Project description:The transcriptional programs of ectothermic teleosts are directly influenced by water temperature. Although various cold-responsive transcriptional patterns have been determined in fishes, the systematic molecular networks governing the temperature responses are still unknown. We profiled the transcriptional responses in eight tissues of zebrafish exposed to graded cold temperatures, ranging from normal (28°C) to mild (18°C) and severe (10°C) cold, using RNA-seq. The tissues varied in the number of cold-responsive genes, of which the kidney appeared to be most sensitive, whereas the brain was the least. Fuzzy k-means clustering revealed 34 gene clusters of distinct expression patterns, demonstrating diverse tissue-specific responses in conjunction with multiple aspects of ubiquitous cross-tissue responses to cold. Thirty-one GO terms were over-represented upon cold treatment. These terms are involved in basic cellular processes, such as RNA splicing and proton transport, as well tissue-specific processes, such as ‘negative regulation of endopeptidase activity’ in the kidney. To identify the cis-regulatory elements governing the concerted cold responses, the promoters of the genes that demonstrated strong co-regulation were analyzed using an enriched motif discovery program, DREME. Eleven motifs, 6 known and 5 novel, were identified. These motifs belong to the genes corresponding to the 16 over-represented GO terms identified above. Some motifs, such as the AP-1 and STAT1 binding sites, are known to be stress responsive. By integrating comprehensive cold-induced transcriptional changes with a cis-motif identification tool, we identified genome-wide regulatory networks for the cold response in zebrafish. The identified networks provided new insights into molecular mechanisms of thermal responses in teleosts. Examination of gene expression of 24 samples (eight tissues at three temperatures)

Project description:The transcriptional programs of ectothermic teleosts are directly influenced by water temperature. Although various cold-responsive transcriptional patterns have been determined in fishes, the systematic molecular networks governing the temperature responses are still unknown. We profiled the transcriptional responses in eight tissues of zebrafish exposed to graded cold temperatures, ranging from normal (28°C) to mild (18°C) and severe (10°C) cold, using RNA-seq. The tissues varied in the number of cold-responsive genes, of which the kidney appeared to be most sensitive, whereas the brain was the least. Fuzzy k-means clustering revealed 34 gene clusters of distinct expression patterns, demonstrating diverse tissue-specific responses in conjunction with multiple aspects of ubiquitous cross-tissue responses to cold. Thirty-one GO terms were over-represented upon cold treatment. These terms are involved in basic cellular processes, such as RNA splicing and proton transport, as well tissue-specific processes, such as ‘negative regulation of endopeptidase activity’ in the kidney. To identify the cis-regulatory elements governing the concerted cold responses, the promoters of the genes that demonstrated strong co-regulation were analyzed using an enriched motif discovery program, DREME. Eleven motifs, 6 known and 5 novel, were identified. These motifs belong to the genes corresponding to the 16 over-represented GO terms identified above. Some motifs, such as the AP-1 and STAT1 binding sites, are known to be stress responsive. By integrating comprehensive cold-induced transcriptional changes with a cis-motif identification tool, we identified genome-wide regulatory networks for the cold response in zebrafish. The identified networks provided new insights into molecular mechanisms of thermal responses in teleosts.

Project description:Tissue-specific or cell-type-specific transcription of protein-coding genes is controlled by both trans-regulatory elements (TREs) and cis-regulatory elements (CREs). However, it is challenging to identify TREs and CREs, which are unknown for most genes. Here, we describe a protocol for identifying two types of transcription-activating CREs-core promoters and enhancers-of zebrafish photoreceptor type-specific genes. This protocol is composed of three phases: bioinformatic prediction, experimental validation, and characterization of the CREs. To better illustrate the principles and logic of this protocol, we exemplify it with the discovery of the core promoter and enhancer of the mpp5b apical polarity gene (also known as ponli), whose red, green, and blue (RGB) cone-specific transcription requires its enhancer, a member of the rainbow enhancer family. While exemplified with an RGB-cone-specific gene, this protocol is general and can be used to identify the core promoters and enhancers of other protein-coding genes.

Project description:Accurate and efficient splicing of eukaryotic pre-mRNAs requires recognition by trans-acting factors of a complex array of cis-acting RNA elements. Here, we developed a generalized Bayesian network to model the coevolution of splicing cis elements in diverse eukaryotic taxa. Cross-exon but not cross-intron compensatory interactions between the 5' splice site (5'ss) and 3' splice site (3'ss) were observed in human/mouse, indicating that the exon is the primary evolutionary unit in mammals. Studied plants, fungi, and invertebrates exhibited exclusively cross-intron interactions, suggesting that intron definition drives evolution in these organisms. In mammals, 5'ss strength and the strength of several classes of exonic splicing silencers (ESSs) evolved in a correlated way, whereas specific exonic splicing enhancers (ESEs), including motifs associated with hTra2, SRp55, and SRp20, evolved in a compensatory manner relative to the 5'ss and 3'ss. Interactions between specific ESS or ESE motifs were not observed, suggesting that elements bound by different factors are not commonly interchangeable. Thus, the splicing elements defining exons coevolve in a way that preserves overall exon strength, allowing specific elements to substitute for loss or weakening of others.

