Patterns of protein synthesis and metabolism during sea urchin embryogenesis

Effects of sublethal Cd, Zn, and mixture exposures on antioxidant defense and oxidative stress parameters in early life stages of the purple sea urchin Strongylocentrotus purpuratus

Oxidative stress parameters were evaluated during the first 72 h of embryonic development of purple sea urchin Strongylocentrotus purpuratus continuously exposed to control conditions, to cadmium alone (Cd, 30 μg/L), to zinc alone (Zn, 9 μg/L) or to a Cd (28 μg/L) plus Zn (9 μg/L) mixture. These sublethal concentrations represent ∼ 10% of the acute EC50. Bioaccumulation, antioxidant capacity against peroxyl radicals (ACAP), total glutathione (GSH) level, glutathione-S-transferase (GST), glucose-6-phosphate dehydrogenase (G6PDH) and superoxide dismutase (SOD) activity, and lipid peroxidation (LPO) were analyzed at 24 h (blastula), 48 h (gastrula), and 72 h (pluteus) stages of development. Zinc (an essential metal) was well-regulated, whereas Cd (non-essential) bioaccumulated and whole-body [Cd] increased from blastula to pluteus stage in sea urchin larvae. In controls, ACAP progressively declined from 24 h to 72 h, while LPO reciprocally increased, but other parameters did not change. Cd alone was more potent than Zn alone as a pro-oxidant, with the major effects being decreases in SOD activity and parallel increases in LPO throughout development; GST activity also increased at 24 h. Zn alone caused only biphasic disturbances of ACAP. In all cases, the simultaneous presence of the other metal prevented the effects, and there was no instance where the oxidative stress response in the presence of the Cd/Zn mixture was greater than in the presence of either Cd or Zn alone. Therefore the sublethal effects of joint exposures were always less than additive or even protective, in agreement with classical toxicity data. Furthermore, our results indicate that SOD and Zn can play important roles in protecting sea urchin embryos against Cd-induced lipid peroxidation.

Trapping, tagging and tracking: Tools for the study of proteins during early development of the sea urchin

The exquisite synchronicity of sea urchin development provides a reliable model for studying maternal proteins in the haploid egg as well as those involved in egg activation, fertilization and early development. Sea urchin eggs are released by the millions, enabling the quantitative evaluation of maternally stored and newly synthesized proteins over a range of time (seconds to hours post fertilization). During this window of development exist many hallmark and unique biochemical interactions that can be investigated for the purpose of characterizing profiles of kinases and other signaling proteins, manipulated using pharmacology to test sufficiency and necessity, for identification of post translational modifications, and for capturing protein-protein interactions. Coupled with the fact that sea urchin eggs and embryos are transparent, this synchronicity also results in large populations of cells that can be evaluated for newly synthesized protein localization and identification through use of the Click-iT technology. We provide basic protocols for these approaches and direct readers to the appropriate literature for variations and examples.

The echinoid mitotic gradient: effect of cell size on the micromere cleavage cycle

Like other euechinoids, the fertilized eggs of the sand dollar Dendraster excentricus proceed through cleavages that produce a pattern of macromeres, mesomeres, and micromeres at the 4th division. The 8 cells of the macro-mesomere lineage proceed through 6 additional cleavages before hatching. At the fifth overall division, the 4 micromeres produce a lineage of large micromeres that will divide 3 additional times, and a lineage of small micromeres that will divide once more before hatching. Irrespective of lineage, the length of the cell cycles is closely related to the size of the blastomere; cells of the same size have the same cell cycle time. A consequence is that at the fourth cleavage, there is a gradient of mitotic activity from the fastest dividers at the animal pole and the slowest cleaving micromeres at the vegetal pole. By the time of hatching, which is the 10th division of meso-macromeres, all cells are the same small size, the metachronic pattern of division gives way to asynchrony, and the mitotic gradient along the polar axis is lost. Experimental pre-exposure to sodium dodecyl sulfate (SDS), however, blocks the appearance of the gradients in cell size, the mitotic gradient, and the differential in cell cycle times. It is proposed that the mitotic gradients, cell cycle times, and attainment of a state of asynchrony are functions of cell size. Developmental consequences of the transition are large, and include coordinated activation of transcriptions, synthesis of new patterns of proteins, alterations of metabolism, and onset of morphogenesis.

Soluble tubulin complexes, γ-tubulin, and their changing distribution in the zebrafish (Danio rerio) ovary, oocyte and embryo

Tubulin dynamics, i.e., the interchange of polymeric and soluble forms, is important for microtubule (MTs) cellular functions, and thus plays essential roles in zebrafish oogenesis and embryogenesis. A novel finding in this study revealed that there were soluble pools of tubulins in zebrafish oocytes that were sequestered and maintained in a temporary "oligomeric" state, which retained assembling and disassembling potential (suggested by undetected acetylated tubulin, marker of stable tubulin), but lacked abilities to assemble into MTs spontaneously in vivo. Using differential centrifugation, gel chromatography and DM1A-probed western blot, soluble alpha-tubulin was found to be associated with large molecular weight complexes (MW range to over 2 MDa) which were reduced in amount by the blastula stage, especially in some batches of embryos, with a concomitant decrease in soluble tubulin. Complexes (MW range less than 2 MDa) then increased in the gastrula with an increase in soluble alpha-tubulin. Two different anti-gamma-tubulin monoclonal antibodies, GTU 88 and TU 30, revealed the existence of soluble gamma-tubulin in both zebrafish oocytes and embryos, which also decreased by the blastula stage and increased in the gastrula stage. Soluble alpha-tubulin and gamma-tubulin extracted from zebrafish ovaries, oocytes and embryos co-localized in fractions on three different columns: S-200 Sephacryl, DEAE and Superose-6b. The soluble tubulin complexes were competent to assemble into MTs in vitro induced by taxol, and gamma-tubulin was co-localized with assembled MTs. These soluble tubulin complexes were stable during freeze-thaw cycles and resisted high ionic interaction (up to 1.5 M NaCl). Furthermore, some ovarian soluble alpha-tubulin could be co-immunoprecipitated with gamma-tubulin, and vice versa. Two antibodies specific for Xenopus gamma-tubulin ring complex proteins (Xgrip 109 and Xgrip 195) detected single bands from ovarian extracts in western blots, suggesting the existence of Xgrip 109 and Xgrip 195 homologues in zebrafish. These findings, together with recent work on gamma-tubulin ring complexes in oocytes, eggs and embryos of other species, suggest that soluble gamma-tubulin-associated protein complexes may be involved in regulating tubulin dynamics during zebrafish oogenesis and embryogenesis.

