Maternal messenger RNA and histone synthesis in embryos of the surf clam Spisula solidissima.

Messenger RNA has been isolated from the postribosomal supernatant of Spisula solidissima eggs. This mRNA directs the synthesis of several proteins when added to the ascites or wheat germ cell free system. No histone except F1 is coded for by Spisula egg mRNA, in contrast to what has been reported previously for sea urchin egg mRNA. In sea urchin eggs histone mRNA is among the abundant species of maternal mRNA.Histones have been prepared from Spisula embryos at different development stages and histone synthesis followed by incubation with (¹⁴C)lysine. The analysis by electrophoresis on acrylamide gels indicates that the pattern of synthesis of histones changes during development and that a new histone F1 fraction is actively synthesized from the 32–64 cells stage. In earlier embryos a different F1 histone is synthesized and the mRNA for this protein may be the only histone mRNA present in eggs.     

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.     

Translational regulation of histone synthesis in the sea urchin strongylocentrotus purpuratus

The pattern and schedule of histone synthesis in unfertilized eggs and early embryos of the sea urchin Strongylocentrotus purpuratus were studied using two-dimensional gel electrophoresis. After fertilization there is an abrupt change in the pattern of histone variant synthesis. Although both cleavage-stage (CS) variants. However, after fertilization, both CS and alpha messages are translated. Since alpha histone mRNA isolated from unfertilized eggs can be translated in vitro, the synthesis of alpha histone subtypes appears to be under translational control. Although the synthesis of alpha subtypes is shown here to occur before the second S phase after fertilization, little or no alpha histone is incorporated into chromatin at this time. Thus, early chromatin is composed predominantly of CS variants probably recruited for the most part from the large pool of CS histones stored in the unfertilized egg.     

Changing rates of histone mRNA synthesis and turnover in Drosophila embryos

The rates of synthesis and turnover of histone mRNA in Drosophila embryos were determined by hybridization of in vivo and in vitro labeled embryonic RNA to Drosophila histone DNA of the recombinant plasmid cDm500. There is a large store of maternal histone mRNA, equivalent to at least 7 X 10(7) copies of each of the five classes of histone mRNA per embryo. Embryonic synthesis of histone mRNA begins at 90 min after oviposition, making the histone genes among the first to be transcribed by embryonic nuclei. Embryonic histone mRNA accumulates rapidly during the blastoderm and gastrula stages. The peak in the rate of histone mRNA synthesis per embryo coincides with the peak in the rate of DNA synthesis per embryo, which occurs at 6 hr after oviposition. After 6 hr, as the rate of DNA synthesis per embryo decreases, the rate of histone mRNA synthesis and the total mass of histone mRNA per embryo both drop sharply. The rate of histone mRNA synthesis per gene falls more than 60 fold in the first 13 hr after oviposition, from 1.3 -2.5 copies per gene-min at 2 hr to 0.02-0.03 copies per gene-min at 13 hr. From measurements of the mass of histone mRNA per embryo and of the rate of accumulation of newly synthesized histone mRNA at a number of stages of early embryogenesis we determined that the cytoplasmic half-life of histone mRNA decreases approximately 7 fold during early Drosophila development, from 2.3 hr at blastoderm to 20 min by the end of gastrulation. Thus the level of expression of histone genes in Drosophila development is controlled not only by the size of the maternal mRNA pool and changes in the rate of histone mRNA synthesis, but also by changes in the rate of histone mRNA turnover.     

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.     

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 stability and translation of sea urchin histone messenger RNA molecules injected into Xenopus laevis eggs and developing embryos

Embryonic sea urchin histone mRNA was injected into eggs and developing zygotes of Xenopus. The functional stability of the mRNA was monitored by separating newly synthesized sea urchin histones from those of Xenopus. Just as when injected into Xenopus oocytes, sea urchin H1, H2A, and H2B mRNA molecules have a functional half-life of about 3 hr in the developing embryo. This suggests that the endogenous Xenopus histone mRNA is also unstable and has a number of implications for the amount of histone mRNA that is stored in the oocyte and the time at which histone genes should become active in development. The injected mRNA is translated with little, if any, greater efficiency in the egg than in the oocyte. However, Xenopus histone synthesis increases about 20- to 50-fold during the transition from oocyte to egg. The injection experiments therefore suggest that this increase is brought about primarily by the mobilization of stored mRNA, rather than an increase in the efficiency of histone synthesis.     

Cell-free translation analysis of messenger RNA in echinoderm and amphibian early development

