data,  that  transcription  of  both  functional  and nonfunctional  genomic  elements  is  substantially  more  widespread  in  the  testis  than  in  other  organs  across representative mammals. By scrutinizing the transcriptomes of all main testicular cell types in the mouse, we then  reveal  that meiotic  spermatocytes  and  especially  post‐meiotic  round  spermatids  have  remarkably diverse  transcriptomes,  which  explains  the  high  transcriptome  complexity  of  the  testis  as  a  whole.  The widespread  transcriptional  activity  in  spermatocytes  and  spermatids  encompasses  protein‐coding  genes  and long  noncoding  RNA  genes  but  also  poorly  conserved  intergenic  sequences,  suggesting  that  much  of  it  is  not of  immediate  functional  relevance.  Rather,  our  analyses  of  genome‐wide  epigenetic  data  show  that  this prevalent  transcription,  which  apparently  promoted  the  birth  of  new  genes  during  evolution,  results  from  a highly  permissive  chromatin  state  during  and  after  meiosis  that  may  ultimately  facilitate  the  replacement  of histones by protamines during late spermatogenesis. To study the cellular source and mechanisms of high transcriptome complexity in the mammalian testis, we generated strand-specific deep coverage RNA‐Seq data for purified sertoli cells, spermatogonia, spermatocytes, spermatids and spermatozoa as well as for brain, liver and the whole testis from the mouse. We prepared 8 sequencing libraries for the polyadenylated RNA fraction of each sample and sequenced each library in 3 lanes of the Illumina Genome Analyser IIx platform, yielding a total of >60 millions strand-specific reads of 76 base pairs per sample. In addition, we generated ChIP-Seq data for the H3K4me2 modification as well as RRBS data for brain, liver, testis, spermatocytes and spermatids. RNA-seq, ChIP-seq and RRBS data were generated from the same individual or pool of individuals, in the case of purified cells. RNA-Seq of brain, liver and the whole testis

Project description:Understanding the extent of genomic transcription and its functional relevance is a central goal in genomics research. However, detailed genome€wide investigations of transcriptome complexities in major mammalian organs  and  their  underlying  cellular sources, transcriptional mechanisms, and functional relevance have been scarce. Here we first show, using extensive RNA€seq data, that transcription of both functional and nonfunctional genomic elements is substantially more widespread in the testis than in other organs across representative mammals. By scrutinizing the transcriptomes of all main testicular cell types in the mouse, we then reveal that meiotic  spermatocytes and especially post€meiotic round spermatids have remarkably diverse transcriptomes, which explains the high transcriptome  complexity of the testis as a whole. The widespread transcriptional activity in spermatocytes and spermatids encompasses protein €coding genes and long noncoding RNA genes but also poorly conserved intergenic sequences, suggesting that much of it is not of immediate functional relevance.  Rather, our analyses of genome€wide epigenetic data show that this prevalent transcription, which apparently promoted the birth of new genes during evolution, results from a highly permissive chromatin state during and after meiosis that may ultimately facilitate the replacement of histones by protamines during late spermatogenesis. To study the cellular source and mechanisms of high transcriptome complexity in the mammalian testis, we generated strand-specific deep coverage RNA€Seq data for purified sertoli cells, spermatogonia, spermatocytes, spermatids and spermatozoa as well as for brain, liver and the whole testis from the mouse. We prepared 8 sequencing libraries for the polyadenylated RNA fraction of each sample and sequenced each library in 3 lanes of the Illumina Genome Analyser IIx platform, yielding a total of >60 millions strand-specific reads of 76 base pairs per sample. In addition, we generated ChIP-Seq data for the H3K4me2 modification as well as RRBS data for brain, liver, testis, spermatocytes and spermatids. RNA-seq, ChIP-seq and RRBS data were generated from the same individual or pool of individuals, in the case of purified cells. RNA€Seq data for purified sertoli cells, spermatogonia, spermatocytes, spermatids and spermatozoa

