Synthesis and turnover of late H2B histone mRNA in developing embryos of the sea urchin, Strongylocentrotus purpuratus

In sea urchins, "early" histone proteins are synthesized during cleavage and blastula formation, "late" histone proteins in subsequent stages of development. To understand the molecular mechanisms responsible for this ontogenic switch in histone subtype synthesis, we determined the absolute amounts, rates of synthesis, and rates of turnover of late H2b histone mRNAs during development. We showed previously that late H2b mRNA comprises several mRNA isotypes. In this study, we used both a class-specific DNA probe to measure the amounts of the late H2b mRNA isotypes collectively, and a gene-specific probe to measure amounts of a particular late H2b mRNA encoded by a gene known as L1. We found that the amount of late H2b mRNA increased dramatically from 85,000 molecules per embryo in the 16-hr blastula to a peak of 670,000 molecules per embryo in the 24-hr mesenchyme blastula, and fell to 380,000 molecules per embryo in the 72-hr pluteus larva. The L1 late H2b mRNA achieved its maximum abundance earlier than the late H2b mRNA class as a whole, reaching a peak of 34% of total late H2b in the 14-hr blastula and declining to 7% in the pluteus larva. Measurements of the rate of incorporation of [3H]uridine into late class H2b mRNA, performed by a novel in vivo isotope incorporation method, enabled us to calculate both synthesis rates and half-lives of late H2b mRNA during development. These calculations showed (1) that the increase in late H2b mRNA level between 16 and 24 hr postfertilization is regulated primarily if not entirely at the level of mRNA synthesis; and (2) that the half-life of late H2b mRNA is comparatively short, around 20 min, at all stages examined.     

Individual regulation of the accumulation of H1 mRNA and core histone mRNAs in sea urchin embryos.

The relative cytoplasmic accumulation of the individual histone mRNAs in sea urchins was determined by gel analysis of 3H-labeled cytoplasmic RNA isolated from embryos of the early cleavage through the mesenchyme blastula stages. A number of separate determinations showed that H1 mRNA accumulates at a molar ratio of 0.5 or less compared with each of the H2 or H3 core histone mRNAs through approximately the first 12 h of embryonic development. After this time, the accumulation of H1 mRNA increases relative to the core histone mRNAs, and approximately equimolar amounts of the histone mRNAs are produced by about the 14-h stage. The equimolar synthesis of H1 mRNA appears to be transient, returning to 0.5-molar levels several hours later. The increase in H1 mRNA accumulation, relative to the core histone RNAs, is coincident with the transition from expression of the early (alpha) sea urchin histone gene set to the late histone genes. Since all five of the early histone genes occur in a 1:1 ratio within repeating units, the data suggest that the genes within a single repeat, or their immediate products, are individually regulated. Gel analysis of the proteins synthesized in vivo by embryos demonstrates that the pattern of synthesis of the histone proteins reflects the changing ratios of the histone mRNAs.     

Histone gene switch in the sea urchin embryo. Identification of late embryonic histone messenger ribonucleic acids and the control of their synthesis.

During embryogenesis in the sea urchin Strongylocentrotus purpuratus, there is a shift from one histone mRNA population to another. The early and late embryonic histone mRNAs, previously shown to differ considerably in sequence from each other by hybrid melting studies, are shown here to differ also in electrophoretic mobility on polyacrylamide gels as the positions of the early and late mRNAs are completely noncoincident. The various species of both early and late samples are identified as particular histone mRNAs by hybridization to cloned histone DNAs containing part of the early-type repeat unit or to restriction enzyme fragments derived from these unit. Four bands in the early mRNA sample are identified as H1, H3, H2A " H2B, and H4 mRNA while at least 10 bands can be seen in the late mRNA preparation with unambiguous identification of H1, H2B, and H4 mRNAs. A cluster of late species is shown to contain both H3 and H2A mRNA. When a polysomal RNA preparation from the 26-h embryo is hybridized to the histone DNA, eluted, and then translated in vitro in a wheat germ system, the histone products migrate in the position of late histones when subjected to electrophoresis on Triton X-urea gels. Using DNA which contains genes for H2A + H3 or H2A alone, we demonstrate the specificity of the early-type DNA probes for these two late histones. Therefore, by hybridization of newly synthesized RNAs and translation of the total polysomal RNA present in the late embryo, it is shown that mRNAs for all five histone classes may cross-react with the cloned early-type DNA. The hybrids formed, however, are much less stable than those formed with the early histone mRNA. In vitro translation of total cytoplasmic RNA from various embryonic stages indicates that transition between the two classes occurs during most of the blastula period.     

