Project description:We replaced the endogenous histones of Drosophila melanogaster with either histones containing an H3K9R mutation or histones containing an H4K16R mutation to interrogate direct functions for histone residues in salivary gland endoreplication. We performed genomic DNA sequencing in HWT (Histone Wild Type) control, H3K9R, and H4K16R females. We found that H3K9 promotes under-replication of pericentromeric heterochromatin but not along chromosome arms and H4K16 is dispensable for under-replication.

Project description:Drosophila dosage compensation is an epigenetic phenomenon in which the transcription of most genes on X-chromosome is enhanced by approximately two folds in males to equalize that in females. In this study, we provide evidence that transcriptional repressors, such as HP1 and linker histone H1, are globally reduced on male X chromosome. We further investigated the role of HP1 and linker H1 on X chromosome dosage compensation using flies with overexpression of HP1 and H1, we demonstrate that these repressors surpress H4K16 acetylation, presence of the elongating RNA Pol II and the transcription of the genes on male X chromosomes. To understand how H1 and HP1 are regulated on male X chromosome, we next explored the relationship between MOF and the two repressors of chromatin. We show that the hyperacetylation of H4K16 induced by MOF resulted in the loss of H1 and HP1 on chromatin and global chromatin decondensation. Our biochemical analysis further shows that the presence of acetylation on histone H4 at lysine 16 directly inhibits the interaction between histone H4 and linker H1. This study therefore provides novel clues on understanding the dynamic regulation of chromatin regulators on male X chromosome dosage compensation.

Project description:We have performed a comparison of global patterns of gene expression between two bird species, the chicken and zebra finch, especially with regard to sex bias of autosomal vs. Z chromosome genes, dosage compensation and evolution of sex bias. Both species appear to lack a Z chromosome-wide mechanism of dosage compensation, because both have a similar pattern of significantly higher expression of Z genes in males relative to females. Unlike the chicken Z chromosome, which has female-specific expression of the non-coding RNA MHM (male hypermethylated), and acetylation of histone 4 lysine 16 (H4K16) near MHM, the zebra finch Z chromosome appears to lack the MHM sequence and acetylation of H4K16. The zebra finch also does not show the reduced male to female (M:F) ratio of gene expression near MHM similar to that found in the chicken. Although the M:F ratios of Z chromosome gene expression are similar across tissues and ages within each species, they differ between the two species. Z genes showing the greatest species difference in M:F ratio were concentrated near the MHM region of the chicken Z chromosome. The current study shows that the zebra finch differs from the chicken because it lacks a specialized region of greater dosage compensation along the Z chromosome, and shows dosage compensation for a different set of Z genes than the chicken. These patterns suggest that different avian taxa may have evolved specific compensatory mechanisms. Experimental groups: Post-hatch Days 1, 25, 45, and 90+ for both Females and Males (d1_F, d1_M, d25_F, d25_M, d45_F, d45_M, adult_F, adult_M). Biological replicates: 6 per group. One test developmental stage subject and one universal SoNG reference (pooled Taeniopygia guttata brain) per array.

Project description:Duplication of eukaryotic genomes during S phase is coordinated in space and time. In order to identify zones of initiation and cell-type as well as gender-specific plasticity of DNA replication, we profiled replication timing, histone acetylation and transcription throughout the Drosophila genome. We observed two waves of replication initiation with many distinct zones firing in early and multiple, less defined peaks at the end of S phase, suggesting that initiation becomes more promiscuous at the end of S phase. A comparison of different cell types revealed widespread plasticity of replication timing on autosomes. Most occur in large regions but only half coincide with local differences in transcription. In contrast to confined autosomal differences, a global shift in replication timing occurs throughout the single male X chromosome. Unlike in females, the dosage compensated X chromosome replicates almost exclusively early. This difference occurs at sites which are not transcriptionally hyperactivated, but show increased acetylation of lysine 16 of histone H4. This suggests a transcription-independent, yet chromosome-wide process related to chromatin. Importantly, H4K16ac is also enriched at initiation zones as well as early replicating regions on autosomes during S phase. Together, our data reveal novel organizational principles of DNA replication of the Drosophila genome and imply chromatin structure as a determinant of replication timing locally and chromosome-wide. Keywords: cell type comparison, chip-chip, replication timing

Project description:The essential process of dosage compensation is required to equalize gene expression of X-chromosome genes between males (XY) and females (XX). In Drosophila, the conserved Male-specific lethal (MSL) histone acetyltransferase complex mediates dosage compensation by increasing transcript levels from genes on the single male X-chromosome approximately two-fold. Consistent with its increased levels of transcription, the male X-chromosome has enhanced chromatin accessibility, distinguishing it from the autosomes. Here, we demonstrate that the non-sex specific CLAMP (Chromatin-linked adaptor for MSL proteins) zinc finger protein that recognizes GA-rich sequences genome-wide promotes the specialized chromatin environment on the male X-chromosome. In contrast, MSL complex is not required for global male X-chromosome chromatin accessibility, and instead promotes chromatin accessibility just at its highest-occupancy sites. Overall, our results support a model where synergy between the global increases in accessibility promoted by CLAMP and the local effects of MSL complex create a specialized chromatin domain on the male X-chromosome.