Project description:The zebrafish (Danio rerio) has been widely used in the study of human disease and development, and about 70% of the protein-coding genes are conserved between the two species1. However, studies in zebrafish remain constrained by the sparse annotation of functional control elements in the zebrafish genome. Here we performed RNA sequencing, assay for transposase-accessible chromatin using sequencing (ATAC-seq), chromatin immunoprecipitation with sequencing, whole-genome bisulfite sequencing, and chromosome conformation capture (Hi-C) experiments in up to eleven adult and two embryonic tissues to generate a comprehensive map of transcriptomes, cis-regulatory elements, heterochromatin, methylomes and 3D genome organization in the zebrafish Tübingen reference strain. A comparison of zebrafish, human and mouse regulatory elements enabled the identification of both evolutionarily conserved and species-specific regulatory sequences and networks. We observed enrichment of evolutionary breakpoints at topologically associating domain boundaries, which were correlated with strong histone H3 lysine 4 trimethylation (H3K4me3) and CCCTC-binding factor (CTCF) signals. We performed single-cell ATAC-seq in zebrafish brain, which delineated 25 different clusters of cell types. By combining long-read DNA sequencing and Hi-C, we assembled the sex-determining chromosome 4 de novo. Overall, our work provides an additional epigenomic anchor for the functional annotation of vertebrate genomes and the study of evolutionarily conserved elements of 3D genome organization.

Project description:Zebrafish, a popular organism for studying embryonic development and for modeling human diseases, has so far lacked a systematic functional annotation program akin to those in other animal models. To address this, we formed the international DANIO-CODE consortium and created a central repository to store and process zebrafish developmental functional genomic data. Our data coordination center ( https://danio-code.zfin.org ) combines a total of 1,802 sets of unpublished and re-analyzed published genomic data, which we used to improve existing annotations and show its utility in experimental design. We identified over 140,000 cis-regulatory elements throughout development, including classes with distinct features dependent on their activity in time and space. We delineated the distinct distance topology and chromatin features between regulatory elements active during zygotic genome activation and those active during organogenesis. Finally, we matched regulatory elements and epigenomic landscapes between zebrafish and mouse and predicted functional relationships between them beyond sequence similarity, thus extending the utility of zebrafish developmental genomics to mammals.

Project description:In this study, we have applied ChIP-Seq to identify putative regulatory elements throughout the zebrafish genome. For this purpose we identified sequences within the zebrafish genome that associate with H3K4me1 and H3K4me3, which are epigenetic modifications known to be associated with active cis-regulatory elements in other species. Determination of H3K4me1- and H3K4me3-binding sites in the zebrafish genome.

Project description:The liver plays a key role in metabolism and affects pig production. However, the functional annotation of noncoding regions of the pig liver remains poorly understood. We revealed the landscape of cis-regulatory elements and their functional characterization in pig liver. We identified 102,373 cis-regulatory elements in the pig liver, including enhancers, promoters, super-enhancers, and broad H3K4me3 domains, and highlighted 26 core transcription regulatory factors in the pig liver as well. We found similarity of cis-regulatory elements among those of pigs, humans, and cattle. Despite the low proportion of functionally conserved enhancers (~30%) between pig and human liver tissue, ~78% of the pig liver enhancer orthologues sequence could play an enhancer role in other human tissues. Additionally, we observed that the ratio of consistent super-enhancer-associated genes was significantly higher than the ratio of functionally conserved super-enhancers. Approximately 54% of the core regulation factors driven by super-enhancers were consistent across the liver from these three species. Our pig liver annotation and functional characterization studies provide a system and resource for noncoding annotation for future gene regulatory studies in pigs. Furthermore, our study also showed the high level functional conservation of cis-regulatory elements in mammals; it also improved our understanding of regulation function of mammal cis-regulatory elements.

Project description:The majority of human genes undergo alternative splicing to generate multiple isoforms with distinct functions. This process is generally controlled by cis-acting splicing regulatory elements (SREs) that recruit trans-acting factors to promote or inhibit the use of nearby splice sites. The growing interest in understanding the regulatory rules of splicing necessitates the systematic identification of these SREs and their cognate protein factors using experimental and computational approaches. Here we describe a strategy to identify and analyze both cis-acting SREs and trans-acting splicing factors. This strategy involves a cell-based screen to identify SREs from a random sequences library and a modified RNA affinity purification approach to unbiasedly identify the splicing factors. These methods can be adopted to identify splicing enhancers or silencers in both exons and introns, and can be extended to different cultured cells. The resulting SREs and splicing factors can be further analyzed with a series of computational and experimental approaches. This approach will help us to collect a molecular part-list for splicing regulation, providing a rich data source that enables a better understanding of the "splicing code".

Project description:Expression patterns of genes are controlled by short regions of DNA in promoter regions known as cis-regulatory elements. How expression patterns change due to alterations in cis-regulatory elements in the context of gene duplication are not well studied in plants. Over 300 promoter sequences from a small, well-conserved family of plant transcription factors known as Cytokinin Response Factors (CRFs) were examined for conserved motifs across several known clades present in Angiosperms. General CRF and lineage specific motifs were identified. Once identified, significantly enriched motifs were then compared to known transcription factor binding sites to elucidate potential functional roles. Additionally, presence of similar motifs shows that levels of conservation exist between different CRFs across land plants, likely occurring through processes of neo- or sub-functionalization. Furthermore, significant patterns of motif conservation are seen within and between CRF clades suggesting cis-regulatory regions have been conserved throughout CRF evolution.