Restricted expression of the Lytechinus pictus Spec1 gene homologue in reciprocal hybrid embryos with Strongylocentrotus purpuratus

Hybrid embryos were derived from reciprocal crosses of Strongylocentrotus purpuratus and Lytechinus pictus sea urchins. The expression of proteins specific for L. pictus was restricted in these hybrid embryos, while this was not so for most proteins specific for S. purpuratus. In particular, the aboral ectoderm-specific calcium-binding protein Spec1 was expressed at normal levels in hybrid embryos, but its L. pictus homologue, LpS1, was considerably reduced. LpS1 mRNA accumulated in hybrid plutei to only 4-5% of its normal level. Transcription of the LpS1 gene was substantially reduced in hybrid embryos, as determined by a nuclear RNA run-on assay. Southern blot analysis of genomic DNA indicated that there was no detectable loss or rearrangement of LpS1 DNA in hybrid embryos. Thus, the Spec1 gene is expressed normally in hybrid embryos, but the transcription of its homologue, the LpS1 gene, is considerably restricted.

Protein synthesis and morphogenesis are not tightly linked during embryogenesis in Fucus

Fertilized eggs of the brown alga Fucus have long been used as model organisms for investigating the early events in the establishment of polarity and subsequent embryogenesis since large numbers of zygotes can easily be obtained. We have analyzed protein synthesis in eggs and embryos during the first day of development using two-dimensional gels and found that synthesis of 12 of the 60 most prominent proteins changed either qualitatively or quantitatively. Actin and beta-tubulin were identified by immunoblotting; synthesis of these cytoskeletal proteins was initiated at different times during the first 12 hr of development. Unique, reproducible patterns of protein synthesis observed during development in the light permitted accurate staging of developing embryos. Inhibitors such as cytochalasin and sucrose, however, blocked morphogenesis without affecting protein synthesis, and, conversely, growth in the dark delayed protein synthesis but had very little effect on the timing of morphogenesis. The data are consistent with morphogenesis and protein synthesis being relatively independent during early embryogenesis. Actinomycin D added soon after fertilization had no effect on protein synthesis 1 day later, indicating that the proteins analyzed were encoded by maternal mRNA stored in the egg.

Multiple levels of regulation of tubulin gene expression during sea urchin embryogenesis

The expression of the tubulin genes during embryogenesis of the sea urchin Lytechinus pictus has been analyzed. Single strand tracer excess titrations of alpha- and beta-tubulin mRNA and RNA gel blot hybridizations indicate that tubulin mRNA remains at a constant 1.3 X 10(5) transcripts per embryo during cleavage stages, increases during ciliogenesis shortly before hatching (12 hr PF), declines until midgastrula (30-35 hr PF), and then gradually increases 3-fold to about 6 X 10(5) per pluteus larva (72 hr PF). Tubulin synthesis changes in concert with its mRNA, except that during cleavage the relative rate of tubulin synthesis increases without a corresponding increase in tubulin mRNA abundance. The relative rates of tubulin gene transcription were assayed by a run-on assay in isolated nuclei. The synthesis of alpha- or beta-tubulin RNA results in little supplementation of maternal tubulin RNA during cleavage stages, but the rate increases at least 18-fold during ciliogenesis and then gradually decreases thereafter. The accumulation of tubulin mRNA after gastrulation can be accounted for by an ontogenetic increase in tubulin RNA stability, assayed by actinomycin D chase and RNA gel blot hybridization. The rates of synthesis, stabilities, and abundances of alpha- and beta-tubulin mRNAs were similar, suggesting coordinate regulation. These observations indicate the importance of translational regulation during cleavage, transcriptional regulation during ciliogenesis, and regulation of mRNA stability by the level of unpolymerized tubulin during later development.

