Delayed accumulation of maternal histone mRNA during sea urchin oogenesis

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.

The sea urchin stem-loop-binding protein: a maternally expressed protein that probably functions in expression of multiple classes of histone mRNA

Following the completion of oogenesis and oocyte maturation, histone mRNAs are synthesized and stored in the sea urchin egg pronucleus. Histone mRNAs are the only mRNAs that are not polyadenylated but instead end in a stem-loop which has been conserved in evolution. The 3' end binds the stem-loop-binding protein (SLBP), and SLBP is required for histone pre-mRNA processing as well as translation of the histone mRNAs. A cDNA encoding a 59 kDa sea urchin SLBP (suSLBP) has been cloned from an oocyte cDNA library. The suSLBP contains an RNA-binding domain that is similar to the RNA-binding domain found in SLBPs from other species, although there is no similarity between the rest of the suSLBP and other SLBPs. The suSLBP is present at constant levels in eggs and for the first 12 h of development. The levels of suSLBP then decline and remain at a low level for the rest of embryogenesis. The suSLBP is concentrated in the egg pronucleus and is released from the nucleus only when cells enter the first mitosis. SuSLBP expressed by in vitro translation does not bind the stem-loop RNA, suggesting that suSLBP is modified to activate RNA binding in sea urchin embryos.

Novel localization and possible functions of cyclin E in early sea urchin development

In somatic cells, cyclin E-cdk2 activity oscillates during the cell cycle and is required for the regulation of the G1/S transition. Cyclin E and its associated kinase activity remain constant throughout early sea urchin embryogenesis, consistent with reports from studies using several other embryonic systems. Here we have expanded these studies and show that cyclin E rapidly and selectively enters the sperm head after fertilization and remains concentrated in the male pronucleus until pronuclear fusion, at which time it disperses throughout the zygotic nucleus. We also show that cyclin E is not concentrated at the centrosomes but is associated with condensed chromosomes throughout mitosis for at least the first four cell cycles. Isolated mitotic spindles are enriched for cyclin E and cdk2, which are localized to the chromosomes. The chromosomal cyclin E is associated with active kinase during mitosis. We propose that cyclin E may play a role in the remodeling of the sperm head and re-licensing of the paternal genome after fertilization. Furthermore, cyclin E does not need to be degraded or dissociated from the chromosomes during mitosis; instead, it may be required on chromosomes during mitosis to immediately initiate the next round of DNA replication.

Ontogeny of placental lactogen-I and placental lactogen-II expression in the developing rat placenta

The purpose of this investigation was to identify the cellular origin, and the temporal and regional characteristics of placental lactogen-I (PL-I) and placental lactogen-II (PL-II) expression during placental development in the rat. PL-I and PL-II mRNA expression were assessed by Northern blot analysis and in situ hybridization. PL-I and PL-II protein expression were determined by Western blot and immunocytochemical analyses. PL-I mRNA was first detected by in situ hybridization at Day 6 of gestation in mural trophoblast giant cells and a day later, PL-I protein was first detected by immunocytochemistry. PL-I immunostaining extended to the polar trophoblast giant cells as gestation advanced. Polar trophoblast giant cell staining for PL-I was not as intense as the mural trophoblast giant cell staining. Northern and Western blot analyses confirmed the asymmetric distribution of PL-I expression. PL-I mRNA migrated as a 1-kb species and PL-I protein migrated as 30- and 36-40-kDa forms. PL-I expression abruptly declined at Day 12, and by Day 13, PL-I was not detectable. PL-II protein was first detectable at Day 11 of gestation and was localized to trophoblast giant cells. PL-II mRNA could be detected at Day 10 of gestation. Northern and Western blot analyses indicated that PL-II expression significantly increased as gestation advanced and that PL-II expression was asymmetrically distributed similar to PL-I. PL-II mRNA migrated as a 1-kb species and PL-II protein migrated as a 25-kDa species. Blastocysts recovered on Day 4 of gestation initially showed no detectable expression of PL-I or PL-II; however, after 2 days of culture PL-I protein expression was detectable. Biochemical characteristics of PL-I synthesized and secreted by blastocyst outgrowths were similar to PL-I synthesized and secreted by Day 10 placental explants. In summary, (1) PL-I and PL-II are produced by trophoblast giant cells of the developing placenta, (2) PL-I and PL-II exhibit distinct temporal and regional patterns of expression during placental morphogenesis, and (3) PL-I expression by blastocyst outgrowths can be induced in vitro, whereas a more complex array of signals appears necessary for induction of PL-II expression.