Project description:Understanding  the  extent  of  genomic  transcription  and  its  functional  relevance  is  a  central  goal  in  genomics research. However, detailed genome‐wide investigations of transcriptome complexities in major mammalian organs  and  their  underlying  cellular  sources,  transcriptional  mechanisms,  and  functional  relevance  have been  scarce.  Here  we  first  show,  using  extensive  RNA‐seq  data,  that  transcription  of  both  functional  and nonfunctional  genomic  elements  is  substantially  more  widespread  in  the  testis  than  in  other  organs  across representative mammals. By scrutinizing the transcriptomes of all main testicular cell types in the mouse, we then  reveal  that meiotic  spermatocytes  and  especially  post‐meiotic  round  spermatids  have  remarkably diverse  transcriptomes,  which  explains  the  high  transcriptome  complexity  of  the  testis  as  a  whole.  The widespread  transcriptional  activity  in  spermatocytes  and  spermatids  encompasses  protein‐coding  genes  and long  noncoding  RNA  genes  but  also  poorly  conserved  intergenic  sequences,  suggesting  that  much  of  it  is  not of  immediate  functional  relevance.  Rather,  our  analyses  of  genome‐wide  epigenetic  data  show  that  this prevalent  transcription,  which  apparently  promoted  the  birth  of  new  genes  during  evolution,  results  from  a highly  permissive  chromatin  state  during  and  after  meiosis  that  may  ultimately  facilitate  the  replacement  of histones by protamines during late spermatogenesis. To study the cellular source and mechanisms of high transcriptome complexity in the mammalian testis, we generated strand-specific deep coverage RNA‐Seq data for purified sertoli cells, spermatogonia, spermatocytes, spermatids and spermatozoa as well as for brain, liver and the whole testis from the mouse. We prepared 8 sequencing libraries for the polyadenylated RNA fraction of each sample and sequenced each library in 3 lanes of the Illumina Genome Analyser IIx platform, yielding a total of >60 millions strand-specific reads of 76 base pairs per sample. In addition, we generated ChIP-Seq data for the H3K4me2 modification as well as RRBS data for brain, liver, testis, spermatocytes and spermatids. RNA-seq, ChIP-seq and RRBS data were generated from the same individual or pool of individuals, in the case of purified cells.

Project description:Understanding  the  extent  of  genomic  transcription  and  its  functional  relevance  is  a  central  goal  in  genomics research. However, detailed genome‐wide investigations of transcriptome complexities in major mammalian organs  and  their  underlying  cellular  sources,  transcriptional  mechanisms,  and  functional  relevance  have been  scarce.  Here  we  first  show,  using  extensive  RNA‐seq  data,  that  transcription  of  both  functional  and nonfunctional  genomic  elements  is  substantially  more  widespread  in  the  testis  than  in  other  organs  across representative mammals. By scrutinizing the transcriptomes of all main testicular cell types in the mouse, we then  reveal  that meiotic  spermatocytes  and  especially  post‐meiotic  round  spermatids  have  remarkably diverse  transcriptomes,  which  explains  the  high  transcriptome  complexity  of  the  testis  as  a  whole.  The widespread  transcriptional  activity  in  spermatocytes  and  spermatids  encompasses  protein‐coding  genes  and long  noncoding  RNA  genes  but  also  poorly  conserved  intergenic  sequences,  suggesting  that  much  of  it  is  not of  immediate  functional  relevance.  Rather,  our  analyses  of  genome‐wide  epigenetic  data  show  that  this prevalent  transcription,  which  apparently  promoted  the  birth  of  new  genes  during  evolution,  results  from  a highly  permissive  chromatin  state  during  and  after  meiosis  that  may  ultimately  facilitate  the  replacement  of histones by protamines during late spermatogenesis. To study the cellular source and mechanisms of high transcriptome complexity in the mammalian testis, we generated strand-specific deep coverage RNA‐Seq data for purified sertoli cells, spermatogonia, spermatocytes, spermatids and spermatozoa as well as for brain, liver and the whole testis from the mouse. We prepared 8 sequencing libraries for the polyadenylated RNA fraction of each sample and sequenced each library in 3 lanes of the Illumina Genome Analyser IIx platform, yielding a total of >60 millions strand-specific reads of 76 base pairs per sample. In addition, we generated ChIP-Seq data for the H3K4me2 modification as well as RRBS data for brain, liver, testis, spermatocytes and spermatids. RNA-seq, ChIP-seq and RRBS data were generated from the same individual or pool of individuals, in the case of purified cells.