Spec2 genes of Strongylocentrotus purpuratus. Structure and differential expression in embryonic aboral ectoderm cells

Members of the Spec gene family are expressed during embryonic development of the sea urchin, Strongylocentrotus purpuratus. The family encodes proteins related to the calmodulin/troponin C/myosin light chain group of calcium binding proteins and one gene, Spec1, has been studied extensively in our laboratory. In this paper, we analyze other members of the family, collectively termed Spec2 genes. We make use of several hybridization probes derived from Spec1 and Spec2 cDNA clones, which recognize different members of the family. Genomic DNA gel blot and slot blot analyses show that there are approximately eight Spec genes in the S. purpuratus genome. The structures of three Spec2 genes, Spec2a, Spec2c and Spec2d, are described. A 60 kb (kb = 10(3) bases or base-pairs) region of the genome contains the linked Spec1-Spec2c genes and two separate 20 kb regions contain the Spec2a and Spec2d genes. Six members of a repetitive sequence family are dispersed at various locations among the genes. The transcriptional initiation sites of the three Spec2 genes are mapped, and 400 to 500 base-pairs of 5'-flanking DNA sequenced. All three Spec2 genes initiate transcription approximately 120 base-pairs upstream from the 3' end of the first exon. In contrast, the 5' end of the Spec1 transcript begins about 107 base-pairs farther upstream, so it contains 5' untranslated sequences that correspond to non-transcribed 5'-flanking sequences of the Spec2 genes. There is little similarity among the sequences upstream from the CAP site of the Spec2 genes except the TATA consensus sequence and a repeating trinucleotide, AAC. Measurements of Spec mRNA levels during embryogenesis show that Spec1 mRNA begins to accumulate at the early blastula stage and is the most abundant; Spec2a/Spec2c mRNAs begin accumulating several hours later at the late blastula-early gastrula stage and reach about 40 to 60% the levels of Spec1; and Spec2d mRNAs accumulate mostly during the gastrula and pluteus stages with levels reaching only 2% those of Spec1. In situ hybridization with probes that recognize either all Spec2 mRNAs or only Spec2d mRNAs show that, like Spec1, these mRNAs are restricted to aboral ectoderm cells and their precursors. The Spec gene family represents a group of related genes whose mRNAs all accumulate in the same cell type but at different times and to different levels during embryogenesis.

Stimulation of tubulin gene transcription by deciliation of sea urchin embryos

Deciliation by hypertonic shock of embryos of the sea urchin Lytechinus pictus resulted in an increase in synthesis of alpha- and beta-tubulins, the consequence of an increased concentration of RNA encoding the tubulins. RNA run-on assays in isolated nuclei indicated that this response is due to a transient increase in the rate of synthesis of tubulin RNA beginning within 5 min of deciliation. This enhancement of tubulin gene transcription also occurred in deciliated embryos treated with the microtubule-depolymerizing agent colcemid; thus the reaction to deciliation is not a response to a reduction in concentration of unpolymerized tubulin utilized for ciliogenesis. In deciliated embryos treated with colcemid, the elevated level of tubulin RNA declined rapidly, due to its destabilization by the elevated concentration of unpolymerized tubulin. The increased transcription of tubulin genes is a response to the loss of cilia, not to the hypertonic shock, and occurs even when cilium regeneration is prevented. Inhibition of protein synthesis with puromycin or emetine did not prevent the transcriptional enhancement but stabilized tubulin mRNA, resulting in increased accumulation of tubulin mRNA after deciliation.

The jellyfish and its polyp: a comparative study of gene expression monitored by the protein patterns, using two-dimensional gels with double-label autoradiography

The life cycle of Podocoryne carnea (Coelenterata, Anthomedusae) shows several distinct stages which differ considerably in terms of their ecology, morphology, cellular composition, and ultrastructure. Previously these stages had even been described as separate species. Using two-dimensional gel electrophoresis and a new method of double-label autoradiography, we show here for the first time for metagenic hydrozoans that only minor differences in gene expression exist between the various life cycle stages. Our results demonstrate the high resolution power of these techniques and show that the different life stages of P. carnea remain rather similar on the protein level. Most of the prominent spots of the two-dimensional gel protein patterns are common to all stages studied. These data show that the hydrozoan life cycle and development are regulated by only minor distinctions in gene expression which possibly explains the great morphogenetic repertoire of these animals described in many studies.

Coordinate accumulation of five transcripts in the primary mesenchyme during skeletogenesis in the sea urchin embryo

The sea urchin larval skeleton is produced by the primary mesenchyme (PM), a group of 32 cells descended from the four micromeres of the 16-cell embryo. The development of this lineage proceeds normally in isolated cultures of micromeres. A complementary DNA (cDNA) library was generated from cytoplasmic polyadenylated RNA isolated from differentiated micromere cultures of Strongylocentrotus purpuratus. Five clones were selected on the basis of their enrichment in differentiated PM cell RNA as compared to the polyribosomal RNAs of other embryonic cell types and other developmental stages. Each cloned cDNA hybridized to a distinct RNA that was abundant in the polyribosomes of differentiated PM cells, but absent from larval ectoderm and from 16-cell embryos. These RNAs were encoded by single or low copy genes. In situ hybridization analysis of the most abundant of these RNAs (SpLM 18) demonstrated that it was specifically limited to the skeletogenic PM of intact embryos. During the development of the PM, all five RNAs exhibited the same schedule of accumulation, appearing de novo, or increasing abruptly just before PM ingression, and remaining at relatively high levels thereafter. This pattern of RNA accumulation closely paralleled the pattern of synthesis of PM-specific proteins in general (Harkey and Whiteley, 1983) and of the SpLM 18-encoded protein specifically (Leaf et al., 1987). These results indicate that at least five distinct genes in the sea urchin, each of which encodes a PM-enriched or PM-specific mRNA, are expressed with tight coordination during development of the larval skeleton. They also demonstrate that expression of these genes in the PM is regulated primarily at the level of RNA abundance rather than RNA utilization.