Cadmium teratogenicity and its relationship with metallothionein gene expression in midgestation mouse embryos

As an approach toward understanding the mechanisms by which cadmium (Cd) exerts its teratogenic effects, the expression and metal regulation of the metallothionein (MT) genes in midgestation mouse embryos were studied by Northern blot and in situ hybridization. Maternal injection of a teratogenic dosage of Cd (50 mumol Cd/kg body wt) did not induce MT mRNA in day 10 (D10) CD-1 mouse embryos, whereas zinc (Zn) (50 mumol/kg was an effective inducer. In contrast, Cd was about 10-fold more potent than Zn at rapidly inducing MT mRNA in D10 embryos incubated in vitro in medium containing micromolar concentrations of these metals. This suggests that following maternal injection, Cd but not Zn is prevented from reaching the D10 embryo and establishes that the embryonic MT genes are not refractory to metal induction, which might have explained the sensitivity of the embryo to Cd. MT mRNA was detected at high levels only in the extraembryonic membranes of D9 embryos exposed to Cd in vivo. On days 9 and 10, no embryonic cell types contained detectable levels of MT mRNA. This mRNA was detected first at low levels in hepatocytes on D11, soon after formation of liver and these levels increased dramatically by D12. Therefore, Cd teratogenicity was not associated with high levels of cell type-specific expression of the MT genes in Cd-sensitive regions of the embryo (neural tube, limb bud), that might have served to target Cd to these cells. Taken together, the results of this study suggest that Cd teratogenicity reflects damage to maternal or extraembryonic tissues. However, the results cannot exclude the possibility that certain cells in the embryo are exceptionally sensitive to low levels of Cd.

Expression of six mitochondrial genes during Drosophila oogenesis: analysis by in situ hybridization

We have done a comparative analysis of RNA from six mitochondrial genes (rDNA, ND2, COI, COIII, ND4-ND5, Cyt b) during Drosophila oogenesis, using in situ hybridization. This study showed the same variation for each of these transcripts, which is similar to that obtained with the total mitochondrial RNA (Tourmente et al. (1990) Biol. Cell 60, 119-127). A constant RNA density until stage 9, followed by a rapid decline, was observed in follicle and nurse cells. These results confirm those previously obtained (Tourmente et al., (1990) Biol. Cell 60, 119-127), in favor of the existence of a correlation between the mtRNA level and the cell volume and/or the nuclear DNA content, and suggest a global extra-mitochondrial, transcriptional control mechanism. We also show that the relative proportions of the different RNA are similar, whatever the stage and cell type examined, even though the total mtRNA quantity is different. They are comparable to those previously obtained by Northern analysis of Drosophila embryos (Berthier et al. (1986) Nucleic Acids Res. 14, 1400-1412, suggesting a posttranscriptional control independent of the cell type. Surprisingly, we have detected an extra-mitochondrial hybridization for COIII, both in light and electron microscopy. Northern analysis of poly(A)+RNA from ovaries or cultured cells revealed an 1.7 kb extra-mitochondrial RNA, which is probably of nuclear origin.

