Histone messenger RNA synthesis and accumulation during early development in the echiuroid worm, Urechis caupo

RNA isolated from Urechis caupo mature oocytes and embryos was analyzed for the presence of histone messenger RNAs (mRNAs) by in vitro translation and by filter blot hybridization to determine the contribution of maternal and newly transcribed histone mRNAs to the pattern of histone synthesis during early development. Histone mRNAs were not detected in mature oocyte RNA which suggests that relatively few if any maternal histone mRNAs are sequestered in the mature oocytes. Histone mRNAs were detected in cleavage-stage RNA and increased in amount from midcleavage through late gastrula stages. The in vitro translation analysis also demonstrated that the amount of H1 histone mRNA in late cleavage- and early blastula-stage embryos exceeds that of the individual core histone mRNAs. The disproportionate accumulation of individual histone mRNAs correlates with the noncoordinate synthesis of H1 and core histones which occurs during early embryogenesis.     

The sea urchin histone gene complement

The only eukaryotic mRNAs that are not polyadenylated are the replication-dependent histone mRNAs in metazoans. The sea urchin genome contains two sets of histone genes that encode non-polyadenylated mRNAs. One of these sets is a tandemly repeated gene cluster with a 5.6-kb repeat unit containing one copy of each of the five alpha-histone genes and is present as a single large cluster which spans over 1 Mb. There is a second set of genes, consisting of 39 genes, containing two histone H1 genes, 34 genes encoding core histone proteins (H2a, H2b, H3 and H4) and three genes expressed only in the testis. Unlike vertebrates where these genes are clustered, the sea urchin late histone genes, expressed in embryos, larvae and adults, are dispersed throughout the genome. There are also genes encoding polyadenylated histone mRNAs, which encode histone variants, including all variants found in other metazoans, as well as a unique set of five cleavage stage histone proteins expressed in oocytes. The cleavage stage histone H1 is the orthologue of an oocyte-specific histone H1 protein found in vertebrates.     

Expression of maternal and paternal histone genes during early cleavage stages of the echinoderm hybrid Strongylocentrotus purpuratus × Lytechinus pictus

Interspecific hybrids of the sea urchins Strongylocentrotus purpuratus (♀) and Lytechinus pictus (♂) were used to estimate the contributions of the maternal and paternal genomes to histone mRNA synthesis during early development. Radiolabeled histone mRNAs from the two sea urchin species were identified by hybridization to cloned histone genes from both S. purpuratus and L. pictus and shown to be electrophoretically distinguishable. The synthesis of maternal and paternal histone mRNA in these hybrid embryos is evident as early as the two-cell stage. By at least the 16-cell stage, both maternal and paternal histone mRNAs are associated with polysomes. The relative amounts of the maternal and paternal histone mRNAs synthesized by the zygote appear to be similar.     

Histone gene expression during sea urchin embryogenesis: isolation and characterization of early and late messenger RNAs of Strongylocentrotus purpuratus by gene-specific hybridization and template activity

We have examined the molecular mechanisms responsible for the shifts in histone protein phenotype during embryogenesis in the sea urchinStrongylocentrotus purpuratus. The H1, H2A, and H2B classes of histone synthesized at the earliest stages of cleavage are heterogeneous: These proteins are replaced at late embryogenesis by a different set of histone-like polypeptides, some of which are also heterogeneous. The H3 and H4 histones appear to be homogeneous classes and remain constant. We have isolated from both early and late embryos the individual messenger RNAs coding for each of the multiple protein subtypes. The RNAs were isolated by hybridization to cloned DNA segments coding for a single histone protein or by elution from polyacrylamide gels. Each RNA was then analyzed and identified by its mobility on polyacrylamide gels and by its template activity in the wheat germ cell-free protein synthesizing system. The mRNAs for each of the five early histone protein classes are heterogeneous in size and differ from the late stage templates. The late mRNAs consist of at least 11 separable types coding for the 5 classes of histones. Each of the 11 has been separated and identified. The late stage proteins were shown to be authentic histones since many of their templates hybridize with histone coding DNA. The early and late stage mRNAs are transcribed from different sets of histone genes since (1) late stage H1 and H2A mRNAs fail to hybridize to cloned early stage histone genes under ideal conditions for detecting homologous early stage hybrids, (2) late stage H2B, H3, and H4 RNA/DNA hybrids melt at 14, 11, and 11°C lower, respectively, than do homologous RNA/DNA hybrids, and (3) purified late stage mRNAs direct the synthesis of the variant histone proteins which are synthesized only during later stages. The time course of synthesis of the late stage mRNAs suggests that they appear many hours before the late histone proteins can be detected, possibly as early as fertilization. In addition, early mRNAs are synthesized in small quantities as late as 40 hr after fertilization, during gastrulation. Thus, the major modulations of histone gene expression are neither abrupt nor an absolute on-off switch, and may represent only a gradual and relative repression of early gene expression. Two histones are detected only transiently during early cleavage. The mRNA for one of them, a subtype of H2A, can be detected in the cytoplasm for as long as 40 hr after fertilization. However, template activity for the other, a subtype of H2B, can be detected only at the blastula stage. Thus, the histone genes represent a complex multigene family that is developmentally modulated.     