Microtubule formation from maternal tubulins during sea urchin embryogenesis: measurement of soluble and insoluble tubulin pools

The mass of tubulin protein in developing embryos of the sea urchin Lytechinus pictus was measured using a radiodilution immunoassay based on densitometric analysis of immunoprecipitated tubulins resolved electrophoretically. The tubulins constitute an average of 360 +/- 35 pg per egg, or 0.66% of the total protein, and there is no significant change in their concentration during embryogenesis. The masses of soluble and polymerized tubulin were measured for extracts prepared under conditions that stabilize microtubules. In eggs, a maximum of 14% of the tubulin is insoluble, and this increases throughout embryogenesis to 67% at pluteus stage (72 hr). The concentration of tubulin in eggs is at least 500 micrograms/ml, well above the critical concentration for tubulin assembly in vitro, yet microtubules have not been observed in eggs. The mass of newly synthesized tubulin, estimated from the mass of tubulin mRNA per embryo, accounts for a small fraction of the total tubulin by the end of gastrulation but for over half of the tubulin by the 72-hr pluteus stage. These observations are consistent with a model in which the declining level of unpolymerized tubulin controls the stability of tubulin mRNa, providing an autogenous regulation of the ontogenetic pattern of tubulin synthesis during sea urchin embryogenesis (Gong and Brandhorst, Development 102: 31-43).

Regulation of actin gene expression during sea urchin development

The progress that has been made in the last several years toward an understanding of the expression of the actin genes of the sea urchin is impressive. It serves as an excellent example of how the application of modern molecular biological techniques to a classic experimental system (the sea urchin embryo) can begin to give us insight into the processes of embryological development. There is reason to hope that general principles will emerge from studies such as these, but many questions are unanswered. With specific regard to the actin genes and proteins, there are some obvious questions. Are the actins encoded by the different genes functionally distinct, and what roles do they play in differentiation and development? How is the expression of each of these genes regulated; i.e., what molecules participate, how do they work, where are they located in the embryo, and when do they appear? The more general question is: How are these (and other) genes and proteins affected by, or how do they contribute to, determination and induction in early development? We hope that answers to the specific questions posed will provide important steps toward answers to the general question.

Stimulation of tubulin gene transcription by deciliation of sea urchin embryos

Deciliation by hypertonic shock of embryos of the sea urchin Lytechinus pictus resulted in an increase in synthesis of alpha- and beta-tubulins, the consequence of an increased concentration of RNA encoding the tubulins. RNA run-on assays in isolated nuclei indicated that this response is due to a transient increase in the rate of synthesis of tubulin RNA beginning within 5 min of deciliation. This enhancement of tubulin gene transcription also occurred in deciliated embryos treated with the microtubule-depolymerizing agent colcemid; thus the reaction to deciliation is not a response to a reduction in concentration of unpolymerized tubulin utilized for ciliogenesis. In deciliated embryos treated with colcemid, the elevated level of tubulin RNA declined rapidly, due to its destabilization by the elevated concentration of unpolymerized tubulin. The increased transcription of tubulin genes is a response to the loss of cilia, not to the hypertonic shock, and occurs even when cilium regeneration is prevented. Inhibition of protein synthesis with puromycin or emetine did not prevent the transcriptional enhancement but stabilized tubulin mRNA, resulting in increased accumulation of tubulin mRNA after deciliation.

Spec3: embryonic expression of a sea urchin gene whose product is involved in ectodermal ciliogenesis

We have characterized the temporal and spatial expression of Spec3 mRNA in embryos of the sea urchin, Strongylocentrotus purpuratus. This mRNA, 2.0 kb in length, is present at low levels in unfertilized eggs but accumulates rapidly during cleavage, increasing 50-fold by hatching blastula stage. Message levels then decline abruptly, remain constant during mesenchyme blastula and gastrula stages, and increase again during prism and pluteus stages. This accumulation pattern is quite similar to that of the ectodermally expressed beta-tubulin mRNAs described recently by Harlow and Nemer (1987a). In situ hybridization shows that although Spec3 message accumulates in all blastomeres at early blastula stages, it later becomes restricted to ectoderm. By late blastula stage, hybridization is strongest in the animal hemisphere. At gastrula, signals are variable over ectoderm, and by pluteus, grains are concentrated in the ciliary band, though present in other ectodermal cells as well. Deciliation and regeneration of cilia in gastrula-stage embryos results in a four- to fivefold increase in Spec3 mRNA levels, implying that the Spec3 gene product is associated with ciliogenesis. Spec3 mRNA is encoded by a single gene in the haploid genome, and characterization of the gene shows that it contains three exons that encode an open reading frame for a hydrophobic protein of 21.6 kD. The reading frame reveals that the carboxy-terminal part of the protein contains two long hydrophobic stretches, 31 and 37 residues long, separated by short hydrophilic regions of six to eight residues. The presence of these two distinct hydrophobic stretches suggests that the Spec3 protein contains two alpha-helical domains that either span the lipid bilayer or are associated with some other hydrophobic environment.

Changes in the synthesis and intracellular localization of nuclear proteins during embryogenesis in the sea urchin Strongylocentrotus purpuratus

A rapid, gentle technique is described for the isolation of nuclei from sea urchin embryos. Using this technique, we have analyzed the synthesis and accumulation of nonhistone nuclear proteins during sea urchin development by two-dimensional gel electrophoresis. Most nuclear proteins fall into one of three patterns of synthesis, which are distinguished by maximal rates of accumulation at early (prior to hatching blastula), middle (hatching blastula/gastrula), or late (prism/pluteus) stages of development. Over 60% of observed nuclear proteins undergo apparent qualitative changes in synthesis and accumulation between the 64-cell and pluteus stages. Most of these changes represent appearances of new proteins. A large number of qualitative changes occur very early in development; the period of greatest change is between the 64-cell and 200-cell stages. Over half of the proteins which first appear in the nucleus subsequent to the 64-cell stage are synthesized at stages prior to the time of their initial appearance in nuclei, but are excluded from nuclei for some time.