Project description:The essential process of dosage compensation is required to equalize gene expression of X-chromosome genes between males (XY) and females (XX). In Drosophila, the conserved Male-specific lethal (MSL) histone acetyltransferase complex mediates dosage compensation by increasing transcript levels from genes on the single male X-chromosome approximately two-fold. Consistent with its increased levels of transcription, the male X-chromosome has enhanced chromatin accessibility, distinguishing it from the autosomes. Here, we demonstrate that the non-sex specific CLAMP (Chromatin-linked adaptor for MSL proteins) zinc finger protein that recognizes GA-rich sequences genome-wide promotes the specialized chromatin environment on the male X-chromosome. In contrast, MSL complex is not required for global male X-chromosome chromatin accessibility, and instead promotes chromatin accessibility just at its highest-occupancy sites. Overall, our results support a model where synergy between the global increases in accessibility promoted by CLAMP and the local effects of MSL complex create a specialized chromatin domain on the male X-chromosome.

Project description:We have performed a comparison of global patterns of gene expression between two bird species, the chicken and zebra finch, especially with regard to sex bias of autosomal vs. Z chromosome genes, dosage compensation and evolution of sex bias. Both species appear to lack a Z chromosome-wide mechanism of dosage compensation, because both have a similar pattern of significantly higher expression of Z genes in males relative to females. Unlike the chicken Z chromosome, which has female-specific expression of the non-coding RNA MHM (male hypermethylated), and acetylation of histone 4 lysine 16 (H4K16) near MHM, the zebra finch Z chromosome appears to lack the MHM sequence and acetylation of H4K16. The zebra finch also does not show the reduced male to female (M:F) ratio of gene expression near MHM similar to that found in the chicken. Although the M:F ratios of Z chromosome gene expression are similar across tissues and ages within each species, they differ between the two species. Z genes showing the greatest species difference in M:F ratio were concentrated near the MHM region of the chicken Z chromosome. The current study shows that the zebra finch differs from the chicken because it lacks a specialized region of greater dosage compensation along the Z chromosome, and shows dosage compensation for a different set of Z genes than the chicken. These patterns suggest that different avian taxa may have evolved specific compensatory mechanisms.

Project description:roX RNAs are involved in the chromosome-wide gene regulation that occurs during dosage compensation in Drosophila. Dosage compensation equalizes expression of X-linked and autosomal genes. Drosophila males increase transcription two-fold from their single X chromosome. This is mediated by the MSL complex, which is composed of the male-specific lethal (MSL) proteins and two noncoding roX RNAs, roX1 and roX2. Upon elimination of both roX transcripts, a global decrease of X-linked gene expression is observed in males. Expression of the genes on the entire 4th chromosome also decreased in the absence of both roX transcripts. roX1 RNA also presents in females in the early stages. To investigate the effect of loss of roX transcripts on gene expression in females, gene expression was analyzed by microarrays in roX1-roX2- female flies. To eliminate inconsistency caused by differences in genetic background, expression of roX1-roX2- females with females of virtually identical genetic background but carrying the [hsp83-roX1+] transgene were compared. Expression of any chromosome did not change in roX1-roX2- females. It was concluded that roX RNAs only effect in males .

Project description:We replaced the endogenous histones of Drosophila melanogaster with histones containing an H3K9R mutation to interrogate the role of H3K9 in heterochromatin formation and function. We queried heterochromatin formation through Formaldhyde Assisted Isolation of Regulatory Elements coupled with sequencing to examine nucleosome occupancy and Heterochromatin Protein 1a ChIP sequencing to determine the localization of the major reader of H3K9me. We found that regions of pericentromeric heterochromatin exhibit decreased HP1a and nucleosome occupancy in H3K9R mutants. To examine potential consequences of these changes of chromatin architecture, we performed total RNA-seq. In H3K9R mutants we observed increased levels of transposon and pIRNA cluster transcripts; however, the protein-coding transcriptome was similar to controls.

Project description:Drosophila males double transcription of their single X chromosome to equalize X-linked gene expression with females, which carry two X chromosomes. Increased transcription requires the Male-Specific Lethal (MSL) complex. The MSL2 protein is essential component of the MSL complex. MSL2 is the only protein that is strictly limited to males. MSL2 together with MSL1 forms the core of the MSL complex. The global effect of msl2 mutation on gene expression was measured by microarray analysis. We found that expression of the X chromosome was decreased in msl21 male larvae, supporting the involvement of MSL2 in the up-regulation of X-linked genes. However, there was no change in expression of 4th chromosomal and heterochromatic genes. This finding is broadly comparable to reports of reduced X chromosome expression following msl2 RNAi knockdown in S2 cells. Hence MSL2 is required for up-regulation of male X chromosome where as it is not necessary for normal expression of 4th chromosomal genes and heterochromatic genes in Drosophila melanogaster males.