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 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.     

Synthesis of histone mRNA sequences in isolated nuclei of cleavage stage sea urchin embryos

A qualitative assay for detection of histone mRNA sequences in nuclear RNA was developed using actinomycin D-CsCl gradients to separate histone DNA from bulk DNA by differences in buoyant density. A significant amount of RNA synthesized in vitro in isolated nuclei from early blastula stage sea urchin embryos hybridized coincident with the histone DNA satellite, and this hybridization was competed out by unlabeled “9S” polysomal RNA purified from embryos at the same stage of development. The biogenesis of these histone mRNA sequences appeared similar as observed during in vivo and in vitro synthesis. Nuclear RNA from embryos pulse labeled in vivo was found to lack histone sequences, suggesting a rapid exit time for these sequences from the nucleus. Attempts to study the exit of histone sequences from isolated nuclei labeled in vitro also suggested a rapid exit time for histone sequences. The histone sequences were synthesized to a much lesser extent in isolated nuclei from late blastula stage embryos, as anticipated from the much reduced amount of histone mRNA labeled on polysomes at this stage.     

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.     

Evidences of two different sets of histone genes active during embryogenesis of the sea urchin Paracentrotus lividus.

Histone mRNAs at different stages of development were purified by hybridization with the cloned homologous histone genes. The electrophoretic patterns of oocytes, 2-4 blastomeres, 64 cells and morula histone mRNAs was found to be identical, whereas the electrophoretic pattern of mesenchyme blastula histone mRNA was markedly different. The cloned histone DNA of P.lividus was hybridized with the RNA of each stage. The Tm was 74 degrees C in all cases except for the mesenchyme histone mRNAs whose Tm was 59 degrees C, thus suggesting that at least two different clusters of histone genes are active in the course of the sea urchin development.     

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.     

Stability of histone mRNAs is related to their location in polysomes

Synthesis of histone mRNAs is closely coupled to DNA synthesis. Following inhibition of DNA synthesis in L6 myoblasts with cytosine arabinoside, a coordinate and exaggerated rate of degradation of histone mRNAs occurs while other mRNAs, encoding ribosomal protein L32 and actin, are unaffected. Inhibition of protein synthesis by puromycin, emetine, or cycloheximide stabilizes histone mRNAs and results in their accumulation. When inhibition of DNA synthesis was followed immediately by inhibition of protein synthesis, the exaggerated rate of decay of the existing subspecies of histone H4 mRNAs was prevented and histone mRNA accumulated. If inhibition of protein synthesis was delayed longer than 3 minutes following inhibition of DNA synthesis, the ability to accumulate H4 mRNAs was lost. Furthermore, new protein synthesis was required to activate the mechanism which specifically destabilized histone mRNA. Puromycin was able to prevent the exaggerated rate of degradation of the various subspecies of H4 mRNA when added up to 15 min after inhibition of DNA synthesis, whereas emetine was effective only when added up to 5 min following inhibition of DNA synthesis. These data suggest that histone H4 mRNAs in polysomes are better targets than those released from polysomes for the specific mechanism which destabilizes histone mRNAs upon inhibition of DNA synthesis.     

Morphogenesis and regulated gene activity are independent of DNA replication in Xenopus embryos.

Xenopus embryos were transferred into media containing aphidicolin at late blastula, mid-gastrula, and early neurula stages. In each case, embryos continued to differentiate in the absence of DNA replication. When the inhibitor was added at late blastula, embryos continued to develop for about 8 h. However, when aphidicolin was added at the early neurula stage, development could be seen for up to 40 h after addition. The influence of replication on embryonic gene activity was studied by RNA blot analysis. Of the genes we examined only histone gene expression was down regulated by the addition of aphidicolin. The expression of various embryo-specific genes was unaffected by the lack of DNA synthesis. Even after several hours of treatment with aphidicolin, replication-inhibited tailbud and tadpole stages showed the same levels of specific mRNAs as control embryos containing 4-5 times more DNA. We conclude that morphogenesis and embryo-specific gene activity are independent of both DNA replication and a precise amount of DNA per embryo.     

The relative contributions of newly synthesized and stored messages to Hl histone synthesis in interspecies hybrid echinoid embryos.