Repression of quiescence-specific polypeptides in chicken heart mesenchymal cells transformed by Rous sarcoma virus

Chicken heart mesenchymal cells do not proliferate in medium of physiological composition containing plasma (S. Balk, Proc. Natl. Acad. Sci. USA 77:6606-6610, 1980). To understand the molecular events involved in cell quiescence and in the initiation of cell division under physiological conditions, we examined the differences in the patterns of protein synthesis of quiescent, hormone-stimulated, and Rous sarcoma virus-transformed chicken heart mesenchymal cells. We describe the expression of a 20,000-kilodalton (kDa) polypeptide actively synthesized by quiescent cells but not by their transformed counterparts. Normal chicken heart mesenchymal cells stimulated with epidermal growth factor and insulin also repressed the synthesis of the 20,000-kDa polypeptide while actively growing but synthesized increasing amounts of the protein at high cell density (confluence). The synthesis of the 20,000-kDa protein is not restricted to chicken heart mesenchymal cells, since confluent, density-arrested chicken embryo fibroblasts also expressed high levels of the protein. Transformed chicken heart mesenchymal cells and embryo fibroblasts did not synthesize the protein even at high cell density. The 20,000-kDa polypeptide accumulated in the culture medium.

Post-transcriptional restriction of gene expression in sea urchin interspecies hybrid embryos

The synthesis of many paternal species-specific proteins is reduced in all stages of sea urchin interspecies hybrid embryos, due to the reduced amounts of some paternal mRNA species in hybrid embryos compared with the embryos of the paternal species (Tufaro and Brandhorst 1982). Possible explanations for this restriction were tested. Cloned cDNAs were selected that were specific for paternal RNA sequences having reduced amounts (to 2-20% of normal) in hybrid embryos derived from a cross of Stronglyocentrotus purpuratus eggs with Lytechinus pictus sperm. Several of these RNA species are barely detectable in the eggs, but they accumulate extensively (5- to 40-fold) during L. pictus embryogenesis. Thus, the restricted expression of these paternal genes in hybrid embryos is not the result of the persistence of stable maternal mRNA species stored in eggs and not replaced by zygotic transcription. The accumulation of some of these L. pictus transcripts is also reduced in the reciprocal cross (L. pictus eggs X S. purpuratus sperm); therefore, the full expression of these L. pictus genes in hybrid embryos is not dependent on species-specific maternal factors stored in the egg. The transcriptional activity of one such gene was estimated using a run-on assay in isolated nuclei; it is as actively transcribed in hybrid as it is in homospecific embryos, but in hybrid embryos the cytoplasmic transcript accumulates to only 2-15% of the normal level. Sequence analysis indicates that this gene encodes a metallothionein. Mechanisms are discussed that might account for the post-transcriptional restriction of expression of some genes in hybrid embryos.

Repression of quiescence-specific polypeptides in chicken heart mesenchymal cells transformed by Rous sarcoma virus

Chicken heart mesenchymal cells do not proliferate in medium of physiological composition containing plasma (S. Balk, Proc. Natl. Acad. Sci. USA 77:6606-6610, 1980). To understand the molecular events involved in cell quiescence and in the initiation of cell division under physiological conditions, we examined the differences in the patterns of protein synthesis of quiescent, hormone-stimulated, and Rous sarcoma virus-transformed chicken heart mesenchymal cells. We describe the expression of a 20,000-kilodalton (kDa) polypeptide actively synthesized by quiescent cells but not by their transformed counterparts. Normal chicken heart mesenchymal cells stimulated with epidermal growth factor and insulin also repressed the synthesis of the 20,000-kDa polypeptide while actively growing but synthesized increasing amounts of the protein at high cell density (confluence). The synthesis of the 20,000-kDa protein is not restricted to chicken heart mesenchymal cells, since confluent, density-arrested chicken embryo fibroblasts also expressed high levels of the protein. Transformed chicken heart mesenchymal cells and embryo fibroblasts did not synthesize the protein even at high cell density. The 20,000-kDa polypeptide accumulated in the culture medium.

Translational activation of maternal mRNA encoding the heat-shock protein hsp90 during sea urchin embryogenesis

Changes in protein synthesis induced by heat shock of Strongylocentrotus purpuratus gastrulae were analyzed bt two-dimensional electrophoresis. Hyperthermia induces the synthesis of polypeptides having molecular masses of 90, 70, 50, 40, and 38 kDa. One of these, hsp90, appears as a pair of polypeptides which comigrates with proteins synthesized at normal temperature in eggs and embryos; these comigrating spots produce indistinguishable patterns upon electrophoretic analysis of partial V8 protease digests, indicating that hsp90 is synthesized throughout embryogenesis. The relative rate of incorporation of methionine into hsp90 is low in eggs and zygotes, but increases abruptly in morulae, constituting a rare and striking change in protein synthesis during early development. Cell-free translation analyses indicate that most of the mRNA encoding hsp90 resides in the pool of free ribonucleoprotein particles in eggs and early embryos, but shifts to polysomes by the 64-cell stage while remaining constant in mass. Thus the increase in synthesis of hsp90 appears to be via the selective activation of translation of a stored maternal mRNA. The shift of hsp90 mRNA to polysomes is accompanied by polyadenylation. Heat shock of eggs or zygotes did not result in translational activation of hsp90 mRNA. The sea urchin hsp90 doublet of spots comigrates with hsp90 induced by heat shock of chicken embryo fibroblasts, a conserved protein abundant in many cells of a variety of species.