Uncoordinate synthesis of histone H1 in cells arrested in the G1 phase

It has been known for several years that DNA replication and histone synthesis occur concomitantly in cultured mammalian cells. Normally all five classes of histones are synthesized coordinately. However, mouse myeloma cells, synchronized by starvation for isoleucine, synthesize increased amounts of histone H1 relative to the four nucleosomal core histones. This unscheduled synthesis of histone H1 is reduced within 1 h after refeeding isoleucine, and is not a normal component of G1. The synthesis of H1 increases coordinately again with other histones during the S phase. The DNA synthesis inhibitors, cytosine arabinoside and hydroxyurea, block all histone synthesis in S-phase cells. The levels of histone H1 mRNA, relative to the other histone mRNAs, is increased in isoeleucine-starved cells and decreases rapidly after refeeding isoleucine. The increased incorporation of histone H1 is at least partially due to the low isoleucine content of histone H1. Starvation of cells for lysine resulted in a decrease in H1 synthesis relative to core histones. Again the ratio was altered on refeeding the amino acid. 3T3 cells starved for serum also incorporated only H1 histones into chromatin. The ratio of different H1 proteins also changed. The synthesis of the H1⁰ protein was predominant in G₀ cells, and reduced in S-phase cells. These data indicate the metabolism of H1 is independent of the other histones when cell growth is arrested.     

Simultaneous expression of early and late histone messenger RNAs in individual cells during development of the sea urchin embryo

The transition from early (E) to late (L) histone gene expression in developing sea urchin (Strongylocentrotus purpuratus) embryos was examined for H2B, H3, and H4 mRNAs by in situ hybridization of class-specific probes. Hybridization patterns indicate that the shift from E to L mRNAs occurs gradually and simultaneously in all blastomeres. Thus, during the transition the ratio of L to E mRNAs is similar in most cells. This suggests that no sudden changes in histone composition occur in individual cells which might be related to alterations in gene expression associated with differentiation of cell lineages. Around the midpoint of the transition, clusters of cells progressively appear which contain little, if any, E or L histone mRNA. This modulation of expression is coordinated for the three late genes examined because most individual cells contain either high or low levels of all three mRNAs. At blastula stage these clusters of unlabeled cells appear to be randomly distributed throughout the embryo. Subsequently the unlabeled regions expand and are found predominantly in aboral ectoderm as these cells cease to divide. Thus, the L/E histone mRNA ratio is not differentially regulated in diverse cell lineages, and the major differences in total histone mRNA content among individual cells may be related to cell cycle and/or the cessation of division.     

Histone gene expression in early development of Xenopus laevis

Abstract. This study comprises the hybridization analysis of electrophoretically separated histone mRNAs from oocytes and embryos of Xenopus laevis , and analysis of in vitro translation products of these mRNAs on polyacrylamide gels containing sodium dodecyl sulfate (SDS) or Triton X-100. In oocytes and embryos up to the tailbud stage, four types of mRNAs complementary to histone H2B DNA and two complementary to histone H4 DNA can be discriminated by their different electrophoretic mobilities on polyacrylamide gels. Electrophoretic heterogeneity was not detected for messengers for histones H2A and H3.
Histone mRNA, purified by hybridization under stringent conditions with a cloned histone gene cluster, was used to direct histone protein synthesis in a wheat-germ cell free system. The proteins synthesized comigrate with purified marker histones when electrophoresed on SDS-gels or acid-urea gels containing Triton X-100. When hybrid-selected histone mRNAs from oocytes and embryos in different developmental stages are translated, the proteins made by the mRNA from one stage can not be discriminated from those made by the mRNA from another stage after electrophoresis on SDS-gels or acid urea Triton X-100 gels.