Project description:Acute knockout of the rod photoreceptor transcription factor Nrl delays retinal degeneration in multiple mouse models of blindness1-3, but the downstream transcriptomic changes that mediate these therapeutic effects are unknown. Here, we show that acute Nrl knockout causes upregulation of a subset of cone genes in rods as well as downregulation of rod genes, including the rod-specific transcriptional repressor Nr2e3. We hypothesized that Nr2e3 downregulation might mediate some of the therapeutic effects of Nrl knockout. Indeed, acute knockout of Nr2e3 prevents photoreceptor degeneration and preserves visual function in mice with mutations in the catalytic subunit of the rod-specific phosphodiesterase (Pde6brd10/rd10). Upregulation of Pde6c, the cone-specific homolog of Pde6b, in Nr2e3-knockout rods is required to prevent degeneration in Pde6brd10/rd10 mice, suggesting that this therapeutic effect is mediated by a gene-replacement mechanism. In contrast, acute Nr2e3 knockout fails to prevent degeneration caused by loss- or gain-of-function mutations in Rhodopsin (Rho-/- and RhoP23H/P23H), whereas acute Nrl knockout delays degeneration in both models. These results suggest that acute Nrl knockout may rescue Pde6brd10/rd10 mice via downregulation of Nr2e3 and consequent upregulation of Pde6c, while rescuing Rho mutants via a distinct mechanism, possibly by downregulating rod genes. These findings indicate that acute NRL knockout may be a promising gene-independent strategy for preventing photoreceptor degeneration in human patients.

Project description:In inherited retinal disorders such as retinitis pigmentosa (RP), rod photoreceptor-specific mutations cause primary rod degeneration that is followed by secondary cone death and loss of high-acuity vision. Mechanistic studies of retinal degeneration are challenging because of retinal heterogeneity. Moreover, the detection of early cone responses to rod death is especially difficult due to the paucity of cones in the retina. To resolve heterogeneity in the degenerating retina and investigate events in both types of photoreceptors during primary rod degeneration, we utilized droplet-based single-cell RNA sequencing in an RP mouse model, rd10.

Project description:The rd10 mouse is a model of retinitis pigmentosa characterized by the dysfunction of a rod-photoreceptor-specific phosphodiesterase. Compared to the rd1 mouse, retinal degeneration in the rd10 mouse begins later in age with a milder phenotype, making it ideal for investigating cell death and neuroprotective mechanisms. Alterations in the rd10 retina proteome at pre-, peak-, and post-degenerative time points were examined using a modified high-recovery filter-aided sample preparation (FASP) method and label-free mass spectrometry, generating a unique proteomic dataset on almost 3000 proteins. Our data confirmed a period of protein expression similar to age-matched wild-type mice pre-degeneration, with decreases in proteins associated with phototransduction and increases in signaling proteins at peak- and post-degenerative stages. 123 proteins were differentially expressed the rd10 retinae during peak-degeneration compared to wild-type mice. Network analysis separated these proteins into a cluster of downregulated photoreceptor proteins, and one of upregulated signaling proteins centered around GFAP, STAT3, and STAT1. This is the first study to identify alterations in STAT1 in the rd10 mouse, which were confirmed with gene expression and immunoblotting experiments. This finding proves the efficacy of our approach, and that this dataset could serve as an information source for protein alterations in retinal degeneration.

Project description:To explore the mechanism associated with retinal degeneration and adeno-associated virus (AAV)-mediated gene therapy in rd10 mouse, a model of autosomal recessive retinitis pigmentosa (arRP) containing mutation of β subunit of the rod cGMP phosphodiesterase 6 (PDE6).

Project description:G9a (EHMT2) and the G9a-like protein GLP (EHMT1) form a stable G9a/GLP heterodimer in embryonic stem cells and function cooperatively to establish and maintain the abundant repressive H3K9me2 modification, in addition to modifying several non-histone proteins. The G9a-dependent H3K9me2 is implicated in lineage-specific gene silencing and covers large chromosomal domains. While the mechanism of H3K9me2maintenance by G9a/GLP is known, how new patterns of this modification are established is not well understood. With this in mind, we used FLAG affinity purification of G9a under two different stringency conditions (150 and 300 mM NaCl) coupled with mass spectrometry to identify proteins stably associated with G9a/GLP, which could serve as potential recruiters of the complex to unmodified chromatin.