Transient synthesis of a specific set of proteins during the rapid cleavage phase of sea urchin development

The rapid cleavage stage of early sea urchin development is characterized by the transient synthesis of a specific set of proteins. These proteins were identified by comparing the pattern of newly synthesized proteins from fully grown sea urchin oocytes, unfertilized and fertilized eggs, several embryonic stages, and adult tissues by one- and two-dimensional gel electrophoresis. We found that, in contrast to fertilization, meiotic maturation results in major changes in the relative amounts and types of proteins synthesized. The synthesis of many proteins in the oocyte, including actin, tubulin, and other proteins which have accumulated during oogenesis, appears to be greatly reduced or eliminated in the unfertilized and newly fertilized egg. An examination of the proteins synthesized in unfertilized and fertilized eggs reveals several proteins that are synthesized only during this phase of development and may be required for the rapid cell divisions which occur during this period. At the midblastula stage, when the cell-doubling time shows down, the pattern of synthesis changes to resemble that of the oocyte. These results imply that many of the changes in the pattern of protein synthesis seen around the blastula stage may be associated with the return of the cell cycle to a normal length rather than synthetic changes associated with differentiation.

Calmodulin gene expression during sea urchin development: persistence of a prevalent maternal protein

Calmodulin gene expression during embryogenesis of the sea urchin Strongylocentrotus purpuratus was investigated. Several identical bacteriophages containing a cDNA insert encoding sea urchin calmodulin (CM-1) were identified by screening a lambda gt10 library of S. purpuratus gastrula-stage cDNAs with a chicken calmodulin cDNA sequence. A 1.2-kb cDNA fragment from CM-1 was subcloned into pUC-8 to give plasmid pCAL-8. pCAL-8 contains a single open reading frame encoding 79 amino acids, a termination codon, and 0.9 kb of 3'-untranslated message. This sea urchin amino acid sequence shows 95% homology to amino acid residues 69-148 of the predicted sequence of chicken calmodulin. Northern analysis showed that pCAL-8 hybridizes to a single size (3.2 kb) of mRNA in both embryonic and adult somatic tissues. Genome blots suggested that there is a single calmodulin gene in the S. purpuratus genome. We used pCAL-8 to study calmodulin mRNA accumulation in S. purpuratus embryos. Calmodulin mRNA is present in the unfertilized egg at the level of a typical rare-class mRNA (1000-2000 transcripts) and accumulates approximately 100-fold to levels representing about 1/10th of 1% of the total mRNA in pluteus-stage cells. Synthesis of calmodulin, identified by two-dimensional gel electrophoresis, shows a similar developmental pattern. However, in spite of the very active synthesis of calmodulin during embryogenesis, most of the calmodulin in the pluteus is apparently provided for by an enormous store of calmodulin in the egg, corresponding to about 2% of the mass of total protein.

Biphasic stage sensitivity to UV suppression of gastrulation in sea urchin embryos

The effects of ultraviolet light (UV) on the gastrulation of sea urchin embryos were examined. The results suggest that gastrulation is inhibited by UV irradiation and that stage sensitivity to UV suppression of gastrulation changes biphasically: higher sensitivity at early and late blastula, and lower sensitivity at the mid-blastula stages. The UV-induced inhibition of gastrulation was completely reversible by subsequent exposure to visible light.

Sequential expression of germ-layer specific molecules in the sea urchin embryo

Described are two germ-layer specific molecules that appear coincident with the formation of two germ layer cell lineages in the sea urchin embryo. Meso1 is a molecule of 380 kDa that is first detected at the time of primary mesenchyme cell delamination from the wall of the blastula. Endo1 is a molecule of 320 kDa that appears on endoderm cells at the time of archenteron formation a few hours after Meso1 appears. Both antigens are identified by monoclonal antibodies. The appearance of these antigens is described by immunofluorescence microscopy, and quantitative data on their localization has been obtained by ultrastructural immunoelectron microscopy. The synthesis of the molecules has been followed by pulse-chase immunoprecipitation. Meso1 is first expressed in trans Golgi-like saccules, is concentrated in peripheral low electron-dense vesicles, and is found throughout the plasma membrane of the mesenchymal cells and their filopodial extensions. Newly translated Meso1 can first be immunoprecipitated upon differentiation of the mesoderm cell lineage, and pulse-chase studies suggest that the determinant is the result of a post-translational modification. [35S]Methionine pulses early in development followed by a chase to the mesenchyme blastula or prism stage show that at least a portion of the molecule is translated well in advance of the mesenchyme blastula stage. Endo1, in contrast, does not appear to be translated until the onset of gastrulation, just preceding the post-translational expression of the Endo1 determinant. Endo1 is localized to the apical and basolateral cell surfaces of the midgut and hindgut. No label is detected in foregut cells, demonstrating a heterogeneity of cell populations within the endoderm cell lineage corresponding to a difference in morphology. In addition, Endo1 is shown to be the result of new transcription by the embryonic genome. Even though the function of neither molecule is known, together they show the spatial and temporal precision of differentiation that accompanies the formation of germ layers.

