Histone macroH2A1 is concentrated in the inactive X chromosome of female preimplantation mouse embryos.

MacroH2As are core histone proteins with a hybrid structure consisting of a domain that closely resembles a full-length histone H2A followed by a large nonhistone domain. We recently showed that one of the macroH2A subtypes, macroH2A1.2, is concentrated in the inactive X chromosome in adult female mammals. Here we examine the timing of the association of macroH2A1.2 with the inactive X chromosome during preimplantation mouse development in order to assess the possibility that macroH2A1 participates in the initiation of X inactivation. The association of macroH2A1.2 with one of the X chromosomes was observed in 50% of blastocysts, occurring mostly, if not exclusively, in extraembryonic cells as was expected from previous studies, which indicated that X inactivation in embryonic lineages happens after implantation. Examination of earlier embryonic stages indicates that the association of macroH2A1 with the inactive X chromosome begins between the 8- and 16-cell stages. Of the changes that are known to happen during X inactivation in preimplantation embryos, the accumulation of macroH2A1 appears to be the earliest marker of the inactive X chromosome and is the only change that has been shown to occur during the period when transcriptional silencing is initiated.

Stage-dependent redistributions of acetylated histones in nuclei of the early preimplantation mouse embryo.

In the preimplantation mouse embryo, activation of the embryonic genome is accompanied by a transient enrichment of histone H4 acetylated at lysines 5, 8, and 12 at the nuclear periphery (Worrad et al., 1995: Development 121:2949-2959). In the present report, we use laser-scanning confocal microscopy and a new panel of antibodies to define the distribution of specific acetylated isoforms of the other three core histones in mouse embryos at the 1- to 4-cell stage. We find that histone H3 acetylated at lysine 9 and/or 18 (H3.Ac9/18) and the single acetylated form of H2A (H2A.Ac5) become transiently enriched at the nuclear periphery in the 2-cell embryo. In contrast, H3.Ac14, H3.Ac23, and acetylated H2B, like H4.Ac16, remain distributed throughout the nucleoplasm. The staining intensity with antisera to H3.Ac9/18, even at the periphery was weak compared to that obtained with antisera to acetylated H4. A brief period of culture, however, in the presence of the inhibitor of histone deacetylases trichostatin A (TSA) or trapoxin increased labeling. Thus, the steady-state level of H3.Ac9/18 at the nuclear periphery and H3.Ac14 and H3.Ac23 in the nuclear interior is relatively low, but turnover remains high. The localization of selected acetylated isoforms of H3 and H2A at the nuclear periphery was independent of ongoing transcription or of cytokinesis, but did require DNA replication. We propose a model in which the selective, replication-dependent acetylation and deacetylation of zygotic chromatin at the nuclear periphery mediates the programming of zygotic transcription.

Regulation of gene expression in the preimplantation mouse embryo: temporal and spatial patterns of expression of the transcription factor Sp1.

Activation of the embryonic genome during preimplantation mouse development entails a dramatic reprogramming of the pattern of gene expression. The complement of transcription factors that are present in the early embryo and that must intrinsically be involved in this reprogramming is essentially uncharacterized. We and others have demonstrated that transcription factor Sp1 is present in the mouse oocyte and early cleavage stage preimplantation embryo. Due to Sp1's prominent role in regulating the expression of a vast array of genes that are involved in cell proliferation and differentiation, as well as in general housekeeping functions, we characterized the temporal and spatial patterns of Sp1 expression during preimplantation development. The relative abundance of Sp1 transcripts, as well as transcripts for the TATA box-binding protein TBP, decreases during oocyte maturation and reaches a minimum level in the two-cell stage, after which time the abundance of these transcripts increases progressively to the blastocyst stage. Immunoblotting experiments detect Sp1 species of Mr = 95,000 and 105,000 at all stages of preimplantation development. The amount of Sp1 increases about 8-fold during preimplantation development, and an alpha-amanitin-insensitive increase is observed between G1 and G2 of the one-cell embryo; this increase may reflect the mobilization of a maternal Sp1 transcript. Immunocytochemical experiments also reveal a similar increase in the amount of Sp1 during preimplantation; the nuclear concentration of Sp1 is greater in the trophectoderm cells than in the inner cell mass cells. Finally, gel-shift experiments document an increase during preimplantation development of a DNA-binding activity that is likely due to Sp1. These increases in the abundance of the Sp1 protein and an Sp1-like DNA-binding activity parallel increases in the rate of transcription that occur during preimplantation development.

