Project description:Pseudotaxiphyllum elegans (elegant silkmoss), genomic and transcriptomic data

Project description:Orthotrichum pulchellum (elegant bristlemoss)

Project description:Developmental experiences play critical roles in shaping adult physiology and behavior. We and others previously showed that adult C. elegans which transiently experienced dauer arrest during development (PD: post-dauer) exhibit distinct gene expression profiles as compared to control adults which bypassed the dauer stage. In particular, the expression patterns of subsets of chemoreceptor genes are markedly altered in PD adults. Whether altered chemoreceptor levels drive plasticity in chemosensory behaviors in PD adults is unknown. Via transcriptional profiling of sorted populations of AWA neurons from control and PD adults, we further show that the expression of a subset of chemoreceptor genes in AWA are differentially regulated in PD animals. Our results suggest that developmental experiences may be encoded at the level of olfactory receptor regulation, and provide an elegant mechanism by which C. elegans is able to precisely modulate its behavioral preferences as a function of its current and past experiences.

Project description:Orthotrichum pulchellum (elegant bristlemoss), genomic and transcriptomic data

Project description:characterize the molecular signature of PB-IMC in different stages of tumor development, thus possibly leading to a novel, sensitive and elegant approach for early cancer detection and surveillance.

Project description:High connectivity among breeding populations of the Elegant Tern (Thalasseus elegans) in Mexico and southern California revealed through population genomic analysis

Project description:Most human transcription factors bind a small subset of potential genomic sites and often use different subsets in different cell types. To identify mechanisms that govern cell type-specific transcription factor binding, we used an integrative approach to study estrogen receptor α (ER). We found that ER exhibits two distinct modes of binding. Shared sites, bound in multiple cell types, are characterized by high affinity estrogen response elements (EREs), inaccessible chromatin and a lack of DNA methylation, while cell-specific sites are characterized by a lack of EREs, co-occurrence with other transcription factors and cell type-specific chromatin accessibility and DNA methylation. These observations enabled accurate quantitative models of ER binding that suggest tethering of ER to one-third of cell-specific sites. The distinct properties of cell-specific binding were also observed with glucocorticoid receptor and for ER in primary mouse tissues, representing an elegant genomic encoding scheme for generating cell type-specific gene regulation. ChIP-seq of transcription factors in mouse tissues

Project description:The goal of this study is to identify and characterize sites in the C. elegans genome bound by the transcription factor TRA-1. TRA-1 ChIP-seq was performed in the following stages of animals in duplicate: 1) L2 stage of C. elegans wild-type N2 strain; 2) L3 stage of C. elegans wild-type N2 strain; 3) young adult stage of C. elegans glp-4(bn2) mutant; 4) young adult stage of C. elegans spe-11(hc77) mutant; 5) L3 stage of C. briggsae wild-type AF16 strain. As a negative control, TRA-1 ChIP-seq was also performed in C. elegans L3 stage with tra-1(e1834) homozygous and heterozygous mutation. Input DNA was also sequenced in each condition.

Project description:Yilmaz2016 - Genome scale metabolic model - Caenorhabditis elegans (iCEL1273) This model is described in the article: A Caenorhabditis elegans Genome-Scale Metabolic Network Model. Yilmaz LS, Walhout AJ. Cell Syst 2016 May; 2(5): 297-311 Abstract: Caenorhabditis elegans is a powerful model to study metabolism and how it relates to nutrition, gene expression, and life history traits. However, while numerous experimental techniques that enable perturbation of its diet and gene function are available, a high-quality metabolic network model has been lacking. Here, we reconstruct an initial version of the C. elegans metabolic network. This network model contains 1,273 genes, 623 enzymes, and 1,985 metabolic reactions and is referred to as iCEL1273. Using flux balance analysis, we show that iCEL1273 is capable of representing the conversion of bacterial biomass into C. elegans biomass during growth and enables the predictions of gene essentiality and other phenotypes. In addition, we demonstrate that gene expression data can be integrated with the model by comparing metabolic rewiring in dauer animals versus growing larvae. iCEL1273 is available at a dedicated website (wormflux.umassmed.edu) and will enable the unraveling of the mechanisms by which different macro- and micronutrients contribute to the animal's physiology. This model is hosted on BioModels Database and identified by: MODEL1604210000. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:We have characterized two post-translational histone modifications in C. elegans on a genomic scale. Micrococcal nuclease digestion and immunoprecipitation were used to obtain distinct populations of single nucleosome cores, which were analyzed using massively parallel DNA sequencing to obtain positional and coverage maps. Two methylated histone H3 populations were chosen for comparison: H3K4 histone methylation (associated with active chromosomal regions) and H3K9 histone methylation (associated with inactivity). From analysis of the sequence data, we found nucleosome cores with these modifications to be enriched in two distinct partitions of the genome; H3K4 methylation was particularly prevalent in promoter regions of widely-expressed genes while H3K9 methylation was enriched on specific chromosomal arms. For each of the six chromosomes, the highest level of H3K9 methylation corresponds to the pairing center responsible for chromosome alignment during meiosis. H3K9 enrichment at pairing centers appears to be an early mark in meiotic chromosome sorting, occurring in the absence of components required for proper pairing of homologous chromosomes. H3K9 methylation shows an intricate pattern within the chromosome arms, with a particular anti-correlation to regions that display a strong ~10 bp periodicity of AA/TT dinucleotides that is known to associate with germline trancription. By contrast to the global features observed with H3K9 methylation, H3K4 methylation profiles were most striking in their local characteristics around promoters, providing a unique promoter-central landmark for 3903 C. elegans genes and allowing a precise analysis of nucleosome positioning in the context of transcriptional initiation. Keywords: epigenetics Examination of total nucleosome and nucleosomes with 2 different histone modifications in C. elegans. 5 samples are analyzed: 1. total mononucleosome core DNA from C. elegans wild type strain N2, 2. anti-H3K4me2/3 precipitated mononucleosome core DNA from C. elegans wild type strain N2, 3. anti-H3K9me3 precipitated mononucleosome core DNA from C. elegans wild type strain N2, 4. total mononucleosome core DNA from C. elegans mutant strain zim-2(tm-574), 5. anti-H3K9me3 precipitated mononucleosome core DNA from C. elegans mutant strain zim-2(tm-574)