Dissociation of cells from sea urchin embryos alters the synthesis of actins and other proteins

The effects of altered cellular microenvironments on patterns of protein synthesis at various periods during sea urchin development were quantitated by comparing the relative incorporation of [35S]methionine into selected polypeptides of intact embryos and cells dissociated from them. The effects of increasing times of reassociation were also determined. Quantitative, but not qualitative, differences in incorporation were noted. Actins, as well as heterogeneous acidic polypeptides with an Mr of about 80 kDa, showed increased incorporation in dissociated cells labeled at the time control embryos were recently hatched blastulae. Labeling of another acidic group of polypeptides with an Mr of about 100 kDa was decreased. Possible mechanisms regulating these shifts in incorporation were investigated by the use of inhibitors. The dissociation-triggered changes were insensitive to actinomycin D, cordycepin, dibutyryl cAMP, 3-isobutyl-1-methylxanthine, and trifluoperazine; however, the latter two stimulated incorporation into some polypeptides in intact blastulae. Age-dependent shifts in incorporation were also detected in both intact embryos and dissociated/reassociating cells.

Expression of alpha- and beta-tubulin genes during development of sea urchin embryos

Mature unfertilized eggs of the sea urchin Lytechinus pictus contain multiple alpha-tubulin mRNAs, which range in size from 1.75 to 4.8 kb, and two beta-tubulin mRNAs, 1.8 and 2.25 kb. These mRNAs were found at similar levels throughout the early cleavage stages. RNA gel blot hybridizations showed that prominent quantitative and qualitative changes in tubulin mRNAs occurred between the early blastula and hatched blastula stages. The overall amounts of alpha- and beta-tubulin mRNAs increased two- to fivefold between blastula and pluteus. These increases were due mainly to a rise in a 1.75-kb alpha RNA and a new 2.0-kb beta RNA. Other, minor changes also occurred during subsequent development. All size classes of alpha- and beta-tubulin RNAs in early and late embryos contained poly(A)+ translatable sequences. As reported earlier, some of each of the alpha RNAs, but neither of the beta RNAs, are translated in the egg and a small portion of each of the stored alpha and beta RNAs is recruited onto polysomes within 30 min of fertilization. In the work described here, subsequent development up to the morula stage was accompanied by a gradual recruitment of tubulin mRNAs into polysomes. By the early blastula stage, most of the maternal tubulin sequences were associated with polysomes. In contrast to the gradual recruitment of maternal sequences throughout cleavage, the tubulin mRNAs which appeared at the blastula stage showed no delay in entering polysomes. The exact fraction of each mRNA that was translationally active at later stages varied somewhat among the individual mRNAs. From the differential hybridization patterns of egg, embryo, and testis RNAs to various tubulin cDNA and genomic DNA probes, it is concluded that at least one gene producing maternal alpha mRNA is different from a second one which is expressed only in testis. Each of the three embryonic beta RNAs is encoded by a different beta gene; at least two of these different beta genes are also expressed in testis.

Maternal inheritance of transcripts from three Drosophila src-related genes

The Drosophila genome contains three major sequences related to the v-src gene. Previously published molecular studies have confirmed the structural homology between v-src and two of the Drosophila sequences. We have sequenced a portion of the third v-src-related Drosophila gene and found that it also shares structural homology with vertebrate and Drosophila src-family genes. RNA sequences from each of the src genes are present in pre-blastoderm embryos indicating that they are of maternal origin. As embryogenesis proceeds, the levels of each of the src RNA sequences decline. The pre-blastoderm src gene transcripts contain poly(A) and are present on polyribosomes suggesting that they are functional mRNAs. Since the Drosophila src transcripts were maternally inherited, we also investigated their distribution in adult females. The majority of the src transcripts in adult females were contained in ovaries. Only low levels of the transcripts were detected in males. These results strongly suggest that an abundant supply of src protein is required during early embryogenesis, perhaps at the time of cellularization of the blastoderm nuclei.

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.

Developmental time, cell lineage, and environment regulate the newly synthesized proteins in sea urchin embryos

Strongylocentrotus purpuratus embryos were fractionated into two cell populations of defined lineages at times corresponding to two critical developmental events: determination (16-cell stage) and early differentiation (mesenchyme blastula). The 16-cell stage blastomeres, labeled with [35S]methionine, exhibited identical protein synthesis patterns by fluorography, and this pattern was not significantly altered by cell separation. In comparing the proteins of the mesenchyme blastula to the 16-cell stage, differences (increases and decreases) were seen by fluorography of newly synthesized proteins. The synthesis of 2.9% of the mesenchyme blastula proteins is specific to or enriched in primary mesenchyme cells and 8.2% is specific to or enriched in endoderm/ectoderm cells. Additionally, in contrast to the earlier stage, the pattern of protein synthesis in the mesenchyme blastula embryos is substantially altered by cell separation. The ability to alter protein synthesis in response to environmental factors may be a further demonstration of the differentiation of these cells.

Regulation of cytoplasmic mRNA prevalence in sea urchin embryos. Rates of appearance and turnover for specific sequences