Project description:GLP (EHMT1) functions as an H3K9me1 and H3K9me2 methyltransferase through its reportedly obligatory dimerization with G9A (EHMT2). Here, we investigated the role of GLP in oocyte and embryo development in comparison to G9A using oocyte-specific conditional knockout mouse models (G9a cKO, Glp cKO, G9a-Glp cDKO). Loss of GLP in oogenesis severely impairs oocyte maturation, fertilization and embryo development, resulting in lethality before embryonic day E12.5. In contrast, loss of G9A has a milder effect with a proportion of embryos producing viable offspring. The Glp cKO also showed loss of G9A protein and, hence, was phenotypically very similar to the G9a-Glp cDKO. H3K9me2 was equally depleted in all cKO genotypes, whereas H3K9me1 was decreased only in Glp cKO and G9a-Glp cDKO oocytes. Furthermore, the transcriptome, DNA methylome and proteome were markedly more affected in G9a-Glp cDKO than G9a cKO oocytes, demonstrating that in the absence of GLP there are widespread epigenetic and gene expression changes in the oocyte independent of H3K9me2. Gene dysregulation with coupled changes in DNA methylation suggest localised loss of chromatin repression, resulting in upregulated protein expression. Together, our findings demonstrate that GLP can function independently of G9A in the oocyte and is required for oocyte developmental competence.

Project description:G9a and GLP lysine methyltransferases form a heterodimeric complex that is responsible for the bulk of cellular mono- and di-methylation on histone H3 lysine 9 (H3K9me1/me2). Widely Interspaced Zinc finger (WIZ) associates with the G9a/GLP protein complex, but its role in lysine methylation is poorly defined. Here, we show that WIZ regulates global H3K9me2 levels through a mechanism that involves retention of G9a on chromatin. We also show that WIZ-mediated chromatin loss of G9a/GLP results in altered gene expression and protein-protein interactions that are distinguishable from that of using a molecule-induced enzymatic inhibitor towards G9a/GLP – thus providing evidence that the G9a/GLP/WIZ complex has unique functions when bound to chromatin that are independent of the H3K9me2 mark DMSO, UNC0638, NS, and siWIZ treatments to HEK293T cells, assessing G9a and H3K9me2 localization, each performed in duplicate, plus one input control for each cell condition. 30 samples total.

Project description:Lysine methyltransferases G9a and GLP (G9a- Like Protein) form functional heterodimeric complexes that establish mono- and dimethylation on histone H3 lysine 9 (H3K9me1, H3K9me2) in euchromatin. Here we describe unexpected opposite individual roles for G9a and GLP during skeletal muscle terminal differentiation. Indeed, gain- or loss-of-function assays in myoblasts showed that in consistency with previous reports that G9a inhibits terminal differentiation. But GLP plays a more complicated role in muscle differentiation since both knockdown and overexpression inhibits terminal differentiation. Unexpectedly, in contrast to G9a, we show that GLP overexpression promotes abnormal expression of muscle differentiationspecific genes in proliferating myoblasts. Transcriptomic analysis indicates that G9a and GLP regulate different sets of genes. GLP, but not G9a, inhibits at the transcriptional level proteasome subunit-encoding genes resulting in an inhibition of the proteasome activities. Subsequently, GLP, but not G9a, overexpression stabilizes MyoD that is likely to be responsible for muscle markers expression in proliferating myoblasts.

Project description:G9a/GLP and Polycomb Repressive Complex 2 (PRC2) are two major epigenetic silencing machineries, which in particular methylate histone H3 on lysines 9 and 27 (H3K9 and H3K27), respectively. Although evidence of a crosstalk between H3K9 and H3K27 methylations has started to emerge, their actual interplay remains elusive. Here, we show that PRC2 and G9a/GLP interact physically and functionally. Moreover, combining different genome-wide approaches, we demonstrate that Ezh2 and G9a/GLP share an important number of common genomic targets, encoding developmental and neuronal regulators. Furthermore, we show that G9a enzymatic activity modulates PRC2 genomic recruitment to a subset of its target genes. Taken together, our findings demonstrate an unanticipated interplay between two main histone lysine methylation mechanisms, which cooperate to maintain silencing of a subset of developmental genes. Microarray has been perform in triplicate on total extract RNA from mES cell (TT2 : Wildtype and KOs G9a-/-, GLP-/-, G9a-/- and GLP-/-)

Project description:G9a/GLP and Polycomb Repressive Complex 2 (PRC2) are two major epigenetic silencing machineries, which in particular methylate histone H3 on lysines 9 and 27 (H3K9 and H3K27), respectively. Although evidence of a crosstalk between H3K9 and H3K27 methylations has started to emerge, their actual interplay remains elusive. Here, we show that PRC2 and G9a/GLP interact physically and functionally. Moreover, combining different genome-wide approaches, we demonstrate that Ezh2 and G9a/GLP share an important number of common genomic targets, encoding developmental and neuronal regulators. Furthermore, we show that G9a enzymatic activity modulates PRC2 genomic recruitment to a subset of its target genes. Taken together, our findings demonstrate an unanticipated interplay between two main histone lysine methylation mechanisms, which cooperate to maintain silencing of a subset of developmental genes. ChIP-seq has been performed for G9a and Ezh2 in wild type TT2 mES cells or in mES cells lacking both G9a and GLP (G9a-/-GLP-/-). As a control, input DNA was saved before immunoprecipitation. Note that the two inputs (Input_TT2_0 and Input_TT2_1) have been combined and used as control for Ezh2 and G9a ChIP-seq.