Regulation of transcriptional activity during the first and second cell cycles in the preimplantation mouse embryo.

Transcription of endogenous genes in preimplantation 1- and 2-cell mouse embryos was determined by monitoring the incorporation of BrUTP by plasma membrane-permeabilized embryos. Incorporation is observed starting by mid-S phase in the 1-cell embryo and increases progressively; the amount of incorporation by the 1-cell embryo in G2 is about 20% that of the 2-cell embryo in G2. Incorporation by the male pronucleus is always about four to five times greater than that of the female pronucleus. Nevertheless, the amount of incorporation by the female pronucleus present in parthogenetically activated eggs is similar to the total amount of incorporation in inseminated eggs, i.e., the transcriptional capacity of the female pronucleus is not inherently less than that of the male pronucleus. Inhibiting the first round of DNA replication does not prevent the initiation of transcription in the 1-cell embryo, but does inhibit the extent of BrUTP incorporation by 35%. The transcriptional machinery of the 1-cell embryo appears to be rate-limiting, since the total amount of BrUTP incorporation by parthenogenetically activated and dispermic eggs is similar to that in monospermic eggs; trispermic eggs incorporate BrUTP to only about 60% the level of monospermic eggs. A transcriptionally repressive state may start to develop in the 2-cell embryo, since inhibiting the second round of DNA replication results in an 50% increase in BrUTP incorporation. Trapoxin treatment, which induces histone hyperacetylation, enhances incorporation by 2-cell embryos 1.8-fold and suggests that histone hyperacetylation can relieve this repression.

Temporally restricted spatial localization of acetylated isoforms of histone H4 and RNA polymerase II in the 2-cell mouse embryo.

Using immunofluorescent labeling and laser-scanning confocal microscopy, we show that isoforms of histone H4 acetylated on lysine 5, 8 and/or 12 (H4.Ac5-12), as well as RNA polymerase II, become enriched at the nuclear periphery around the time of zygotic gene activation, i.e., the 2-cell stage, in the preimplantation mouse embryo. In contrast, DNA and H4 acetylated on lysine 16 are uniformly distributed throughout the cytoplasm. Culture of embryos with inhibitors of histone deacetylase trichostatin A and trapoxin results in an increase in the (1) amount of acetylated histone H4 detected by immunoblotting, (2) intensity and sharpness of the peripheral staining for H4.Ac5-12, and (3) relative rate of synthesis of proteins that are markers for zygotic gene activation. The enhanced staining for H4.Ac5-12 at the nuclear periphery seems to require DNA replication, but appears independent of cytokinesis or transcription, since its development is inhibited by aphidicolin but not by either cytochalasin D or alpha-amanitin. Lastly, the restricted localization of H4.Ac 5-12 is not observed in the 4-cell embryo or at later stages of preimplantation development. These results suggest that changes in chromatin structure underlie, at least in part, zygotic gene activation in the mouse.

Role of chromatin structure in zygotic gene activation in the mammalian embryo.

Changes in chromatin structure, rather than changes in the activity of the transcriptional apparatus, may underlie the timing and basis for zygotic gene activation in the mouse embryo. The transcriptional capacity of the male and female pronuclei differs and the first mitosis is associated with development of a transcriptionally repressive state such that efficient gene expression requires a functional enhancer. This repressive state is also relieved by increasing the level of histone H4 hyperacetylation. Zygotic gene activation is also associated with the transient enrichment of chromatin containing hyperacetylated histone H4 and RNA polymerase II at the nuclear periphery. Depletion of maternally-derived histones as the signal for zygotic gene activation is explored.

Regulation of gene expression in the mouse oocyte and early preimplantation embryo: developmental changes in Sp1 and TATA box-binding protein, TBP.

