Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Transcription levels of a noncoding RNA orchestrate opposing regulatory and cell fate outcomes in yeast

Project description:It is established that the transcription factor E2A and its antagonist Id3 modulate the checkpoints consisting of the precursor to the T cell antigen receptor (pre-TCR) and the TCR. Here we demonstrate that Id3 expression was higher beyond the pre-TCR checkpoint, remained high in naive T cells and showed a bimodal pattern in the effector-memory population. We show how E2A promoted T lineage specification and how pre-TCR-mediated signaling affected E2A genome-wide occupancy. Thymi in Id3-deficient mice had aberrant development of effector-memory cells, higher expression of the chemokine receptor CXCR5 and the transcriptional repressor Bcl-6 and, unexpectedly, T cell-B cell conjugates and B cell follicles. Collectively, our data show how E2A acted globally to orchestrate development into the T lineage and that Id3 antagonized E2A activity beyond the pre-TCR checkpoint to enforce the naive fate of T cells.

Project description:Long noncoding RNAs (lncRNA) play diverse roles in gene regulation controlling key cellular processes, most notably, cell-fate programming {Anderson, 2016 #20;Flynn, 2014 #16;Guttman, 2011 #35;Wang, 2011 #18}. Many long noncoding RNAs (lncRNAs) act in cis through transcription-coupled chromatin alterations that drive changes in local gene expression { Martens, 2004 #47; Kim, 2012 #74;van Werven, 2012 #57;Hainer, 2011 #73;Kim, 2016 #41;Ard, 2016 #21;Latos, 2012 #7}. How transcription of some lncRNAs leads to activation of gene expression, while others inhibit and repress gene expression remains poorly understood {Kornienko, 2013 #17}. Here we investigated in S. cerevisiae the function of the lncRNA IRT2, which is expressed upstream in the promoter of the master regulator for entry into meiosis, IME1. We report the surprising finding that distinct levels of IRT2 transcription regulates opposing chromatin and transcription states in order to ensure that only diploids, and not haploids, enter meiosis and form gametes. In haploid cells, IRT2 transcription at very low levels is required for the correct induction of the adjacent lncRNA IRT1, which in turn represses the IME1 promoter and prevents meiotic entry {van Werven, 2012 #57}. Low levels of IRT2 transcription stimulates histone exchange delivering acetylated histone H3 lysine 56 (H3K56ac) to chromatin, thereby facilitating chromatin disassembly and recruitment of the transcriptional activator of IRT1, Rme1. Inhibiting IRT2 transcription, or mutations that resulted in cells lacking H3K56ac impairs Rme1 recruitment and IRT1 induction, and consequently haploid cells induce IME1 and undergo a lethal meiosis. In contrast to its function at low levels, increasing IRT2 transcription enhances transcription-coupled chromatin assembly and interferes with IRT1 expression, promoting IME1 expression and meiotic entry in diploid cells {Moretto, 2018 #10}. Thus, transcription of lncRNAs, even at very low levels, can play an important role in regulating gene expression, and changes in lncRNA transcription levels can confer distinct regulatory and cell fate outcomes.

Project description:Long noncoding RNAs (lncRNA) play diverse roles in gene regulation controlling key cellular processes, most notably, cell-fate programming {Anderson, 2016 #20;Flynn, 2014 #16;Guttman, 2011 #35;Wang, 2011 #18}. Many long noncoding RNAs (lncRNAs) act in cis through transcription-coupled chromatin alterations that drive changes in local gene expression { Martens, 2004 #47; Kim, 2012 #74;van Werven, 2012 #57;Hainer, 2011 #73;Kim, 2016 #41;Ard, 2016 #21;Latos, 2012 #7}. How transcription of some lncRNAs leads to activation of gene expression, while others inhibit and repress gene expression remains poorly understood {Kornienko, 2013 #17}. Here we investigated in S. cerevisiae the function of the lncRNA IRT2, which is expressed upstream in the promoter of the master regulator for entry into meiosis, IME1. We report the surprising finding that distinct levels of IRT2 transcription regulates opposing chromatin and transcription states in order to ensure that only diploids, and not haploids, enter meiosis and form gametes. In haploid cells, IRT2 transcription at very low levels is required for the correct induction of the adjacent lncRNA IRT1, which in turn represses the IME1 promoter and prevents meiotic entry {van Werven, 2012 #57}. Low levels of IRT2 transcription stimulates histone exchange delivering acetylated histone H3 lysine 56 (H3K56ac) to chromatin, thereby facilitating chromatin disassembly and recruitment of the transcriptional activator of IRT1, Rme1. Inhibiting IRT2 transcription, or mutations that resulted in cells lacking H3K56ac impairs Rme1 recruitment and IRT1 induction, and consequently haploid cells induce IME1 and undergo a lethal meiosis. In contrast to its function at low levels, increasing IRT2 transcription enhances transcription-coupled chromatin assembly and interferes with IRT1 expression, promoting IME1 expression and meiotic entry in diploid cells {Moretto, 2018 #10}. Thus, transcription of lncRNAs, even at very low levels, can play an important role in regulating gene expression, and changes in lncRNA transcription levels can confer distinct regulatory and cell fate outcomes.

