Project description:In therian mammals, X-chromosomal genes are expressed only from a single active X chromosome, both in males (XY) as well as females (XX). To compensate for this reduction in dosage compared to the evolutionary ancestral state on two autosomes, it has been proposed that genes from the active X chromosome exhibit dosage compensation (“Ohno’s hypothesis”). However, the existence and mechanism of X-to-autosome dosage compensation are still under debate. Here, we show that dosage compensation is achieved via differential N6-methyladenosine (m6A) RNA modification. X-chromosomal transcripts are reduced in m6A modifications and more stable compared to the autosomal counterparts. Acute depletion of m6A using a small molecule inhibitor differentially affects autosomal and X-chromosomal transcripts across sexes, cell types, tissues and species, resulting in perturbed dosage compensation. We propose that higher stability of X-chromosomal transcripts is directed by lower levels of m6A, indicating that mammalian dosage compensation occurs via epitranscriptomic RNA regulation.

Project description:In therian mammals, X-chromosomal genes are expressed only from a single active X chromosome, both in males (XY) as well as females (XX). To compensate for this reduction in dosage compared to the evolutionary ancestral state on two autosomes, it has been proposed that genes from the active X chromosome exhibit dosage compensation (“Ohno’s hypothesis”). However, the existence and mechanism of X-to-autosome dosage compensation are still under debate. Here, we show that dosage compensation is achieved via differential N6-methyladenosine (m6A) RNA modification. X-chromosomal transcripts are reduced in m6A modifications and more stable compared to the autosomal counterparts. Acute depletion of m6A using a small molecule inhibitor differentially affects autosomal and X-chromosomal transcripts across sexes, cell types, tissues and species, resulting in perturbed dosage compensation. We propose that higher stability of X-chromosomal transcripts is directed by lower levels of m6A, indicating that mammalian dosage compensation occurs via epitranscriptomic RNA regulation.

Project description:In therian mammals, X-chromosomal genes are expressed only from a single active X chromosome, both in males (XY) as well as females (XX). To compensate for this reduction in dosage compared to the evolutionary ancestral state on two autosomes, it has been proposed that genes from the active X chromosome exhibit dosage compensation (“Ohno’s hypothesis”). However, the existence and mechanism of X-to-autosome dosage compensation are still under debate. Here, we show that dosage compensation is achieved via differential N6-methyladenosine (m6A) RNA modification. X-chromosomal transcripts are reduced in m6A modifications and more stable compared to the autosomal counterparts. Acute depletion of m6A using a small molecule inhibitor differentially affects autosomal and X-chromosomal transcripts across sexes, cell types, tissues and species, resulting in perturbed dosage compensation. We propose that higher stability of X-chromosomal transcripts is directed by lower levels of m6A, indicating that mammalian dosage compensation occurs via epitranscriptomic RNA regulation.

Project description:In mammals, X-chromosomal genes are expressed from a single copy since males (XY) possess a single X chromosome, while females (XX) undergo X inactivation. To compensate for this reduction in dosage compared to two active copies of autosomes, it has been proposed that genes from the active X chromosome exhibit dosage compensation. However, the existence and mechanism of X-to-autosome dosage compensation are still under debate. Here, we show that X-chromosomal transcripts are reduced in m6A modifications and more stable compared to their autosomal counterparts. Acute depletion of m6A selectively stabilises autosomal transcripts, resulting in perturbed dosage compensation in mouse embryonic stem cells. We propose that higher stability of X-chromosomal transcripts is directed by lower levels of m6A, indicating that mammalian dosage compensation is partly regulated by epitranscriptomic RNA modifications.

Project description:In mammals, X-chromosomal genes are expressed from a single copy since males (XY) possess a single X chromosome, while females (XX) undergo X inactivation. To compensate for this reduction in dosage compared to two active copies of autosomes, it has been proposed that genes from the active X chromosome exhibit dosage compensation. However, the existence and mechanism of X-to-autosome dosage compensation are still under debate. Here, we show that X-chromosomal transcripts are reduced in m6A modifications and more stable compared to their autosomal counterparts. Acute depletion of m6A selectively stabilises autosomal transcripts, resulting in perturbed dosage compensation in mouse embryonic stem cells. We propose that higher stability of X-chromosomal transcripts is directed by lower levels of m6A, indicating that mammalian dosage compensation is partly regulated by epitranscriptomic RNA modifications.