Complementary DNA clones representing cytoplasmic poly(A) RNAs of sea urchin embryos were hybridized with metabolically labeled cytoplasmic RNA preparations and the rates of appearance and of decay for each transcript species were determined at the blastula-gastrula stage of development. The prevalence of the transcripts chosen for this study ranged, on average, from about one molecule per cell to a few hundred molecules per cell. The embryos were labeled continuously for 18 hours with [3H]guanosine, beginning at 24 hours post-fertilization. The amount of cytoplasmic [3H]poly(A) RNA that hybridized to each cloned sequence was determined and the specific activity of the [3H]GTP pool was measured in the same embryos. Rate constants for the entry of each transcript species into the cytoplasm, and for its decay were extracted from these data. The embryo transcript species identified by the cloned probes displayed a range of stabilities. Half-lives of only a few hours were measured both for a very rare sequence and for a moderately prevalent sequence. Other newly synthesized transcripts, including sequences that first appear during embryonic development, as well as sequences also represented in maternal RNA, are far more stable. We conclude that cytoplasmic RNA turnover rate is a major variable in the determination of the cytoplasmic level of expression of embryo genes. The entry rates of the transcripts into the cytoplasm also varied, from a few molecules per embryo per minute to several hundred, depending on the sequence. By comparing the mass of transcripts of a given sequence in the embryo to the mass of transcripts of that sequence accumulating as a result of new synthesis, the point at which embryo transcription accounts for the major fraction of the cytoplasmic molecules could be estimated. This calculation showed that for some sequences maternal transcripts persist well beyond gastrulation, while other embryo poly(A) RNA species are largely the product of transcription in the embryo nuclei from the blastula stage onwards. There is no single stage at which all maternal transcripts are suddenly replaced by newly synthesized embryo transcripts. Primary transcription rates were measured for two sequences by determining accumulation of label in these RNA species soon after addition of [3H]guanosine to the cultures. Comparing these rates to the cytoplasmic entry rates, we did not detect a significantly greater nuclear transcription of the sequence homologous to the cloned probe.

Temporal expression of late histone messenger RNA in the sea urchin Lytechinus pictus

Sea urchin histones are encoded by several multigene families. The temporal expression of one of these families, the late histones, has been studied during the early development of Lytechinus pictus. Using a nuclease S1 assay, we detected about 10,000 transcripts encoding both late H3 and H4 proteins in the unfertilized egg. This suggests that the late genes were active at some point during oogenesis. The number of late gene transcripts begins to increase 6.5 hr after fertilization (64-cell stage), indicating that these genes probably become reactivated 4.5-6.5 hr after fertilization. The maximum rate of accumulation of transcripts (4600 molecules per min per embryo) occurs 9-14 hr after fertilization (from blastula stage to hatching). The number of transcripts peaks 21 hr after fertilization (onset of gastrulation) when the embryo has accumulated 1.8 X 10(6) copies of each late mRNA (a 164-fold increase). A 5.5-fold increase in the relative rate of transcription, between 7 and 15 hr after fertilization, is partly responsible for the accumulation of these gene products. The relative synthesis of early histone message, which is encoded by a different family, decreases 18-fold during this time. Synthesis of the late transcripts continues at the higher rate after accumulation has ceased (24 hr after fertilization). The number of late transcripts begins to decrease 48 hr after fertilization, reaching about 10,000 copies at 72 hr.

Detection of mrnas in sea urchin embryos by in situ hybridization using asymmetric RNA probes

Asymmetric RNA probes, which contain only the mRNA coding strand, provide a large increase in hybridization efficiency in situ over that observed with either symmetric (both strands represented) RNA or DNA probes. Asymmetric RNA probes are synthesized in vitro by transcription from recombinants formed between sequences encoding sea urchin mRNAs and the transcription vector R7 delta 7. Using a probe representing early variant histone mRNA sequences we have characterized hybridization to sections of sea urchin embryos with respect to thermal stability of the hybrids formed, optimum temperature, effect of sequence divergence on hybrid thermal stability, and dependence of the hybridization signals on probe concentration and hybridization time. Estimates from the observed signals indicate that a large fraction of target RNAs is both retained in sections and hybridized with probe at saturation. Coupled with measurements of nonspecific background binding of heterologous probes, these data indicate that the method has sufficient sensitivity to detect many moderately abundant mRNAs (20-75 molecules per cell in the 1500-cell pluteus). In situ hybridizations to embryos at different developmental stages show that while histone mRNAs are uniformly distributed in cleaving embryos, different cell lineages of older embryos show large differences in accumulation of these mRNAs.

The program of protein synthesis during the development of the micromere-primary mesenchyme cell line in the sea urchin embryo

Changes in the pattern of protein synthesis were analyzed during the in vitro development of the micromere-primary mesenchyme cell line of the sea urchin embryo. Micromeres were isolated and cultured from 16-cell stage embryos, and primary mesenchyme cells were isolated and cultured from early gastrulae. Both cell isolates developed normally in culture with about the same timing as their in situ counterparts in control embryos. Newly synthesized proteins were labeled with [3H]valine at several stages of development and were analyzed by two-dimensional polyacrylamide gel electrophoresis and fluorography. The electrophoretic pattern of labeled proteins changed dramatically during development. More than half of the analyzed proteins underwent qualitative or quantitative changes in their relative rates of valine incorporation and these changes were highly specific to this cell line. Almost all of the changes were initiated prior to gastrulation and many prior to hatching. The highest frequency of changes in the micromere pattern of protein synthesis occurred between hatching and the start of gastrulation. this peak of activity coincided with the normal time of ingression of the primary mesenchyme and preceded the differentiation of spicules by more than 30 hr. Most of the observed changes were characterized as either decreases in the synthesis of proteins that showed maximum incorporation at the 16-cell stage or increases in the synthesis of proteins that showed maxima in the fully differentiated cells. Very few proteins exhibited transient synthetic maxima at intermediate stages. Thus, the program of protein synthesis associated with the development of micromeres consists largely of a switch in emphasis from early to late proteins, with the primary time of switching being between hatching and the onset of grastrulation.

Protein synthesis during Ilyanassa organogenesis

The proteins labeled by normal and lobeless embryos of Ilyanassa obsoleta incubated in [35S]methionine during early and late organogenesis were shown by two-dimensional electrophoresis to be qualitatively equivalent. It is concluded that these polypeptides are part of the ubiquitous proteins required for cellular maintenance and that they are not uniquely associated with the differentiation of any specific organ or structure.