Chromatin immunoprecipitation coupled with high-throughput sequencing (ChIP-seq) has become the dominant technique for mapping transcription factor (TF) binding regions genome-wide. We performed an integrative analysis centered around 457 ChIP-seq data sets on 119 human TFs generated by the ENCODE Consortium. We identified highly enriched sequence motifs in most data sets, revealing new motifs and validating known ones. The motif sites (TF binding sites) are highly conserved evolutionarily and show distinct footprints upon DNase I digestion. We frequently detected secondary motifs in addition to the canonical motifs of the TFs, indicating tethered binding and cobinding between multiple TFs. We observed significant position and orientation preferences between many cobinding TFs. Genes specifically expressed in a cell line are often associated with a greater occurrence of nearby TF binding in that cell line. We observed cell-linespecific secondary motifs that mediate the binding of the histone deacetylase HDAC2 and the enhancer-binding protein EP300. TF binding sites are located in GC-rich, nucleosome-depleted, and DNase I sensitive regions, flanked by wellpositioned nucleosomes, and many of these features show cell type specificity. The GC-richness may be beneficial for regulating TF binding because, when unoccupied by a TF, these regions are occupied by nucleosomes in vivo. We present the results of our analysis in a TF-centric web repository Factorbook (http://factorbook.org) and will continually update this repository as more ENCODE data are generated.
Purple-leaf tea is a phenotype with unique color because of its high anthocyanin content. The special flavor of purple-leaf tea is highly different from that of green-leaf tea, and its main ingredient is also of economic value. To probe the genetic mechanism of the phenotypic characteristics of tea leaf color, we conducted widely targeted metabolic and transcriptomic profiling. The metabolites in the flavonoid biosynthetic pathway of purple- and green-leaf tea were compared, and results showed that phenolic compounds, including phenolic acids, flavonoids, and tannins, accumulated in purple-leaf tea. The high expression of genes related to flavonoid biosynthesis (e.g., PAL and LAR) exhibits the specific expression of biosynthesis and the accumulation of these metabolites. Our result also shows that two CsUFGTs were positively related to the accumulation of anthocyanin. Moreover, genes encoding transcription factors that regulate flavonoids were identified by coexpression analysis. These results may help to identify the metabolic factors that influence leaf color differentiation and provide reference for future research on leaf color biology and the genetic improvement of tea.
Nlrp9a, Nlrp9b and Nlrp9c are preferentially expressed in
oocytes and early embryos in the mouse. Simultaneous genetic ablation of Nlrp9a and
Nlrp9c does not affect early embryonic development, but the function of
Nlrp9b in the process of oocyte maturation and embryonic development has not been
elucidated. Here we show that both Nlrp9b mRNA and its protein are expressed in ovaries and
the small intestine. Moreover, the NLRP9B protein was restricted to oocytes in the ovary and declined with
oocyte aging. After ovulation and fertilization, NLRP9B protein was found in preimplantation embryos. Confocal
microscopy demonstrated that it was mainly localized in the cytoplasm in the oocytes and blastomeres. Thus,
this protein might play a role in oocyte maturation and early embryonic development. However, knockdown of
Nlrp9b expression in GV-stage oocytes using RNA interference did not affect oocyte
maturation or subsequent parthenogenetic development after Nlrp9b-deficient oocytes were
activated. Furthermore, Nlrp9b knockdown zygotes could reach the blastocyst stage after being
cultured for 3.5 days in vitro. These results provide the first evidence that the NLRP9B
protein is dispensable for oocyte maturation and early embryonic development in the mouse.
The Nlrp gene family contains 20 members and plays a pivotal role in the innate immune and reproductive systems in the mouse. During evolution, seven Nlrp4 gene copies (named from Nlrp4a to Nlrp4g). Nlrp4a-Nlrp4g have arisen that display specific or preferential ovarian expression patterns. However, the expression pattern and localization of Nlrp4g in mouse preimplantation embryo development are unknown. Here we report that Nlrp4g was highly expressed in mature oocytes and zygotes, then downregulated and not detected after the 2-cell embryo stage. NLRP4G protein remained present through the blastocyst stage and was mainly localized in the cytoplasm. Furthermore, overexpression of Nlrp4g in zygotes did not affect normal development in terms of the rate of blastocyst formation. These results provide the first evidence that NLRP4G is a maternal factor that may play essential role during zygotic genome activation in the mouse.
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