Previous work in our laboratory revealed upregulated transcription of the testis-specific linker histone H1t gene in pachytene primary spermatocytes during spermatogenesis. Using the H1t X-box as an affinity chromatography probe, we identified Regulatory Factor X2 (RFX2), a member of the RFX family of transcription factors, as a nuclear protein that binds the probe. We also showed that RFX2 activated the H1t promoter in transient expression assays. However, other RFX family members have the same DNA-binding domain and they also may regulate H1t gene expression. Therefore, in this study we examined the distribution of RFX2 and other RFX family members in rat testis germinal cells and in several tissues. Among tissues examined, RFX2 is most abundant in testis. Testis RFX2 is most abundant in spermatocytes where transcription of the H1t gene is upregulated and the steady-state H1t mRNA level is high. RFX2 levels decrease but RFX1 levels increase in early spermatids where H1t gene transcription is downregulated. Antibodies against RFX2 generate a shifted band in electrophoretic mobility shift assays (EMSA) using H1t or testisin X-box DNA probes with nuclear proteins from spermatocytes. These data support the hypothesis that RFX2 expression is upregulated in spermatocytes where it participates in activating transcription of the H1t gene and other testis genes. These data also support the possibility that other RFX family members may bind to the H1t promoter in other testis germinal cell types and in nongerminal cells to downregulate H1t gene transcription.
Differential expression of globin genes has provided an interesting model system for better understanding commonly inherited diseases such as thalassemia. In the avian beta-type globin cluster (5'-rho-betaH-betaA-epsilon-3'), silencing of the embryonic rho-globin gene occurs concomitantly with the activation of the adult betaA-globin gene during embryonic development. DNA methylation is a dynamic process that regulates gene expression. We observed a progressive loss of methylation of betaA-globin gene, during avian embryonic development that was concurrent with the expression of the gene. The promoter and exon 1 regions of the template strand were completely demethylated, whereas residual methylation was retained in exons 2 and 3. Using a modified methylation-sensitive single-nucleotide primer extension (MS-SNuPE) assay, we observed stage-specific demethylase activity in the nuclear extracts of chicken red cells; activity in 5-, 8-, and 11-day-old erythroid cell nuclear extracts was 6, 76, and 24%, respectively. The demethylase targeted both hemimethylated and fully methylated substrates. Our findings demonstrate stage-specific demethylase activity in nuclear extracts from primary chicken erythroid cells that could target the fully methylated promoter of a developmentally regulated native gene.
Differential expression of globin genes has provided an interesting model system for the better understanding of commonly inherited diseases such as thalassemia. In the avian β-type globin cluster (5′- ρ-βA- βA - ε - 3′), silencing of the embryonic ρ-globin gene occurs concomitantly with the activation of adult βA-globin gene during the embryonic development. The pattern of cytosine methylation plays an important role in gene regulation. We have previously shown that de novo methylation of the embryonic ρ-globin gene during development is strand-asymmetrical and spreads from the proximal transcribed region in the early definitive chicken erythroid cells. In the present study, we examined the methylation pattern of βA- globin gene during development in primary chicken erythroid cells. Using bisulfite genomic sequencing we observed a progressive demethylation of βA- globin gene during embryonic development. Maximum methylation is seen in the different regions of the βA- globin gene on day 5, which reduces on day 8 by about 50 %, and on day 11 the degree of methylation is minimal. Further, strand and regional asymmetry was seen with respect to loss of methylation. The template strand gets demethylated first and demethylation of the coding strand lags behind. The promoter and exon 1 get completely demethylated by day 11 whereas residual methylation is retained on exons 2 and 3. To investigate the mechanism of loss of methylation, we examined the methylation pattern of multiple DNA strands derived from primitive and early definitive embryonic erythroid cells. The primitive embryonic erythroid cells demonstrated methylation of the βA- globin promoter and exon 1 on most of the CpG dinucleotides. Discontinuous loss of methylation in early definitive erythroid cells suggested an active mechanism of demethylation since the DNA replication mediated passive demethylation is likely to be continuous. To investigate if an active process contributes to the demethylation of βA- globin gene, we used a modified methylation sensitive single nucleotide primer extension assay (MS-SNuPE) assay for quantitation of demethylase activity. Demethylase assay was carried out using synthetic unmethylated, hemimethylated, and completely methylated oligonucleotides derived from the βA-globin promoter region and nuclear extracts from embryonic chicken erythroid cells. The demethylase activity in day 5, 8 and 11 nuclear extracts was 6%, 76%, and 24% respectively. In contrast to the previously reported 5-methylcytosine glycosylase, which shows a significant substrate specificity for the hemimethylated DNA, we observed the demethylase activity in the embryonic chicken erythroid cells on both fully methylated and hemimethylated βA-globin promoter sequences. Since human and chicken methyl binding domain 4 (MBD4) proteins exhibit 5-methylcytosine glycosylase activity, we determined the in vivo binding of MBD4 to βA- globin promoter in chicken erythroid cells using Chromatin ImmunoPrecipitation (ChIP) followed by real time polymerase chain reaction. MBD4 binding to βA- globin promoter was seen in day 8 but not day 5 chicken erythroid cells implicating a possible role of chicken MBD4 in mediating the active demethylation of the avian βA- globin gene. Our findings demonstrate that demethylation of βA globin gene in developing primary chicken erythroid cells shows strand and regional asymmetry and occurs at least in part by an active process.
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