Spatial distribution of histone isoforms on the bovine active and inactive X chromosomes.

The inactive X chromosome (Xi) in female mammals serves as an important model for studying the role of histone isoforms in directing specific nuclear processes leading to inherited differences in transcription. In the present study, we investigated the distribution of some histone isoforms known to be involved in the process of human X inactivation on their bovine counterparts. To ascertain the identity of active and inactive X chromosome, their distribution was investigated on the X chromosomes in a cell line derived from a bovine female carrying an X;autosome translocation rcp(Xp+;23q-) which allowed the recognition of the maternal (translocated) and paternal (normal) X chromosome. The distribution patterns of histone H3 trimethylated at lysine 9 (H3K9me3) and trimethylated at lysine 27 (H3K27me3), and histone macroH2A1 and macroH2A2 (isoforms specific to heterochromatin) were determined by immunocytochemistry and compared to the temporal pattern of replication using BrdU pulse labeling prior to staining. Immunostaining revealed that H3K9me3, H3K27me3, and macroH2A1 are preferentially concentrated on the Xi, whereas the histone variant macroH2A2 is not a marker for this chromosome. H3K9me3, H3K27me3, and macroH2A1 were consistently located in bands along the Xi, while H3K9me3, macroH2A1 and macroH2A2 localized in the pericentromeric regions of the autosomes. H3K27me3 identified two intense bands on the Xi at Xp22 and Xq31, representing the early replication regions of the chromosome. H3K27me3 and macroH2A1 overlapped in the Xq31 region. It was concluded that different heterochromatin regions on the bovine inactive X chromosome can be identified by their histone isoform composition.

The impact of chromosomal alteration on embryo development.

Chromosome alterations, such as those affecting telomere erosion, predictably occur with each cell division, others, which involve changes to the expression and replication of the X-chromosome occur at particular stages of development, while those that involve loss or gain of chromosomes occur in a random and so far unpredictable manner. The production of embryos in vitro and by somatic cell nuclear transfer (SCNT) has been associated with altered expression of marker genes on the X-chromosome and an increased incidence of chromosomally abnormal cells during early development. In the case of SCNT embryos chromosome abnormalities may be associated with the nuclear donor cell. Telomere rebuilding subsequent to SCNT appears to vary according to species and type of donor cell used. It is speculated that the rate of telomere erosion and incidence of chromosome abnormalities affects developmental potential of early embryos and may be potential predictors of developmental outcome.

Expression of growth hormone and its transcription factor, Pit-1, in early bovine development.

During bovine embryogenesis, bovine growth hormone (bGH) contributes to proliferation, differentiation, and modulation of embryo metabolism. Pituitary-specific transcription factor-1 (Pit-1) is a transcription factor that binds to promoters of GH, prolactin (PRL), and thyroid-stimulating hormone-beta (TSHbeta) encoding genes. A polymorphism in the fifth exon of the bGH gene resulting in a leucine (Leu) to valine (Val) substitution provides an Alu I restriction site when the Leu allele is present. To determine the onset of embryonic expression of the bGH gene, oocytes derived from ovaries homozygous for Leu alleles were fertilized in vitro with spermatozoa obtained from a Val homozygote. For each developmental stage examined, three separate pools of embryos composed of approximately 100 cell samples underwent RNA isolation, reverse transcription to cDNA, and amplification by nested PCR (nPCR). Bovine GH gene transcripts were identified at 2- to 4-cell (n = 162), 8- to 16-cell (n = 73), morulae (n = 51), and blastocyst (n = 15) stages. Likewise, transcripts for Pit-1 were detected at 2-cell (n = 125), 4-cell (n = 114), 8-cell (n = 56), 12-to-32-cell (n = 32), morulae (n = 68), and blastocyst (n = 14) stages. After digestion with Alu1, bGH cDNA was genotyped by restriction fragment length polymorphism (RFLP) analysis. Bovine GH mRNA was present in all pools of stages examined. Both Leu and Val alleles (maternal and paternal) were only detected in pools of embryos that had reached 8- to 16-cell stage. Results suggest that transcription of the bGH gene begins at the 8- to 16-cell stage in bovine embryos, possibly under control of the transcription factor, Pit-1, and that RFLP analysis of the bGH gene can be used to determine parental origin of transcripts in early embryonic development.