Protamine 3'-untranslated sequences regulate temporal translational control and subcellular localization of growth hormone in spermatids of transgenic mice

Although the mouse protamine 1 gene (mP1) is first transcribed in round spermatids, its mRNA is not translated until about 1 week later in elongating spermatids. To determine what mP1 sequences are important for its transcriptional and translational regulation, we have constructed fusions between mP1 and the human growth hormone (hGH) structural gene and analyzed their expression in transgenic mice. We show that mP1 sequences 5' to the start of transcription are sufficient to confer spermatid-specific expression on the hGH gene. We also show that 156 nucleotides of mP1 3'-untranslated sequence is sufficient to confer mP1-like translational regulation on the hGH mRNA. Interestingly, the subcellular localization of hGH was dependent on the time during spermiogenesis that it was made. Synthesis of hGH in early round spermatids resulted in localization in the acrosome, whereas synthesis in late elongating spermatids resulted in intracellular, but not acrosomal, localization.

Histone H4 mRNA is stored as a small cytoplasmic RNP during the G2 phase in Physarum polycephalum

In Physarum polycephalum the triggering of histone H4 gene transcription occurs in G2 phase. The rate of synthesis of histone H4 mRNA was measured by in vivo pulse-labeling experiments. We show that it begins to increase in mid-G2. During the second part of G2 it increases approximately 20 fold over its minimum value and reaches a maximum at the end of G2. After entry of the cells in S, histone H4 gene transcription rate begins to decrease and reaches a minimum value in early G2. The histone H4 mRNA which accumulates in G2 is not translated immediately into proteins but is stored in an inactive form until the beginning of the next S phase. Immediately after its transcription the H4 mRNA is transported to the cytoplasm where it is stored and stabilized as an inactive mRNP complex. This was shown by fractionation of cytoplasmic RNP in sucrose gradients and blot hybridization of subcellular fractions.

Developmental regulation of micro-injected histone genes in sea urchin embryos

The developmental behavior of cloned histone genes of Psammechinus miliaris was studied by injection into eggs of two related sea urchin species followed by fertilization. All five early histone genes were faithfully expressed in early blastula embryos as shown by SP6 RNA mapping. A 5-10 times lower expression rate was estimated for the injected early H2A gene from its competition strength with the endogenous gene. Transcripts of this early H2A gene accumulated during the cleavage stages and decayed in late embryos in parallel with the endogenous early H2A mRNA. However, an introduced late H2B gene was incorrectly regulated, since its mRNA level did not increase from the blastula to the gastrula stage. The sperm H2B-1 gene, normally inactive in development, was 80 times less well expressed than the early H2A gene in transformed blastulae. A fusion gene with the early H2A promoter linked to the structural sperm H2B gene was, however, efficiently transcribed suggesting that all essential information for an early expression pattern is contained within the 5' region of the early H2A gene.

Brugia malayi: recombinant antigens expressed by genomic DNA clones

A Brugia malayi genomic DNA expression library was screened with rabbit antiserum generated against live infective larvae and 33 clones were identified. Five randomly selected clones were characterized in detail by Western blot, DNA and RNA analyses. The fusion proteins produced by each of these recombinant DNA clones are expressed by different genomic sequences. A profile of antigenic cross-reactivities of all 33 recombinant clones was compiled using a battery of antisera, including sera from humans infected with B. malayi. A high percentage of clones were cross-reactive with antisera against the filarial parasites B. pahangi, Dirofilaria immitis, and Onchocerca volvulus. We have made a preliminary identification of three categories of recombinant clones encoding (1) antigens that were cross-reactive with some or all antisera tested, (2) antigens that were specific to the Brugia genus, and (3) antigens that appeared to be specific to B. malayi. These recombinant antigens are candidates for further studies in filarial immunoprophylaxis and diagnosis.

Three translationally regulated mRNAs are stored in the cytoplasm of clam oocytes

In situ hybridization was used to examine the spatial distributions of three translationally controlled maternal RNAs in oocytes and two-cell embryos of the clam Spisula. 3H-labeled single-stranded RNA probes were generated from SP6 recombinant clones containing DNA inserts encoding portions of histone H3 (the DNA sequence which is presented here), cyclin A, and the small subunit of ribonucleotide reductase. Hybridization of these probes to oocytes, in which the mRNAs are translationally inactive, shows that these mRNAs are stored in the cytoplasm. There is no evidence for sequestration of any of the RNAs within the nucleus or any other discrete structure. Instead they appear to be evenly distributed throughout the cytoplasm.

