Project description:Protein function is controlled by the cellular proteostasis network. Proteostasis is energetically costly and those costs must be balanced with the energy needs of other physiological functions. Hypertonic stress causes widespread protein damage in C. elegans. Suppression and management of protein damage is essential for optimal survival under hypertonic conditions. ASH chemosensory neurons allow C. elegans to detect and avoid strongly hypertonic environments. We demonstrate that gene mutations that disrupt ASH mediated hypertonic avoidance behavior or genetic ablation of ASH neurons enhance survival during hypertonic stress. Enhanced survival is not due to altered systemic volume homeostasis or organic osmolyte accumulation. Instead, loss of ASH neuron function reduces protein damage in non-neuronal cells. Improved proteostasis capacity is due in part to upregulation of genes that play important roles in managing protein damage. We propose that inhibitory signaling from ASH neurons normally suppresses expression of genes required for non-neuronal cell proteostasis. Because all cells have the capacity to sense and respond to stressors, inhibitory neuronal signaling may be important for minimizing activation of cellular stress resistance and proteostasis pathways during short duration and less extreme stressors or stressors that can be avoided by behavioral changes. Neuronal regulation of systemic proteostasis allows the nervous system to monitor environmental variables and more effectively partition finite energy resources between different organismal processes. Our studies add to a growing body of work demonstrating that intercellular communication between neuronal and non-neuronal cells plays a critical role in integrating cellular stress resistance with other organismal physiological demands and associated energy costs. mRNA expression profiling of synchronized L4 stage wild-type N2 Bristol and VC1262 osm-9(ok1677) C. elegans strains under control (51mM NaCl) and hypertonic stress (200mM NaCl).

Project description:Protein function is controlled by the cellular proteostasis network. Proteostasis is energetically costly and those costs must be balanced with the energy needs of other physiological functions. Hypertonic stress causes widespread protein damage in C. elegans. Suppression and management of protein damage is essential for optimal survival under hypertonic conditions. ASH chemosensory neurons allow C. elegans to detect and avoid strongly hypertonic environments. We demonstrate that gene mutations that disrupt ASH mediated hypertonic avoidance behavior or genetic ablation of ASH neurons enhance survival during hypertonic stress. Enhanced survival is not due to altered systemic volume homeostasis or organic osmolyte accumulation. Instead, loss of ASH neuron function reduces protein damage in non-neuronal cells. Improved proteostasis capacity is due in part to upregulation of genes that play important roles in managing protein damage. We propose that inhibitory signaling from ASH neurons normally suppresses expression of genes required for non-neuronal cell proteostasis. Because all cells have the capacity to sense and respond to stressors, inhibitory neuronal signaling may be important for minimizing activation of cellular stress resistance and proteostasis pathways during short duration and less extreme stressors or stressors that can be avoided by behavioral changes. Neuronal regulation of systemic proteostasis allows the nervous system to monitor environmental variables and more effectively partition finite energy resources between different organismal processes. Our studies add to a growing body of work demonstrating that intercellular communication between neuronal and non-neuronal cells plays a critical role in integrating cellular stress resistance with other organismal physiological demands and associated energy costs.

Project description:The plasticity of ageing suggests that longevity may be controlled epigenetically by specific alterations in chromatin state. The link between chromatin and ageing has mostly focused on histone deacetylation by the Sir2 family1, 2, but less is known about the role of other histone modifications in longevity. Histone methylation has a crucial role in development and in maintaining stem cell pluripotency in mammals3. Regulators of histone methylation have been associated with ageing in worms4, 5, 6, 7 and flies8, but characterization of their role and mechanism of action has been limited. Here we identify the ASH-2 trithorax complex9, which trimethylates histone H3 at lysine 4 (H3K4), as a regulator of lifespan in Caenorhabditis elegans in a directed RNA interference (RNAi) screen in fertile worms. Deficiencies in members of the ASH-2 complex—ASH-2 itself, WDR-5 and the H3K4 methyltransferase SET-2—extend worm lifespan. Conversely, the H3K4 demethylase RBR-2 is required for normal lifespan, consistent with the idea that an excess of H3K4 trimethylation—a mark associated with active chromatin—is detrimental for longevity. Lifespan extension induced by ASH-2 complex deficiency requires the presence of an intact adult germline and the continuous production of mature eggs. ASH-2 and RBR-2 act in the germline, at least in part, to regulate lifespan and to control a set of genes involved in lifespan determination. These results indicate that the longevity of the soma is regulated by an H3K4 methyltransferase/demethylase complex acting in the C. elegans germline. There are 23 samples in total. ASH-2 knock-down increases lifespan in a germline dependent manner. We examined ASH-2 regulated genes that are dependent on the presence of an intact germline using WT or glp-1(e2141ts) mutant worms which develop only 5-15 meiotic germ cells treated with either empty vector (EV) or ash-2 RNAi. We examined gene expression at the L3 stage (when we observe changes in H3K4me3) and at a mid life stage (day 8). The majority of ASH-2 controlled genes were regulated in a germline dependent manner. Samples were collected in triplicate for each condition (but Day 8 N2 (WT) E.V. #3 was excluded from all analysis due to quality issues).

