Abstract
Recent studies of transcription have revealed an advanced set of overarching principles that govern vitamin D action on a genome-wide scale. These tenets of vitamin D transcription have emerged as a result of the application of now well-established techniques of chromatin immunoprecipitation coupled to next-generation DNA sequencing that have now been linked directly to CRISPR-Cas9 genomic editing in culture cells and in mouse tissues in vivo. Accordingly, these techniques have established that the vitamin D hormone modulates sets of cell-type specific genes via an initial action that involves rapid binding of the VDR–ligand complex to multiple enhancer elements at open chromatin sites that drive the expression of individual genes. Importantly, a sequential set of downstream events follows this initial binding that results in rapid histone acetylation at these sites, the recruitment of additional histone modifiers across the gene locus, and in many cases, the appearance of H3K36me3 and RNA polymerase II across gene bodies. The measured recruitment of these factors and/or activities and their presence at specific regions in the gene locus correlate with the emerging presence of cognate transcripts, thereby highlighting sequential molecular events that occur during activation of most genes both in vitro and in vivo. These features provide a novel approach to the study of vitamin D analogs and their actions in vivo and suggest that they can be used for synthetic compound evaluation and to select for novel tissue- and gene-specific features. This may be particularly useful for ligand activation of nuclear receptors given the targeting of these factors directly to genetic sites in the nucleus.
Highlights
Background and Review RationalePublished: 16 November 2021The fundamental actions of the steroid hormone 1,25-dihydroxyvitamin D3 (1,25(OH)2 D3 )are to contribute to the maintenance of calcium (Ca) and phosphorus (P) homeostasis in vertebrate organisms [1]
We suggest that advances in our understanding of vitamin D action at the transcriptional level in vivo may provide useful structure/function relationships, and detailed genomic analyses that could well identify the underlying mechanisms through which a novel analog might operate to manifest tissue, cell, and gene selectivity
The purpose of this manuscript has been to delineate new approaches to the study of mechanisms related to the transcriptional regulation of genes by 1,25(OH)2 D3 and their potential application to the analysis of the vitamin D mediated mechanisms in vitro and in vivo
Summary
The fundamental actions of the steroid hormone 1,25-dihydroxyvitamin D3 (1,25(OH) D3 ). In the past decade or more, the actions of vitamin D have been increasingly linked to a diverse set of important biological activities in non-renal tissues that appear to be separate from those that are involved in mineral regulation [23] In many of these targets and specific cell types within, the actions of vitamin D in vitro appear to contribute to differentiation and/or maturation and to the regulation of genes involved in those processes. Despite the very low levels of expression of these two genes in non-renal tissues, the observations suggest a secondary pathway as an entrée into an additional sphere of vitamin D biology that could potentially be independent of that which maintains circulating endocrine 1,25(OH) D3 In support of this concept, the regulation of Cyp27b1 in non-renal cell types differs substantially from that in kidney. To other NRs and most DNA binding transcription factors, the VDR serves as an initial site-specific DNA adaptor, there are hints that it may sub-serve a non-DNA binding role by interacting with proteins previously bound to DNA as well
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