A wheat germ cell-free translation system has been used to analyze populations of abundant messenger RNA from sea urchin eggs and embryos and from amphibian oocytes and ovaries. We show directly that sea urchin eggs and embryos contain translatable mRNA of three general classes: poly(A)⁺ mRNA, poly(A)^? histone mRNA, and poly(A)^? nonhistone mRNA. Additionally, some histone synthesis appears to be promoted by poly(A)⁺ RNA. Sea urchin eggs seem to contain a higher proportion of prevalent poly(A)^? nonhistone mRNAS than do embryos. Some differences in the proteins encoded by poly(A)⁺ and poly(A)^? RNAs are detectable. Many coding sequences in the egg appear to be represented in both poly(A)⁺ and poly(A)^? RNAs, since the translation products of the two RNA classes exhibit many common bands when run on one-dimensional polyacrylamide gels. However, some of this overlap is probably due to fortuitous comigration of nonidentical proteins. Distinct stage-specific changes in the spectra of prevalent translatable mRNAs of all three classes occur, although many mRNAs are detectable throughout early development. Particularly striking is the presence of an egg poly(A)^? mRNA, encoding a 70,000–80,000 molecular weight protein, which is not detected in morula or later-stage embryos. In amphibian (Xenopus laevis and Triturus viridescens) ovary RNA, the translation assay detects the following three mRNA classes: poly(A)⁺ nonhistone mRNA, poly(A)^? histone mRNA, and poly(A)⁺ histone mRNA. Amphibian ovary RNA appearently lacks an abundant poly(A)^? nonhistone mRNA component of the magnitude detectable in sea urchin eggs. mRNA encoding histone-like proteins is found in the very earliest (small stage 1) oocytes of Xenopus as well as in later stage oocytes. During oogenesis there appear to be no striking qualitative changes in the spectra of prevalent translatable mRNAs which are detected by the cell-free translation assay.     

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.     

Translation is required for regulation of histone mRNA degradation

When DNA synthesis is inhibited, the mRNAs coding for the replication-dependent histone proteins are selectively destabilized. The histone genes have been altered and reintroduced into tk- mouse L cells by cotransfection with the herpesvirus thymidine kinase gene. Two features of the mRNA are necessary for regulation of degradation: first, the hairpin loop must be present at the 3' end of the histone mRNA; and second, the histone mRNA must be capable of being translated to within 300 nucleotides of the 3' end of the RNA. Polyadenylated histone mRNAs are stable, as are histone mRNAs that contain in-frame termination codons early in the coding region or 500 nucleotide 3' untranslated regions with a normal hairpin loop at the 3' end.     

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.     

Size and sequence homology of masked maternal and embryonic histone messenger RNAs.

The messenger RNAs for five classes of histone proteins are shown by competitive RNA-DNA hybridization to be stored in the unfertilized egg of the sea urchin, Lytechinus pictus. The masked mRNAs for f2b, f2a2, f3 and f2al histones migrate in polyacrylamide slab gels with the same mobility as the histone mRNAs that are synthesized after fertilization and are found engaged in protein synthesis on polysomes. The masked maternal and embryonic mRNAs for histone f2a1 are identical in mobility when analyzed in a gel system capable of resolving differences estimated as small as 4–5 nucleotides in length. We conclude that these histone mRNAs synthesized during oogenesis and inactive prior to fertilization are not activated during embryogeny by alteration in their molecular size.     

Changing rates of DNA and RNA synthesis in Drosophila embryos

Rates of DNA and RNA synthesis during Drosophila embryogenesis were measured by labeling octane-treated embryos with [¹⁴C]thymidine and [³H]uridine. Radioactivity incorporated per hour was converted to rates of synthesis using measurements of the pool-specific activity during the labeling periods. The rate of DNA synthesis during early embryogenesis increases to a maximum at 6 hr after oviposition and then decreases sharply. Measured rates of DNA synthesis were used to calculate that the total amount of DNA per embryo doubles every 18 min at blastoderm, every 70–80 min during gastrulation, and less than once every 7 hr at later stages. The rate of RNA accumulation per embryo increases continuously during the first 14 hr of embryogenesis. The rate of nuclear RNA synthesis per diploid amount of DNA, however, decreases fivefold between blastoderm and primary organogenesis. The cytoplasmic poly(A)⁺ RNA synthesized by blastoderm embryos associates rapidly with polysomes. The relatively high rate of synthesis of polysomal poly(A)⁺ RNA per nucleus at blastoderm allows the small number of nuclei present at blastoderm to make a significant quantitative contribution to the informational RNA active in the early embryo. At the end of blastoderm, approximately 14% of the mRNA being translated in the embryo has been synthesized after fertilization.     

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.     

Control of mRNA translation in oocytes and developing embryos of giant moths. I. Function of the 5' terminal "Cap"in the tobacco hornworm, Manduca sexta

Injection of labeled leucine into oocytes and developing embryos of the tobacco hornworm, Manduca sexta, revealed that the rate of protein synthesis increases dramatically after fertilization and continues to rise until gastrulation. Cell-free preparations of oocytes and developing embryos show a similar pattern of in vitro incorporation. When messenger RNA extracted from unfertilized oocytes was examined by gradient density centrifugation under denaturing conditions, a broad peak was observed which centered around 15 S. In contrast to mRNA extracted from oocytes, that from embryos was found to be capped by 7-methylguanosine at the 5′ terminus. When translation of oocyte mRNA was compared with that of embryo mRNA in a cell-free translation system derived from wheat germ, oocyte RNA translated less efficiently. In the presence of an inhibitor of methylation, S-adenosylhomocysteine, the differences were further widened. In competition with a cap analog, 7-methylguanosine 5′-monophosphate, embryo mRNA translation was inhibited more than oocyte at low concentrations of analog. These results are taken to indicate that the lack of a cap at the 5′ terminus could be one mechanism to inhibit translation prior to fertilization.