Project description:The plasticity of ageing suggests that longevity may be controlled epigenetically by specific alterations in chromatin state. The link between chromatin and ageing has mostly focused on histone deacetylation by the Sir2 family1, 2, but less is known about the role of other histone modifications in longevity. Histone methylation has a crucial role in development and in maintaining stem cell pluripotency in mammals3. Regulators of histone methylation have been associated with ageing in worms4, 5, 6, 7 and flies8, but characterization of their role and mechanism of action has been limited. Here we identify the ASH-2 trithorax complex9, which trimethylates histone H3 at lysine 4 (H3K4), as a regulator of lifespan in Caenorhabditis elegans in a directed RNA interference (RNAi) screen in fertile worms. Deficiencies in members of the ASH-2 complex—ASH-2 itself, WDR-5 and the H3K4 methyltransferase SET-2—extend worm lifespan. Conversely, the H3K4 demethylase RBR-2 is required for normal lifespan, consistent with the idea that an excess of H3K4 trimethylation—a mark associated with active chromatin—is detrimental for longevity. Lifespan extension induced by ASH-2 complex deficiency requires the presence of an intact adult germline and the continuous production of mature eggs. ASH-2 and RBR-2 act in the germline, at least in part, to regulate lifespan and to control a set of genes involved in lifespan determination. These results indicate that the longevity of the soma is regulated by an H3K4 methyltransferase/demethylase complex acting in the C. elegans germline.

Project description:We used four C. elegans strains: N2(wild type), wdr-5(ok1417) III, rbbp-5(tm3463) II, and ash-2(tm1905) II. By sequence the mRNAs from embryos of these worms we try to assess the effect of these mutations in gene regulation of C.elegans.

Project description:Chromatin modifiers regulate lifespan in several organisms, raising the question of whether changes in chromatin states in the parental generation could be incompletely reprogrammed in the next generation and thereby affect the lifespan of descendents. The histone H3 lysine 4 trimethylation (H3K4me3) complex composed of ASH-2, WDR-5, and the histone methyltransferase SET-2 regulates C. elegans lifespan. Here we show that deficiencies in the H3K4me3 chromatin modifiers ASH-2, WDR-5, or SET-2 in the parental generation extend the lifespan of descendents up until the third generation. The transgenerational inheritance of lifespan extension by members of the ASH-2 complex is dependent on the H3K4me3 demethylase RBR-2, and requires the presence of a functioning germline in the descendents. Transgenerational inheritance of lifespan is specific for the H3K4me3 methylation complex and is associated with epigenetic changes in gene expression. Thus, manipulation of specific chromatin modifiers only in parents can induce an epigenetic memory of longevity in descendents.

Project description:Histone H3 Lys 4 methylation (H3K4me) is deposited by the conserved SET1/MLL methyltransferases acting in multiprotein complexes including Ash2 and Wdr5. While individual subunits contribute to complex activity, how they influence gene expression in a specific tissue remains largely unknown. In caenorhabditis elegans, SET-2/SET1, WDR-5.1 and ASH-2 are differentially required for germline H3K4 methylation. Using expression profiling on germlines from animals lacking set-2, ash-2 or wdr-5.1, we show that these subunits play unique and redundant functions to promote expression of germline genes and repress somatic genes. We further show that in set-2 and wdr-5.1 deficient germlines, somatic gene misexpression is associated with conversion of germ cells into somatic cells, and that nuclear RNAi acts in parallel with SET-2 and WDR-5.1 to maintain germline identity. These findings uncover a unique role for SET-2 and WDR-5.1 in preserving germline pluripotency, and underline the complexity of the cellular network regulating this process. Gene misregulation in SET1/set-2, wdr-5.1 and ash-2 defective germlines

Project description:The etiologic agent of bubonic plague, Yersinia pestis, senses cell density-dependent chemical signals to synchronize transcription between cells of the population in a process named quorum sensing. Though the closely related enteric pathogen Y. pseudotuberculosis uses quorum sensing system to regulate motility, the role of quorum sensing in Y. pestis has been unclear. In this study we performed transcriptional profiling experiments to identify Y. pestis quorum sensing regulated functions. Our analysis revealed that acyl-homoserine lactone based quorum sensing controls the expression of several metabolic functions. Maltose fermentation and the glyoxylate bypass are induced by acyl-homoserine lactone signaling. This effect was seen to be temperature conditional. Metabolism is unresponsive to quorum sensing regulation at mammalian body temperature, indicating a potential role for quorum sensing regulation of metabolism specifically during colonization of the flea vector. It is proposed that utilization of alternative carbon sources may enhance growth and/or survival during prolonged flea colonization, contributing to maintenance of plague in nature.

Project description:ASH-1 orthologs are H3K36-specific methyltransferases that are conserved from fungi to humans but are poorly understood, in part because they are typically essential for viability. Here we examine the H3K36 methylation pathway of Neurospora crassa, which we find has just two H3K36 methyltransferases, ASH-1 and RNA polymerase II-associated SET-2. Our investigation of the interplay between SET-2 and ASH-1 uncovered a regulatory mechanism connecting ASH-1-catalyzed H3K36 methylation to repression of poorly transcribed genes. Our findings provide new insight into ASH-1 function, H3K27me2/3 establishment, and repression at facultative heterochromatin.

Project description:Urea cycle disorders with hyperammonemia remain difficult to treat and eventually necessitate liver transplantation. An ornithine transcarbamylase defect (Otcspf-ash) mouse model, a model of urea cycle disorder, was used to test whether knockdown of a key glutamine metabolism enzyme glutaminase 2 (Gls2) or glutamine dehydrogenase 1 (Glud1) could rescue the hyperammonemia and associated lethality induced by a high protein diet. Reduced hepatic expression of Gls2, but not Glud1, by AAV8-mediated delivery of a short hairpin RNA in Otcspf-ash mice diminished hyperammonemia, reduced body weight loss, and reduced lethality. These data suggest that Gls2 hepatic knockdown could help alleviate risk for hyperammonemia and other clinical manifestations of patients suffering from defects in the urea cycle.