Project description:Multiple intron motifs have redundant functions in trans-splicing of the mod(mdg4) locus

Project description:Here we map the localization of Mod(mdg4), including Mod(mdg4)2.2 specific and Mod(mdg4) common to all isoforms, to chromatin insulators, as well as the lethal-3 malignant brain tumor protein in Drosophila Kc cells. examination of genomic occupancy for Mod(mdg4)2.2, Mod(mdg4)BTB (all isoforms), and L(3)mbt, control samples used for Drosophila Kc were previously described (Wood, Van Bortle et al., 2011 GSE30740)

Project description:Here we map the localization of Mod(mdg4), including Mod(mdg4)2.2 specific and Mod(mdg4) common to all isoforms, to chromatin insulators, as well as the lethal-3 malignant brain tumor protein in Drosophila Kc cells.

Project description:Telomeres in Drosophila are composed of sequential non-LTR retrotransposons: Het-A, TART, TAHRE. Although their expression is highly dynamic, molecular mechanism governing these retrotransposons is poorly understood. Here, we show that specific splice variants of Mod(mdg4) act as repressors of Het-A by blocking subtelomeric enhancers in ovarian somatic cells. We found that a variant, Mod(mdg4)-N, can repress Het-A expression most efficiently among variants. Mod(mdg4)-N mutant flies show elevated Het-A expression and female sterility. Further investigation revealed that Mod(mdg4)-N-binding subtelomeric sequences exhibit enhancer-blocking activity, and recruitment of RNA polymerase II (Pol II) on subtelomeres by Mod(mdg4)-N is essential for this enhancer-blocking. Moreover, Mod(mdg4)-N functions to form chromatin boundaries of higher-order chromatin conformation but this mechanism is independent with its Pol II recruitment activity observed at telomeres/subtelomeres. This study provides an unexpected link between enhancer-blocking and telomere regulation, and two different molecular mechanisms exhibited by an insulator protein to orchestrate precise gene expression.

Project description:The asynchronous timing of replication of different chromosome domains is essential for eukaryotic genome stability, but the mechanisms establishing replication timing programs remain incompletely understood. Drosophila SNF2-related factor SUUR imparts under-replication (UR) of late-replicating intercalary heterochromatin (IH) domains in polytene chromosomes. SUUR negatively regulates DNA replication fork progression across IH; however, its mechanism of action remains obscure. Here we developed a novel method termed MS-Enabled Rapid protein Complex Identification (MERCI) to isolate a stable stoichiometric native complex SUMM4 that comprises SUUR and a chromatin boundary protein Mod(Mdg4)-67.2. In vitro, Mod(Mdg4) stimulates the ATPase activity of SUUR, although neither SUUR nor SUMM4 can remodel nucleosomes. Mod(Mdg4)-67.2 and SUUR distribution patterns in vivo partially overlap, and Mod(Mdg4) is required for a normal spatiotemporal distribution of SUUR in chromosomes. SUUR and Mod(Mdg4)-67.2 mediate insulator activities of the gypsy mobile element that disrupt enhancer-promoter interactions and establish euchromatin-heterochromatin barriers in the genome. Furthermore, mutations of SuUR or mod(mdg4) reverse the locus-specific UR. These findings reveal that DNA replication can be delayed by a chromatin barrier and thus, uncover a critical role for architectural proteins in replication timing control. They also provide a biochemical link between ATP-dependent motor factors and the activity of insulators in regulation of gene expression and chromatin partitioning.

Project description:Fly strains were obtained from the Bloomington Stock Center. The chromosomes containing the gene deletion mod(mdg4)L3101 {y[1] w[1118]; P{w[+mC]=lacW}mod(mdg4)[L3101]/TM3, Ser[1]}, HP1 {In(1)w[m4h]; Su(var)205[5]/In(2L)Cy,In(2R)Cy, Cy[1]}, mod(mdg4)G16853 {w[1118]; P{w[+mC]=EP}mod(mdg4)[G16853]/TM6C, Sb[1]}, and Jil-1Scim {y[1]; P{y[+mDint2] w[BR.E.BR]=SUPor-P}JIL-1[Scim] ry[506]} were introgressed into the genetic background y[1]; bw[1]; e[4]; ci[1] ey[R] to generate the strains Mod(mdg4)/+, Su(var)205/+ and JIL-1/+. All females used in the introgression were collected within 7 hours after eclosion. For gene expression analyses, flies were grown in incubators at 25°C, 65% of relative humidity, and constant light. Newly emerged male adults flies harboring the mutations and the Y chromosomes Yohio and Ycongo(Mod(mdg4)/+;Yohio and Mod(mdg4)/+;Ycongo, Su(var)205/+;Yohio and Su(var)205/+;Ycongo, and JIL-1/+;Yohio and JIL-1/+;Ycongo) were collected and aged for 2 days at the same rearing condition before they were flash-frozen in liquid nitrogen. Four replicas of each sample were collected and stored at -80°C. Total RNA was extracted from whole flies using TRIzol (Life Technologies). The synthesis of cDNA and its labeling with fluorescent dyes (Cy3 and Cy5) as well as hybridization reactions were carried out using 3DNA protocols and reagents (Genisphere). The genetic interaction of the Y chromosome and the mutation was studied by the following contrasts: 1) male flies Mod(mdg4)/+;Yohio versus male flies Mod(mdg4)/+;Ycongo; 2) male flies Su(var)205/+;Yohio versus male flies Su(var)205/+;Ycongo; 3) male flies JIL-1/+;Yohio versus male flies JIL-1/+;Ycongo). As reference we used the same genetic background without the mutations [+/+;Ycongo (background 2) and +/+;Yohio (background 2)]. Slides were scanned using Axon 400B scanner (Axon Instruments) and GenePix Pro 6.0 software. Foreground fluorescence of dye intensities was normalized by the Loess method in Bioconductor / Limma.