Project description:Understanding  the  extent  of  genomic  transcription  and  its  functional  relevance  is  a  central  goal  in  genomics research. However, detailed genome‐wide investigations of transcriptome complexities in major mammalian organs  and  their  underlying  cellular  sources,  transcriptional  mechanisms,  and  functional  relevance  have been  scarce.  Here  we  first  show,  using  extensive  RNA‐seq  data,  that  transcription  of  both  functional  and nonfunctional  genomic  elements  is  substantially  more  widespread  in  the  testis  than  in  other  organs  across representative mammals. By scrutinizing the transcriptomes of all main testicular cell types in the mouse, we then  reveal  that meiotic  spermatocytes  and  especially  post‐meiotic  round  spermatids  have  remarkably diverse  transcriptomes,  which  explains  the  high  transcriptome  complexity  of  the  testis  as  a  whole.  The widespread  transcriptional  activity  in  spermatocytes  and  spermatids  encompasses  protein‐coding  genes  and long  noncoding  RNA  genes  but  also  poorly  conserved  intergenic  sequences,  suggesting  that  much  of  it  is  not of  immediate  functional  relevance.  Rather,  our  analyses  of  genome‐wide  epigenetic  data  show  that  this prevalent  transcription,  which  apparently  promoted  the  birth  of  new  genes  during  evolution,  results  from  a highly  permissive  chromatin  state  during  and  after  meiosis  that  may  ultimately  facilitate  the  replacement  of histones by protamines during late spermatogenesis. To study the cellular source and mechanisms of high transcriptome complexity in the mammalian testis, we generated strand-specific deep coverage RNA‐Seq data for purified sertoli cells, spermatogonia, spermatocytes, spermatids and spermatozoa as well as for brain, liver and the whole testis from the mouse. We prepared 8 sequencing libraries for the polyadenylated RNA fraction of each sample and sequenced each library in 3 lanes of the Illumina Genome Analyser IIx platform, yielding a total of >60 millions strand-specific reads of 76 base pairs per sample. In addition, we generated ChIP-Seq data for the H3K4me2 modification as well as RRBS data for brain, liver, testis, spermatocytes and spermatids. RNA-seq, ChIP-seq and RRBS data were generated from the same individual or pool of individuals, in the case of purified cells.

Project description:Todate, the investigation into the molecular mechanisms of testis development and spermatogenesis has largely focused on the role of protein-coding genes and small noncoding RNA including microRNAs and piRNAs. In recent years, long noncoding RNAs (lncRNAs) have been shown to play critical regulatory roles in mammalian development. To understand the role of lncRNAs in development of the mammalian testis and spermatogenesis, we firstly utilized commercial microarray to systematically investigate lncRNAs expression profiles of neonatal (6-day-old) and adult (8-week-old) mouse testis. By comparison the lncRNAs expression profiles of two developmental stage of testes, we obtained the differentially expressed lncRNAs and examined their genomic context, promoter characteristics, neighbored protein-coding genes, provide an important foundation for future research on molecular mechanisms of lncRNAs in mammalian testis development and spermatogenesis.

Project description:A major event in mammalian male sex determination is the induction of the testis determining factor Sry and its downstream gene Sox9. The current study provides one of the first genome wide analyses of the downstream gene binding targets for SRY and SOX9 to help elucidate the molecular control of Sertoli cell differentiation and testis development. A modified ChIP-Chip analysis using a comparative hybridization was used to identify 71 direct downstream binding targets for SRY and 109 binding targets for SOX9. Interestingly, only 5 gene targets overlapped between SRY and SOX9. In addition to the direct response element binding gene targets, a large number of atypical binding gene targets were identified for both SRY and SOX9. Bioinformatic analysis of the downstream binding targets identified gene networks and cellular pathways potentially involved in the induction of Sertoli cell differentiation and testis development. The specific DNA sequence binding site motifs for both SRY and SOX9 were identified. Observations provide insights into the molecular control of male gonadal sex determination. The current study provides one of the first genome wide analyses of the downstream gene binding targets for SRY and SOX9 to help elucidate the molecular control of Sertoli cell differentiation and testis development. At embryonic day 13 (E13) of pregnancy rats were euthanized and embryonic gonads were collected for chromatin. A modified ChIP-Chip analysis using a comparative hybridization was used to identify direct downstream binding targets for SRY and for SOX9. Then, bioinformatic analysis of the downstream binding targets was done to identify gene networks and cellular pathways that are potentially involved in the induction of Sertoli cell differentiation and testis development.