Project description:Many animal species employ a chromosome-based mechanism of sex determination, which has led to coordinate evolution of dosage compensation systems. Dosage compensation not only corrects the imbalance in the number of X-chromosomes between the sexes, but is also hypothesized to correct dosage imbalance within cells due to mono-allelic X expression and bi-allelic autosomal expression, by upregulating X-linked genes (termed ‘Ohno’s hypothesis’). It is unknown whether any epigenetic mark or protein is involved in X upregulation in mammals. Ser-5 phosphorylated RNA polymerase II (PolII S5p) is required for transcription initiation. Chromatin immunoprecipitation combined with DNA tiling array analysis (ChIP-chip) of PolII S5p in mouse female ES cells with two active X chromosomes demonstrated a greater enrichment of RNA polymerase II on X-linked genes relative to autosomal genes, suggesting that enhanced transcription initiation may play a role in X upregulation. Comparison of RNA PolII S5p enrichment on the X versus autosomes in mouse

Project description:Many animal species employ a chromosome-based mechanism of sex determination, which has led to coordinate evolution of dosage compensation systems. Dosage compensation not only corrects the imbalance in the number of X-chromosomes between the sexes, but is also hypothesized to correct dosage imbalance within cells due to mono-allelic X expression and bi-allelic autosomal expression, by upregulating X-linked genes (termed ‘Ohno’s hypothesis’). It is unknown whether any epigenetic mark or protein is involved in X upregulation in mammals. Ser-5 phosphorylated RNA polymerase II (PolII S5p) is required for transcription initiation. Chromatin immunoprecipitation combined with DNA tiling array analysis (ChIP-chip) of PolII S5p in mouse female ES cells with two active X chromosomes demonstrated a greater enrichment of RNA polymerase II on X-linked genes relative to autosomal genes, suggesting that enhanced transcription initiation may play a role in X upregulation.

Project description:The rules according to which transcription factors selectively bind only a small subset of genomic sites from a vast pool of similar sequences are not understood. One of the most challenging tasks in DNA recognition is posed by dosage compensation systems that require the unequivocal distinction between a sex chromosome and all autosomes. In Drosophila melanogaster the male-specific-lethal dosage compensation complex (MSL-DCC) doubles the transcription output of most genes on the X chromosome via chromatin modification, but the nature of this selectivity is not known. We now found that MSL2, the male-specific organizer of the DCC, uses two distinct DNA interaction surfaces to read out previously identified X chromosomal ‘high affinity sites’. Specificity is provided by the interaction of the CXC domain with a novel, X-specific motif defined by DNA sequence and shape features. By several criteria these ‘PionX sites’ are primary determinants of X chromosome identity.

Project description:Many animal species employ a chromosome-based mechanism of sex determination, which has led to coordinate evolution of dosage compensation systems. Dosage compensation not only corrects the imbalance in the number of X-chromosomes between the sexes, but is also hypothesized to correct dosage imbalance within cells due to mono-allelic X expression and bi-allelic autosomal expression, by upregulating X-linked genes (termed ‘Ohno’s hypothesis’). To identify molecular mechanisms of X upregulation in mammals we established genome-wide profiles for the initiation and elongation forms of RNA polymerase II (PolII), PolII-S5p (phosphorylated at serine 5) and PolII-S2p (phosphorylated at serine 2), and for histone modifications in mouse cell lines and tissues. We found that in addition to being enriched in PolII-S5p but not in PolII-S2p, X-linked promoters were also enriched in two epigenetic marks, H4K16ac and H2AZ, dependent on expression levels. To address the function of the H4K16 acetyltransferase MOF occupancy profiles were established and knockdowns of MOF and MSL1 were done in mouse ES cells. Our results support a conserved role for the MSL complex to enhance transcription initiation of X-linked genes.

Project description:The rules according to which transcription factors selectively bind only a small subset of genomic sites from a vast pool of similar sequences are not understood. One of the most challenging tasks in DNA recognition is posed by dosage compensation systems that require the unequivocal distinction between a sex chromosome and all autosomes. In Drosophila melanogaster the male-specific-lethal dosage compensation complex (MSL-DCC) doubles the transcription output of most genes on the X chromosome via chromatin modification, but the nature of this selectivity is not known. We now found that MSL2, the male-specific organizer of the DCC, uses two distinct DNA interaction surfaces to read out previously identified X chromosomal ‘high affinity sites’. Specificity is provided by the interaction of the CXC domain with a novel, X-specific motif defined by DNA sequence and shape features. By several criteria these ‘PionX sites’ are primary determinants of X chromosome identity.