Project description:Fly strains were obtained from the Bloomington Stock Center. The chromosomes containing the gene deletion mod(mdg4)L3101 {y[1] w[1118]; P{w[+mC]=lacW}mod(mdg4)[L3101]/TM3, Ser[1]}, HP1 {In(1)w[m4h]; Su(var)205[5]/In(2L)Cy,In(2R)Cy, Cy[1]}, mod(mdg4)G16853 {w[1118]; P{w[+mC]=EP}mod(mdg4)[G16853]/TM6C, Sb[1]}, and Jil-1Scim {y[1]; P{y[+mDint2] w[BR.E.BR]=SUPor-P}JIL-1[Scim] ry[506]} were introgressed into the genetic background y[1]; bw[1]; e[4]; ci[1] ey[R] to generate the strains Mod(mdg4)/+, Su(var)205/+ and JIL-1/+. All females used in the introgression were collected within 7 hours after eclosion. For gene expression analyses, flies were grown in incubators at 25°C, 65% of relative humidity, and constant light. Newly emerged male adults flies harboring the mutations and the Y chromosomes Yohio and Ycongo(Mod(mdg4)/+;Yohio and Mod(mdg4)/+;Ycongo, Su(var)205/+;Yohio and Su(var)205/+;Ycongo, and JIL-1/+;Yohio and JIL-1/+;Ycongo) were collected and aged for 2 days at the same rearing condition before they were flash-frozen in liquid nitrogen. Four replicas of each sample were collected and stored at -80°C. Total RNA was extracted from whole flies using TRIzol (Life Technologies). The synthesis of cDNA and its labeling with fluorescent dyes (Cy3 and Cy5) as well as hybridization reactions were carried out using 3DNA protocols and reagents (Genisphere). The genetic interaction of the Y chromosome and the mutation was studied by the following contrasts: 1) male flies Mod(mdg4)/+;Yohio versus male flies Mod(mdg4)/+;Ycongo; 2) male flies Su(var)205/+;Yohio versus male flies Su(var)205/+;Ycongo; 3) male flies JIL-1/+;Yohio versus male flies JIL-1/+;Ycongo). As reference we used the same genetic background without the mutations [+/+;Ycongo (background 2) and +/+;Yohio (background 2)]. Slides were scanned using Axon 400B scanner (Axon Instruments) and GenePix Pro 6.0 software. Foreground fluorescence of dye intensities was normalized by the Loess method in Bioconductor / Limma. Dye "swaps," loop design.

Project description:How the splicing machinery defines exons or introns as the spliced unit has remained a puzzle for 30 years. Here we demonstrate that peripheral and central regions of the nucleus harbor genes with two distinct exon-intron GC content architectures that differ in the splicing outcome. Genes with low GC content exons, flanked by long introns with lower GC content, are localized in the periphery, and the exons are defined as the spliced unit. Alternative splicing of these genes results in exon skipping. In contrast, the nuclear center contains genes with a high GC content in the exons and short flanking introns. Most splicing of these genes occurs via intron definition, and aberrant splicing leads to intron retention. We demonstrate that the nuclear periphery and center generate different environments for the regulation of alternative splicing, and that two sets of splicing factors form discrete regulatory subnetworks for the two gene architectures. Our study connects 3D genome organization and splicing, thus demonstrating that exon and intron definition modes of splicing occur in different nuclear regions.

Project description:Input control for ChIP-seq on transgenic flies expressing mod(mdg4)-eGFP fusion proteins. For data usage terms and conditions, please refer to http://www.genome.gov/27528022 and http://www.genome.gov/Pages/Research/ENCODE/ENCODE_Data_Use_Policy_for_External_Users_03-07-14.pdf

Project description:Co-transcriptional splicing of introns is a defining feature of eukaryotic gene expression. We show that the mammalian spliceosome specifically associates with the S5P CTD isoform of RNA polymerase II (Pol II) as it elongates across spliced exons of protein coding genes, both in human Hela and murine lymphoid cell lines. Immuno-precipitation of MNase digested chromatin with phospho CTD specific antibodies reveals that components of the active spliceosome (both snRNA and proteins) form a specific complex with S5P CTD Pol II. Furthermore a dominant splicing intermediate formed by cleavage at intron 5’ss results in the tethering of upstream exons to this complex at all spliced exons. These are invariably connected to upstream spliced constitutive and less frequently to alternative exons. Finally S5P CTD Pol II accumulates over spliced exons but not adjacent introns. We propose that mammalian splicing employs a rapid, co-transcriptional splicing mechanism based on CTD phosphorylation transitions.