Translation of maternal histone mRNAs in sea urchin embryos: a test of control by 5' cap methylation

Recent results have demonstrated the occurrence of mRNA cap methylation in the sea urchin embryo following fertilization. It has been suggested that this methylation event is responsible for the translational activation of maternal histone mRNAs in these embryos. We have used aphidicolin, an effective inhibitor of both DNA synthesis and cap methylation in cleavage stage sea urchin embryos, to examine the relationship between cap methylation and translation. At 5 micrograms/ml, a dose which rapidly abolishes DNA replication and blocks cleavage, we note no effect on recruitment or translation of maternal alpha-subtype histone mRNAs. This suggests that a postfertilization cap methylation event is not critical to the process of regulation of the translation of stored alpha-subtype histone mRNAs.

Isolation, characterization, and expression of the gene encoding the late histone subtype H1-gamma of the sea urchin Strongylocentrotus purpuratus

We cloned and characterized the gene encoding H1-gamma, a late histone subtype of the sea urchin species Strongylocentrotus purpuratus. The predicted primary sequence of H1-gamma is 216 amino acids in length and has a net charge of +70, which is high for a somatic H1 histone. The H1-gamma gene appears to be a unique sequence gene that is not tightly linked to the core histone genes. The 770-base-pair transcribed region of the H1-gamma gene is bordered on the 5' side by two previously described H1-specific sequence elements and on the 3' side by a hairpin loop structure and CAGA box sequences. We detected 3,900 stored maternal H1-gamma mRNA transcripts per egg. The number of H1-gamma transcripts per embryo rises by 9.5 h postfertilization, but the maximum rate of accumulation (4,300 molecules per min per embryo) occurs in the late-blastula-stage embryo between 14 and 21 h after fertilization. The number of H1-gamma mRNA molecules peaks 21 h after fertilization when there are 2.0 X 10(6) molecules per embryo (a 500-fold increase) and then decreases over the next 3.25 h to 1.3 million molecules per embryo. Between 24 and 82 h after fertilization the number of H1-gamma transcripts declines steadily (210 molecules per min per embryo) to reach approximately 5.4 X 10(5) H1-gamma mRNAs by 82 h postfertilization. Surprisingly, the number of late H1 mRNA molecules per embryo is greater than the number of late H2B mRNA molecules beginning at the early gastrula stage of development.

Characterization of two nonallelic pairs of late histone H2A and H2B genes of the sea urchin: differential regulation in the embryo and tissue-specific expression in the adult

Two nonallelic pairs of late H2A and H2B genes of the sea urchin Psammechinus miliaris were isolated on two different cosmid clones. The genes of cosmid PmL1 are separated by 11 kilobases of DNA and code for the late H2A-2 and H2B-2 variants. The genes of clone PmL2 are divergently transcribed with 1,060 base pairs of intergenic spacer DNA and code for novel variants of the H2A-2 and H2B-2 type. A comparison of the promoter sequences revealed little homology upstream of the TATA box with the exception of a 24-base-pair-long conserved sequence which is present at the same position in both late H2B promoters and part of which is identical with the "H2B-specific" 5' element. The mRNAs of the H2A and H2B genes of cosmid PmL1 reach their maximal levels early in the mesenchyme blastula embryo, whereas the transcripts of both genes of clone PmL2 accumulate maximally only later in the pluteus larva. In the adult sea urchin all four mRNAs are present in the tube foot but not in the intestine and lantern muscle. This pattern of differential expression in the embryo and tissue-specific expression in the adult suggests cell lineage-specific regulation of the late H2A-2 and H2B-2 genes. Another class of late histone genes represented by the H2A-3 and H2B-1 genes was shown to be expressed in all three adult tissues tested, whereas transcripts of the late H2A-1 genes could not be detected, suggesting that these genes are active exclusively during sea urchin development.