Project description:Long noncoding RNAs (lncRNA) play diverse roles in gene regulation controlling key cellular processes, most notably, cell-fate programming {Anderson, 2016 #20;Flynn, 2014 #16;Guttman, 2011 #35;Wang, 2011 #18}. Many long noncoding RNAs (lncRNAs) act in cis through transcription-coupled chromatin alterations that drive changes in local gene expression { Martens, 2004 #47; Kim, 2012 #74;van Werven, 2012 #57;Hainer, 2011 #73;Kim, 2016 #41;Ard, 2016 #21;Latos, 2012 #7}. How transcription of some lncRNAs leads to activation of gene expression, while others inhibit and repress gene expression remains poorly understood {Kornienko, 2013 #17}. Here we investigated in S. cerevisiae the function of the lncRNA IRT2, which is expressed upstream in the promoter of the master regulator for entry into meiosis, IME1. We report the surprising finding that distinct levels of IRT2 transcription regulates opposing chromatin and transcription states in order to ensure that only diploids, and not haploids, enter meiosis and form gametes. In haploid cells, IRT2 transcription at very low levels is required for the correct induction of the adjacent lncRNA IRT1, which in turn represses the IME1 promoter and prevents meiotic entry {van Werven, 2012 #57}. Low levels of IRT2 transcription stimulates histone exchange delivering acetylated histone H3 lysine 56 (H3K56ac) to chromatin, thereby facilitating chromatin disassembly and recruitment of the transcriptional activator of IRT1, Rme1. Inhibiting IRT2 transcription, or mutations that resulted in cells lacking H3K56ac impairs Rme1 recruitment and IRT1 induction, and consequently haploid cells induce IME1 and undergo a lethal meiosis. In contrast to its function at low levels, increasing IRT2 transcription enhances transcription-coupled chromatin assembly and interferes with IRT1 expression, promoting IME1 expression and meiotic entry in diploid cells {Moretto, 2018 #10}. Thus, transcription of lncRNAs, even at very low levels, can play an important role in regulating gene expression, and changes in lncRNA transcription levels can confer distinct regulatory and cell fate outcomes.

Project description:Long noncoding RNAs (lncRNA) play diverse roles in gene regulation controlling key cellular processes, most notably, cell-fate programming {Anderson, 2016 #20;Flynn, 2014 #16;Guttman, 2011 #35;Wang, 2011 #18}. Many long noncoding RNAs (lncRNAs) act in cis through transcription-coupled chromatin alterations that drive changes in local gene expression { Martens, 2004 #47; Kim, 2012 #74;van Werven, 2012 #57;Hainer, 2011 #73;Kim, 2016 #41;Ard, 2016 #21;Latos, 2012 #7}. How transcription of some lncRNAs leads to activation of gene expression, while others inhibit and repress gene expression remains poorly understood {Kornienko, 2013 #17}. Here we investigated in S. cerevisiae the function of the lncRNA IRT2, which is expressed upstream in the promoter of the master regulator for entry into meiosis, IME1. We report the surprising finding that distinct levels of IRT2 transcription regulates opposing chromatin and transcription states in order to ensure that only diploids, and not haploids, enter meiosis and form gametes. In haploid cells, IRT2 transcription at very low levels is required for the correct induction of the adjacent lncRNA IRT1, which in turn represses the IME1 promoter and prevents meiotic entry {van Werven, 2012 #57}. Low levels of IRT2 transcription stimulates histone exchange delivering acetylated histone H3 lysine 56 (H3K56ac) to chromatin, thereby facilitating chromatin disassembly and recruitment of the transcriptional activator of IRT1, Rme1. Inhibiting IRT2 transcription, or mutations that resulted in cells lacking H3K56ac impairs Rme1 recruitment and IRT1 induction, and consequently haploid cells induce IME1 and undergo a lethal meiosis. In contrast to its function at low levels, increasing IRT2 transcription enhances transcription-coupled chromatin assembly and interferes with IRT1 expression, promoting IME1 expression and meiotic entry in diploid cells {Moretto, 2018 #10}. Thus, transcription of lncRNAs, even at very low levels, can play an important role in regulating gene expression, and changes in lncRNA transcription levels can confer distinct regulatory and cell fate outcomes.

Project description:Termination of RNA polymerase II (RNAPII) transcription is a fundamental step of gene expression that is critical for determining the borders between genes. In budding yeast, termination at protein-coding genes is initiated by the cleavage/polyadenylation machinery, whereas termination of most noncoding RNA (ncRNA) genes occurs via the Nrd1-Nab3-Sen1 (NNS) pathway. Here, we find that NNS-like transcription termination is not conserved in fission yeast. Rather, genome-wide analyses show global recruitment of mRNA 3' end processing factors at the end of ncRNA genes, including snoRNAs and snRNAs, and that this recruitment coincides with high levels of Ser2 and Tyr1 phosphorylation on the RNAPII C-terminal domain. We also find that termination of mRNA and ncRNA transcription requires the conserved Ysh1/CPSF-73 and Dhp1/XRN2 nucleases, supporting widespread cleavage-dependent transcription termination in fission yeast. Our findings thus reveal that a common mode of transcription termination can produce functionally and structurally distinct types of polyadenylated and non-polyadenylated RNAs.

Project description:This article describes the creation of the first expert manually curated noncoding RNA interaction networks for S. cerevisiae The RNA-RNA and RNA-protein interaction networks have been carefully extracted from the experimental literature and made available through the IntAct database (www.ebi.ac.uk/intact). We provide an initial network analysis and compare their properties to the much larger protein-protein interaction network. We find that the proteins that bind to ncRNAs in the network contain only a small proportion of classical RNA binding domains. We also see an enrichment of WD40 domains suggesting their direct involvement in ncRNA interactions. We discuss the challenges in collecting noncoding RNA interaction data and the opportunities for worldwide collaboration to fill the unmet need for this data.

Project description:Transcription levels of a long noncoding RNA shape a cell fate regulatory circuit (TES-seq)