Association between proteins and DNA is crucial for many vital cellular functions such as gene transcription, DNA replication and recombination, repair, segregation, chromosomal stability, cell cycle progression, and epigenetic silencing. It is important to know the genomic targets of DNA-binding proteins and the mechanisms by which they control and guide gene regulation pathways and cellular proliferation. Chromatin immunoprecipitation (ChIP) is an important technique in the study of protein-gene interactions. Using ChIP, DNA-protein interactions are studied within the context of the cell. The basic steps in this technique are fixation, sonication, immunoprecipitation, and analysis of the immunoprecipitated DNA. Although ChIP is a very versatile tool, the procedure requires the optimization of reaction conditions. Several modifications to the original ChIP technique have been published to improve the success and to enhance the utility of this procedure. This review addresses the critical parameters and the variants of ChiP as well as the different analytical tools that can be combined with ChIP to enable better understanding of DNA-protein interactions in vivo.
The histone H1t gene is expressed exclusively in testis primary spermatocytes. Previous studies indicate that accumulation of H1t mRNA occurs only in primary spermatocytes in normal rats and in transgenic mice bearing the rat H1t transgene. In this study, DNA sequences of human, monkey, mouse, and rat H1t genes were compared and found to be almost identical in the proximal promoter region extending from the H1/AC box through the TATAA box. In addition to conserved elements common to replication-dependent H1 promoters, the H1t promoter contains a unique TE element, and sequences within this element may contribute to enhanced expression of the gene in primary spermatocytes. Two imperfect inverted repeat sequences designated TE1 and TE2, that are located within the larger TE element, overlap a central GC-rich region and bind specifically to nuclear proteins derived from primary spermatocytes. Protein interactions characterized by methylation interference and UV cross-linking experiments indicate that a complex of proteins with a molecular mass of approximately 180 kDa binds TE1. The GC-rich region in H1t and in some replication dependent histone H1 promoters contains an Sp1 consensus sequence. Although the H1t/TE element that contains the GC-rich region binds nuclear proteins, it does not appear to bind Sp1 obtained from cell populations enriched in primary spermatocytes as determined by electrophoretic mobility supershift assays using polyclonal anti-Sp1 antibodies.
Transcriptional activation of the testis-specific histone H1t gene occurs in pachytene primary spermatocytes during spermatogenesis. Specific binding of testis nuclear proteins to a rat histone H1t promoter sequence, designated the H1t/TE element, correlates with the onset of transcription. This element, located between the H1t/AC box and the H1t/CCAAT box, contains inverted repeats of a shorter element. When the native rat H1t gene along with flanking sequences, including 2453 base pairs (bp) upstream and 3784 bp downstream from the coding region, was microinjected into mouse embryos, the offspring of the resulting transgenic mice transcribed the transgene in a tissue-specific manner and only in primary spermatocytes. In the present study the TE promoter element was deleted and replaced with a heterologous stuffer DNA fragment. When the mutant rat DNA fragment was used to create transgenic mice, offspring of the mice bearing the promoter mutation did not transcribe the rat H1t gene in any tissue. On the other hand, transcription of the rat H4t transgene, which is located approximately 1.5 kilobases downstream from the H1t gene, occurred in these animals. Therefore, these studies support the hypothesis that the TE element is essential for enhanced testis-specific transcription of the H1t gene in primary spermatocytes.
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