Isolation, characterization, and expression of the gene encoding the late histone subtype H1-gamma of the sea urchin Strongylocentrotus purpuratus

We cloned and characterized the gene encoding H1-gamma, a late histone subtype of the sea urchin species Strongylocentrotus purpuratus. The predicted primary sequence of H1-gamma is 216 amino acids in length and has a net charge of +70, which is high for a somatic H1 histone. The H1-gamma gene appears to be a unique sequence gene that is not tightly linked to the core histone genes. The 770-base-pair transcribed region of the H1-gamma gene is bordered on the 5' side by two previously described H1-specific sequence elements and on the 3' side by a hairpin loop structure and CAGA box sequences. We detected 3,900 stored maternal H1-gamma mRNA transcripts per egg. The number of H1-gamma transcripts per embryo rises by 9.5 h postfertilization, but the maximum rate of accumulation (4,300 molecules per min per embryo) occurs in the late-blastula-stage embryo between 14 and 21 h after fertilization. The number of H1-gamma mRNA molecules peaks 21 h after fertilization when there are 2.0 X 10(6) molecules per embryo (a 500-fold increase) and then decreases over the next 3.25 h to 1.3 million molecules per embryo. Between 24 and 82 h after fertilization the number of H1-gamma transcripts declines steadily (210 molecules per min per embryo) to reach approximately 5.4 X 10(5) H1-gamma mRNAs by 82 h postfertilization. Surprisingly, the number of late H1 mRNA molecules per embryo is greater than the number of late H2B mRNA molecules beginning at the early gastrula stage of development.

Characterization of two nonallelic pairs of late histone H2A and H2B genes of the sea urchin: differential regulation in the embryo and tissue-specific expression in the adult

Two nonallelic pairs of late H2A and H2B genes of the sea urchin Psammechinus miliaris were isolated on two different cosmid clones. The genes of cosmid PmL1 are separated by 11 kilobases of DNA and code for the late H2A-2 and H2B-2 variants. The genes of clone PmL2 are divergently transcribed with 1,060 base pairs of intergenic spacer DNA and code for novel variants of the H2A-2 and H2B-2 type. A comparison of the promoter sequences revealed little homology upstream of the TATA box with the exception of a 24-base-pair-long conserved sequence which is present at the same position in both late H2B promoters and part of which is identical with the "H2B-specific" 5' element. The mRNAs of the H2A and H2B genes of cosmid PmL1 reach their maximal levels early in the mesenchyme blastula embryo, whereas the transcripts of both genes of clone PmL2 accumulate maximally only later in the pluteus larva. In the adult sea urchin all four mRNAs are present in the tube foot but not in the intestine and lantern muscle. This pattern of differential expression in the embryo and tissue-specific expression in the adult suggests cell lineage-specific regulation of the late H2A-2 and H2B-2 genes. Another class of late histone genes represented by the H2A-3 and H2B-1 genes was shown to be expressed in all three adult tissues tested, whereas transcripts of the late H2A-1 genes could not be detected, suggesting that these genes are active exclusively during sea urchin development.

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.

The role of cap methylation in the translational activation of stored maternal histone mRNA in sea urchin embryos

Cap methylation was examined in the early sea urchin embryo. Nucleotide analyses of 3H-methyl methionine-labeled RNA in two-cell embryos and in unfertilized eggs show that fertilization activates the cap methylation of about 10(7) RNA molecules. Greater than 37% of methyl-labeled RNAs following fertilization hybridize with so-called early histone genes H1, H4, and H2B, which encode a subpopulation of the maternal mRNA molecules. Activation of RNA cap methylation is inhibited by aphidicolin, but not by actinomycin D, suggesting that this process is temporally coordinated with DNA replication, but independent of RNA transcription. These results indicate that the translational activation of maternal early histone mRNA during fertilization is a consequence of cap methylation of mRNAs incompletely formed during oogenesis.