We have measured the ratio of incorporation of 3H-lysine into the maternal and paternal forms of Hl histones synthesized by the interordinal hybrid embryo which results from the fertilization of sand dollar eggs with sea urchin sperm. This ratio has been used to calculate the relative contributions of newly transcribed and stored Hl histones mRNA to the synthesis of Hl histone at five different stages of development. These calculations are based on the assumption that histone mRNA of both parental types is transcribed with equal efficiency from the genome and that these RNAs are translated with equal efficiency in the cytoplasm of the hybrid embryos. On this basis, we have estimated that the contribution of new mRNA represents 80% of total Hl histone synthesis at the 16--32 cell stage, 54% at the hatching blastula stage, 40% at the mesenchyme blastula stage, and 100% after gastrulation. These data are discussed in the light of presently known parameters of histone and histone mRNA synthesis in echinoderm embryos.     

The Relative Contributions of Newly Synthesized and Stored Messages to Hl Histone Synthesis in Interspecies Hybrid Echinoid Embryos

We have measured the ratio of incoropation of ³H-lysine into the maternal and paternal forms of Hl histones synthesized by the interordinal hybrid embryo which results from the fertilization of sand dollar eggs with sea urchin sperm. This ratio has been used to calculate the relative contributions of newly transcribed and stored Hl histone mRNA to the synthesis of Hl histone at five different stages of development. These calculations are based on the assumption that histone mRNA of both parental types is transcribed with equal efficiency from the genome and that these RNAs are translated with equal efficiency in the cytoplasm of the hybrid embryos. On this basis, we have estimated that the contribution of new mRNA respresents 80% of total Hl histone synthesis at the 16–32 cell stage, 54% at the hatching blastula stage, 40% at the mesenchyme blastula stage, and 100% after gastrulation.
These data are discussed in the light of presently known parameters of histone and histone mRNA synthesis in echinoderm embryos.     

Synthesis and turnover of polysomal mRNAs in sea urchin embryos

The synthesis and turnover kinetics of polysomal mRNA have been measured in sea urchin embryos. Polysomes were isolated from stages ranging between mesenchyme blastula and late gastrula Strongylocentrotus purpuratus embryos which had been exposed to exogenous ³H-guanosine. The amount of radioactivity incorporated into messenger and ribosomal RNAs was determined separately as a function of time, and the precursor pool specific activity was measured in the same embryos. Synthesis and decay rate constants were extracted from the data by a leastsquares procedure. Per embryo, the rate of mRNA synthesis was calculated to be about 0.13 pg min^?1, while the rate of rRNA synthesis is about 0.022 pg min^?1. The newly synthesized mRNA turns over with a half-time of 5.7 hr. The data support only a single decay rate for the mRNA, but small fractions of mRNA decaying at different rates cannot be excluded. Previous studies have shown that a minor fraction of the mRNA includes the least abundant, most highly diverse set of messages (“complex class” mRNAs). To determine whether mRNAs of the complex class are synthesized and degraded at similar rates, labeled mRNA was measured in hybrids formed in mRNA excess reactions with single copy DNA. These experiments showed that complex class mRNAs represent an approximately proportional amount of the new mRNA synthesis, and turn over at the same average rate as does the bulk of the mRNA. Most of the mRNAs in the embryo polysomes are newly synthesized, rather than maternal. This statement refers both to complex class mRNAs and to prevalent mRNAs. Considering the sequence homology between embryo and oocyte mRNAs shown earlier, these results indicate that many of the same structural genes active during oogenesis are being transcribed in embryos at these stages.     

Subcellular localization of histone messenger RNAs on cytoskeleton-associated free polysomes in HeLa S3 cells

We have examined the subcellular distribution of histone mRNA-containing polysomes in HeLa S3 cells to assess the possible relationship between localization of histone mRNAs and the regulation of cellular histone mRNA levels. The distribution of histone mRNAs on free and membrane bound polysomes was examined as well as the association of histone mRNA-containing polysomes with the cytoskeleton. The subcellular localization of histone mRNAs was compared with that of HLA-B7 mRNAs which encode a cell surface antigen. Histone mRNAs were localized predominantly on the free polysomes, whereas the HLA-B7 mRNA was found almost exclusively on membrane bound polysomes. However, both species of mRNA were found associated with the cytoskeleton. Interruption of DNA synthesis by hydroxyurea treatment resulted in a rapid and selective destabilization of histone mRNAs in each subcellular fraction; in contrast, the stability of HLA-B7 mRNA appeared unaffected. The results presented confirm that histone mRNAs are predominantly located on non-membrane bound polysomes and suggest that these polysomes are associated with the cytoskeletal framework.