Our results support a model in which MSL proteins assemble at specific chromatin entry sites (including the roX1 and roX2 genes); the roX RNAs join the complex at their sites of synthesis; and complete complexes spread in cis to dosage compensate most genes on the X chromosome.
Vascular endothelial growth factor A (VEGFA) and the type III receptor tyrosine kinase receptors (RTKs) are both required for the differentiation of endothelial cells (vasculogenesis) and for the sprouting of new capillaries (angiogenesis). We have isolated a duplicated zebrafish VegfA locus, termed VegfAb, and a duplicate RTK locus with homology to KDR/FLK1 (named Kdrb). Morpholinodisrupted VegfAb embryos develop a normal circulatory system until approximately 2 to 3 days after fertilization (dpf), when defects in angiogenesis permit blood to extravasate into many tissues. Unlike the VegfAa 121 and VegfAa 165 isoforms, the VegfAb isoforms VegfAb 171 IntroductionDifferentiation of endothelial cells to form the vascular network of arteries and veins requires a critical mitogenic signal, vascular endothelial growth factor A (VEGFA), which is transduced to the nucleus through a number of functionally redundant receptors. These receptors include the type III receptor tyrosine kinases VEGFR1/FLT1, VEGFR2/FLK1 (human KDR), and type I nonkinase transmembrane receptors neuropilin 1 (NRP1) and NRP2, 1 which are critical mediators of both vasculogenesis (de novo formation of blood vessels) and angiogenesis (sprouting of vessels from preexisting vessels). 2 Mice hemizygous at their single VegfA locus show defective vasculogenesis and die between 11 and 12 days after conception (dpc). [3][4][5] Embryos homozygous for a targeted disruption of Flk1 (Vegfr2) die between 8.5 and 9.5 dpc from defects in both hematopoiesis and vasculogenesis, but disruption of Flt1 (Vegfr1) only leads to perturbed vascular patterning in full-term embryos. 6,7 The tight regulation of VEGFA levels and the requirement for its receptors in hematopoiesis and vasculogenesis point to its critical role in the formation of blood vessels during development.Differential splicing of the single VEGFA locus in humans gives rise to multiple protein isoforms, ranging in size from 121 to 206 amino acids (aa's) (VEGFA 121 , VEGFA 145 , VEGFA 165 , VEGFA 189 , and VEGF 206 ). 8,9 The VEGF isoforms differ mainly by the presence or absence of 2 heparin-binding domains encoded within exon 6 and 7 sequences. [10][11][12] Expression of a single VEGFA isoform rescues VegfA mutant mice through birth, although the vascular networks differ with expression of different isoforms. [13][14][15][16] VEGFA splicing is regulated during development and in disease, resulting in tissue-and stage-specific isoform ratios, which allow for distinct, context-dependent VEGFA signaling. 17 Zebrafish have proven useful for dissecting vascular developmental pathways. 18 A single zebrafish vegfA gene has been previously described, encoding the 121-and 165-aa isoforms. 19,20 Although VegfA 121 is the predominant isoform in early embryos and VegfA 165 in adults, other alternate transcripts exist in specific tissues. 21 The initial establishment of axial vasculature patterning does not require VegfA, but the sprouting of intersegmental vessels does. 22 Together, these results show that VegfA...
In Drosophila, dosage compensation is controlled by the male-specific lethal (MSL) complex consisting of MSL proteins and roX RNAs. The MSL complex is specifically localized on the male X chromosome to increase its expression approximately 2-fold. We recently proposed a model for the targeted assembly of the MSL complex, in which initial binding occurs at approximately 35 dispersed chromatin entry sites, followed by spreading in cis into flanking regions. Here, we analyze one of the chromatin entry sites, the roX1 gene, to determine which sequences are sufficient to recruit the MSL complex. We found association and spreading of the MSL complex from roX1 transgenes in the absence of detectable roX1 RNA synthesis from the transgene. We mapped the recruitment activity to a 217 bp roX1 fragment that shows male-specific DNase hypersensitivity and can be preferentially cross-linked in vivo to the MSL complex. When inserted on autosomes, this small roX1 segment is sufficient to produce an ectopic chromatin entry site that can nucleate binding and spreading of the MSL complex hundreds of kilobases into neighboring regions.
Hepatic steatosis is the initial stage of non-alcoholic fatty liver disease (NAFLD) and may predispose to more severe hepatic disease, including hepatocellular carcinoma. Endoplasmic reticulum (ER) stress has been recently implicated as a novel mechanism that may lead to NAFLD, although the genetic factors invoking ER stress are largely unknown. During a screen for liver defects from a zebrafish insertional mutant library, we isolated the mutant cdipthi559Tg/+ (hi559). CDIPT is known to play an indispensable role in phosphatidylinositol (PtdIns) synthesis. Here we show that cdipt is expressed in the developing liver and its disruption in hi559 mutants abrogates de novo PtdIns synthesis, resulting in hepatomegaly at 5-dpf. The hi559 hepatocytes display features of NAFLD, including macrovesicular steatosis, ballooning, and necroapoptosis. Gene set enrichment of microarray profiling revealed significant enrichment of ER stress response (ERSR) genes in hi559 mutants. ER stress markers, including atf6, hspa5, calr, xbp1, are selectively upregulated in the mutant liver. The hi559 expression profile showed significant overlap with that of mammalian hepatic ER stress and NAFLD. Ultrastructurally, the hi559 hepatocytes display marked disruption of ER architecture with hallmarks of chronic unresolved ER stress. Induction of ER stress by tunicamycin in wild-type larvae results in a fatty liver similar to hi559, suggesting that ER stress could be a fundamental mechanism contributing to hepatic steatosis. Conclusion: Cdipt-deficient zebrafish exhibit hepatic ER stress and NAFLD pathologies, implicating a novel link between PtdIns, ER stress, and steatosis. The tractability of hi559 mutant provides a valuable tool to dissect ERSR components, their contribution to molecular pathogenesis and evaluation of novel therapeutics of NAFLD.
The nuclear receptor DAF-12 has roles in normal development, the decision to pursue dauer development in unfavorable conditions, and the modulation of adult aging. Despite the biologic importance of DAF-12, target genes for this receptor are largely unknown. To identify DAF-12 targets, we performed chromatin immunoprecipitation followed by hybridization to whole-genome tiling arrays. We identified 1,175 genomic regions to be bound in vivo by DAF-12, and these regions are enriched in known DAF-12 binding motifs and act as DAF-12 response elements in transfected cells and in transgenic worms. The DAF-12 target genes near these binding sites include an extensive network of interconnected heterochronic and microRNA genes. We also identify the genes encoding components of the miRISC, which is required for the control of target genes by microRNA, as a target of DAF-12 regulation. During reproductive development, many of these target genes are misregulated in daf-12(0) mutants, but this only infrequently results in developmental phenotypes. In contrast, we and others have found that null daf-12 mutations enhance the phenotypes of many miRISC and heterochronic target genes. We also find that environmental fluctuations significantly strengthen the weak heterochronic phenotypes of null daf-12 alleles. During diapause, DAF-12 represses the expression of many heterochronic and miRISC target genes, and prior work has demonstrated that dauer formation can suppress the heterochronic phenotypes of many of these target genes in post-dauer development. Together these data are consistent with daf-12 acting to ensure developmental robustness by committing the animal to adult or dauer developmental programs despite variable internal or external conditions.
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