Biphasic pattern of histone gene expression during Drosophila oogenesis

The expression of histone genes during Drosophila oogenesis was compared to periods of DNA synthesis as well as to the pattern of actin gene expression. Accumulation of histone mRNAs was measured by RNA blot hybridization. Relatively low levels of histone mRNAs are present in egg chambers prior to stage 10, during the period of nurse and follicle cell polyploidization. Surprisingly, histone mRNAs accumulate rapidly and selectively after stage 10, coinciding with the onset of nurse cell degeneration and well after DNA synthesis and actin mRNA accumulation have ceased. A large proportion of the histone mRNAs is associated with polysomes at all times, indicating that expression of histone genes is not strictly coupled to DNA synthesis. The burst of histone mRNA accumulation near the end of oogenesis may provide a store of maternal histone mRNA to support the rapid cleavages that occur during early embryogenesis. These and previous results suggest that genes are independently regulated during differentiation of the Drosophila egg chamber.

Informational content of the echinoderm egg

The sea urchin egg contains a store of mRNA synthesized during oogenesis but translated only after fertilization, which accounts for a large, rapid increase in the rate of synthesis of largely the same set of proteins synthesized by eggs. Starfish oocytes contain a population of stored maternal mRNA that becomes actively translated upon GVBD and codes for a set of proteins distinct from that synthesized by oocytes. The sequence complexity of RNA in echinoderm eggs is about 3.5 x 10(8) nucleotides, enough to code for about 12,000 different mRNAs averaging 3 kb in length. About 2-4% of the egg RNA functions as mRNA during early embryonic development; most of the sequences are rare, represented in a few thousand copies per egg, but some are considerably more abundant. Many of the stored RNA sequences accumulate during the period of vitellogenesis, which lasts a few weeks. The mechanisms of storage and translational activation of maternal mRNA are not well understood. Histone mRNAs are sequested in the egg pronucleus until first cleavage, but other mRNAs are widely distributed in the cytoplasm. The population of maternal RNA includes many very large molecules having interspersed repetitive sequence transcripts colinear with single-copy sequences. The structural features of much of the cytoplasmic maternal RNA is thus reminiscent of incompletely processed nuclear precursors of mRNA. The functional role of these strange molecules is not understood, but many interesting possibilities have been considered. For instance, they may be segregated into different cell lineages during cleavage and/or they may become translationally activated by selective processing during development. Maternal mRNA appears to be underloaded with ribosomes when translated, possibly because the coding sequences are short relative to the size of the mRNA. Most abundant and many rare mRNA sequences persist during embryonic development. The rare sequence molecules are replaced by newly synthesized RNA, but some abundant maternal transcripts appear to persist throughout embryonic development. Most of the proteins present in the egg do not change significantly in mass during development, but a few decline or accumulate substantially. Together, these observations indicate that much of the information for embryogenesis is stored in the egg, although substantial changes in gene expression occur during development.

Origin of a gene regulatory mechanism in the evolution of echinoderms

A rich diversity of ancient sea urchin lineages survives to the present. These include several advanced orders as well as the cidaroids, which represent the group ancestral to all other sea urchins. Here we show that all advanced groups of sea urchins examined possess in their eggs a class of maternal messenger RNA (mRNA) encoded by the evolutionarily highly conserved alpha-subtype histone genes. The maternal histone mRNAs are unique in their time of accumulation in oogenesis, their localization in the egg nucleus and their delayed timing of translation after fertilization. Cidaroid sea urchins as well as other echinoderm classes, such as starfish and sea cucumbers, possess the genes but do not have maternal alpha-subtype histone mRNAs in their eggs. Thus, although all the echinoderms examined transcribe alpha-subtype histone genes during embryogenesis, the expression of these genes as maternal mRNAs is confined to advanced sea urchins. The fossil record allows us to pinpoint the evolution of this mode of expression of alpha-histone genes to the time of the splitting of advanced sea urchin lineages from the ancestral cidaroids in a radiation which occurred in a relatively brief interval of time approximately 190-200 Myr ago. The origin of a unique gene regulatory mechanism can thus be correlated with a set of macroevolutionary events.