We previously demonstrated that an Sp1-dependent reporter gene is preferentially expressed in G2 of the 1-cell mouse embryo following microinjection of the male pronucleus when compared to microinjection of the female pronucleus (P.T. Ram and R.M. Schultz, 1993, Dev. Biol. 156, 552-556). We also noted that expression of the reporter gene is not observed following microinjection of the germinal vesicle of the fully grown oocyte. In the present study, we examined expression of this reporter gene during oocyte growth, as well as the nuclear concentration of two transcription factors, Sp1 and the TATA box-binding protein, TBP, during oocyte growth and the first cell cycle. The extent of reporter gene expression decreases during oocyte growth and this decrease correlates with the decrease in nuclear concentration of Sp1, as determined by confocal immunofluorescent microscopy. In addition, results of immunoblotting experiments also indicate a similar decrease in the total concentration of Sp1 during oocyte growth. The nuclear concentration of TBP also decreases during oocyte growth, as determined by confocal immunofluorescent microscopy. Following fertilization, the pronuclear concentration of these two transcription factors increases in a time-dependent fashion and the concentration of each is greater in the male pronucleus as compared to the female pronucleus. For each pronucleus and for each transcription factor, this increase in nuclear concentration is inhibited by aphidicolin, which inhibits DNA synthesis. Last, the increase in nuclear concentration of these two proteins observed between the 1-cell and 2-cell stages does not require transcription or cytokinesis.

The herpes simplex virus type 2 UL3 open reading frame encodes a nuclear localizing phosphoprotein.

The herpes simplex virus type 2 (HSV-2, strain 333) UL3 open reading frame (ORF) codes for a protein with a predicted molecular weight of 29,681. Comparisons of the UL3, strain 333 ORF show essentially complete amino acid identity with HSV-2 (strain HG52) and a 75% amino acid identity with HSV type 1 (strain 17). To characterize the expression of this gene, a hydrophilic region of the HSV-2 UL3 gene was cloned into a bacterial expression vector. The resulting fusion protein was used to generate antibodies in rabbits. In vitro translation of HSV-2-derived mRNA followed by immunoprecipitation with the rabbit antisera reveals a major 28,000-Da protein as judged by SDS-polyacrylamide gel electrophoresis. This is consistent with the predicted molecular weight of an unmodified UL3 protein. Pulse-labeling of infected cells, with [35S]methionine, followed by immunoprecipitation and electrophoretic analysis reveals three distinct bands of 28,000, 30,500, and 33,000 Da. Labeling infected cells with [32P]orthophosphate shows that the 30,500- and the 33,000-Da species are post-translationally phosphorylated. The 30,500-Da species can be converted to the 28,000-Da species with alkaline phosphatase treatment. Interestingly, the 33,000-Da species is resistant to this treatment. Immunohistochemical analysis of infected cells reveals that the UL3 protein has a perinuclear location early in infection and at later times becomes associated with the nucleus as discrete particles. A mutant of HSV, which has a major deletion of the UL3 coding region does not show any immunohistochemical staining with the UL3 antisera. The wild-type virus-infected cell staining pattern remains the same subsequent to DNAse and RNAse treatment, indicating that the UL3 protein product is not directly associated with nucleic acid.

Identification of the coding sequence for herpes simplex virus uracil-DNA glycosylase.

We have recently isolated a herpes simplex virus (HSV) type 2 (strain 333)-specific cDNA that encodes uracil-DNA glycosylase. This cDNA lies between 0.065 and 0.08 map units on the HSV genome. Within this region there are five overlapping transcripts which encompass three open reading frames. We have determined that the second open reading frame, UL-2, codes for glycosylase. In vitro transcription of the UL-2 region and subsequent translation yielded uracil-DNA glycosylase activity. Sequence analysis of the UL-2 open reading frame indicated a coding capacity of 295 amino acids. Comparison to the HSV type 1 (strain 17) sequence indicated that there is 74% amino acid homology between the two strains, with most of the conservation occurring in the middle and the 3' end. The 5' end, however, has diverged considerably.