Acylfulvene, derived from the sesquiterpene illudin S by treatment with acid (reverse Prins reaction), is far less reactive to thiols than illudin S. However, it is reduced readily to an aromatic product, in the same way as illudin S. This may explain its greatly improved therapeutic index compared to that of the parent compound.
SUMMARYEmbryogenesis requires epigenetic information that allows each cell to respond appropriately to developmental cues. Histone modifications are core components of a cell’s epigenome, giving rise to chromatin states that modulate genome function. Here, we systematically profile histone modifications in a diverse panel of mouse tissues at 8 developmental stages from 10.5 days post conception until birth, performing a total of 1,128 ChIP-seq assays across 72 distinct tissue-stages. We combine these histone modification profiles into a unified set of chromatin state annotations, and track their activity across developmental time and space. Through integrative analysis we identify dynamic enhancers, reveal key transcriptional regulators, and characterize the role of chromatin-based repression in developmental gene regulation. We also leverage these data to link enhancers to putative target genes, revealing connections between coding and non-coding sequence variation in disease etiology. Our study provides a compendium of resources for biomedical researchers, and achieves the most comprehensive view of embryonic chromatin states to date.
This study suggests an association between pCNVs and fetal IMV. pCNVs may be involved in the pathological process of fetal IMV and postnatal NDs. Identifying specific genomic alterations may provide an insight into pathogenetic mechanism and aid better diagnosis and prognosis of neurodevelopmental outcomes in fetal IMV.
Dynamic changes in the transcriptional regulatory circuit can influence the specification of distinct cell types. Numerous transcription factors (TFs) have been shown to function through dynamic rewiring during embryonic development but a comprehensive survey on the global regulatory network is still lacking. Here, we performed an integrated analysis of epigenomic and transcriptomic data to reveal key regulators from 2 cells to postnatal day 0 in mouse embryogenesis. We predicted 3D chromatin interactions including enhancer-promoter interactions in 12 tissues across 8 developmental stages, which facilitates linking TFs to their target genes for constructing genetic networks. To identify driver TFs particularly those not necessarily differentially expressed ones, we developed a new algorithm, dubbed as Taiji, to assess the global importance of TFs in development. Through comparative analysis across tissues and developmental stages, we systematically uncovered TFs that are critical for lineage-specific and stage-dependent tissue specification. Most interestingly, we have identified TF combinations that function in spatiotemporal order to form transcriptional waves regulating developmental progress and differentiation. Not only does our analysis provide the first comprehensive map of transcriptional regulatory circuits during mouse embryonic development, the identified novel regulators and the predicted 3D chromatin interactions also provide a valuable resource to guide further mechanistic studies.
Pexophagy is a selective autophagy process that degrades damaged and/or superfluous peroxisomes in the yeast vacuole or in mammalian lysosomes. The molecular mechanisms of pexophagy are well studied in yeast. Peroxisomes can be rapidly induced by oleate in the budding yeast, Saccharomyces cerevisiae, and by oleate or methanol in the methylotrophic yeast, Pichia pastoris. A number of peroxisomal matrix enzymes, such as 3-ketoacyl CoA thiolase (thiolase) and alcohol oxidase (AOX), are upregulated correspondingly to meet metabolic demands of the cells. Removal of these peroxisome-inducing carbon sources creates conditions wherein peroxisomes are superfluous and results in pexophagy and the degradation of these peroxisomal matrix enzymes. In this chapter, we discuss different assays to monitor pexophagy in yeast. These assays rely on tracking the localization of the BFP–SKL protein (a peroxisomally targeted version of the blue fluorescent protein) by microscopy, biochemical analysis of the degradation of peroxisomal matrix proteins, thiolase and AOX, and/or measuring the reduction of AOX activity during pexophagy.
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