Project description:Biallelic expression is important to ensure adequate mRNA levels as well as protect cells from deleterious heterozygous mutations. However, the factors determining biallelic expression at individual gene loci are unknown. Deletion of the MSL complex component MSL2 in hybrid mouse NPCs uncovers an unprecedented function for MSL2 in allelic regulation. While biallelically expressed in wildtype NPCs, a class of MSL2 targets switches from bi to monoallelic expression upon MSL2 loss. The silenced allele loses nascent transcription, accompanied by dramatic changes in local chromatin landscape such as monoallelic gain of H3K27me3 and DNA methylation. Meanwhile, active histone modifications, RNA POL II, BRD4 and KANSL3 are retained on the active allele. MSL2 targets include several sex-biased genes on autosomes as well as X-chromosomal genes that escape X inactivation. Together, the allele-specific resolution allowed us to unravel an MSL2 mediated safeguarding mechanism to promote biallelic gene expression of sexually dimorphic and dosage-sensitive genes in mammals.

Project description:Biallelic expression is important to ensure adequate mRNA levels as well as protect cells from deleterious heterozygous mutations. However, the factors determining biallelic expression at individual gene loci are unknown. Deletion of the MSL complex component MSL2 in hybrid mouse NPCs uncovers an unprecedented function for MSL2 in allelic regulation. While biallelically expressed in wildtype NPCs, a class of MSL2 targets switches from bi to monoallelic expression upon MSL2 loss. The silenced allele loses nascent transcription, accompanied by dramatic changes in local chromatin landscape such as monoallelic gain of H3K27me3 and DNA methylation. Meanwhile, active histone modifications, RNA POL II, BRD4 and KANSL3 are retained on the active allele. MSL2 targets include several sex-biased genes on autosomes as well as X-chromosomal genes that escape X inactivation. Together, the allele-specific resolution allowed us to unravel an MSL2 mediated safeguarding mechanism to promote biallelic gene expression of sexually dimorphic and dosage-sensitive genes in mammals.

Project description:Biallelic expression is important to ensure adequate mRNA levels as well as protect cells from deleterious heterozygous mutations. However, the factors determining biallelic expression at individual gene loci are unknown. Deletion of the MSL complex component MSL2 in hybrid mouse NPCs uncovers an unprecedented function for MSL2 in allelic regulation. While biallelically expressed in wildtype NPCs, a class of MSL2 targets switches from bi to monoallelic expression upon MSL2 loss. The silenced allele loses nascent transcription, accompanied by dramatic changes in local chromatin landscape such as monoallelic gain of H3K27me3 and DNA methylation. Meanwhile, active histone modifications, RNA POL II, BRD4 and KANSL3 are retained on the active allele. MSL2 targets include several sex-biased genes on autosomes as well as X-chromosomal genes that escape X inactivation. Together, the allele-specific resolution allowed us to unravel an MSL2 mediated safeguarding mechanism to promote biallelic gene expression of sexually dimorphic and dosage-sensitive genes in mammals.

Project description:Allele-specific gene expression have been observed in genomic imprinting, X chromosome inactivation, allelic exclusion of immunoglobulin loci and non-canonical random monoallelic expression. Here we show that MSL2 can regulate allele specific gene expression and we elucidate its mechanism of action. MSL2 is known to regulate gene dosage up to two fold in drosophila and mammals. In addition to its canonical role as a milder modulator, we found that the loss of MSL2 switches off gene expression completely in an allele specific way and results in biallelic to monoallelic gene expression, which will be ignored as classical down regulated genes without applying the mouse hybrid F1 system. It indicates that MSL2 can activate the expression of the allele which is otherwise inactive intrinsically. We further found this is achieved by the interplay between MSL and KANSL complex. MSL2 acts as a methylation-insensitive factor, which can prevent DNA methylation of the inactive allele, thus facilitating occupancy of methylation-sensitive factor KANSL3 and activating the gene expression. The novel mechanism of MSL2 provides a safeguarding system to warrant biallelic gene expression of intrinsically monoallelic expressed genes including X-inactivated and imprinting genes. These genes are further discovered as sex bias genes such as X-inactivation escaped genes (escapees) are expressed higher in females. Furthermore, the biallelic expression of MSL2 regulated escapees may protect females from single loss of function mutation and contribute to male severer or predominance neurodevelopmental diseases.

Project description:Allele-specific gene expression have been observed in genomic imprinting, X chromosome inactivation, allelic exclusion of immunoglobulin loci and non-canonical random monoallelic expression. Here we show that MSL2 can regulate allele specific gene expression and we elucidate its mechanism of action. MSL2 is known to regulate gene dosage up to two fold in drosophila and mammals. In addition to its canonical role as a milder modulator, we found that the loss of MSL2 switches off gene expression completely in an allele specific way and results in biallelic to monoallelic gene expression, which will be ignored as classical down regulated genes without applying the mouse hybrid F1 system. It indicates that MSL2 can activate the expression of the allele which is otherwise inactive intrinsically. We further found this is achieved by the interplay between MSL and KANSL complex. MSL2 acts as a methylation-insensitive factor, which can prevent DNA methylation of the inactive allele, thus facilitating occupancy of methylation-sensitive factor KANSL3 and activating the gene expression. The novel mechanism of MSL2 provides a safeguarding system to warrant biallelic gene expression of intrinsically monoallelic expressed genes including X-inactivated and imprinting genes. These genes are further discovered as sex bias genes such as X-inactivation escaped genes (escapees) are expressed higher in females. Furthermore, the biallelic expression of MSL2 regulated escapees may protect females from single loss of function mutation and contribute to male severer or predominance neurodevelopmental diseases.

Project description:MSL2 is an allelic dosage sensor in mammals

Project description:BlCa: MSL2 is an allelic dosage sensor in mammals

Project description:CaBl: MSL2 is an allelic dosage sensor in mammals

Project description:BL6Mousei: MSL2 is an allelic dosage sensor in mammals

Project description:9sCa: MSL2 is an allelic dosage sensor in mammals