Sea urchin goosecoid function links fate specification along the animal-vegetal and oral-aboral embryonic axes

We have identified a single homolog of goosecoid, SpGsc, that regulates cell fates along both the animal-vegetal and oral-aboral axes of sea urchin embryos. SpGsc mRNA is expressed briefly in presumptive mesenchyme cells of the ∼200-cell blastula and, beginning at about the same time, accumulates in the presumptive oral ectoderm through pluteus stage. Loss-of-function assays with morpholine-substituted antisense oligonucleotides show that SpGsc is required for endoderm and pigment cell differentiation and for gastrulation. These experiments and gain-of-function tests by mRNA injection show that SpGsc is a repressor that antagonizes aboral ectoderm fate specification and promotes oral ectoderm differentiation. We show that SpGsc competes for binding to specific cis elements with SpOtx, a ubiquitous transcription activator that promotes aboral ectoderm differentiation. Moreover, SpGsc represses transcription in vivo from an artificial promoter driven by SpOtx. As SpOtx appears long before SpGsc transcription is activated, we propose that SpGsc diverts ectoderm towards oral fate by repressing SpOtx target genes. Based on the SpGsc-SpOtx example and other available data, we propose that ectoderm is first specified as aboral by broadly expressed activators, including SpOtx, and that the oral region is subsequently respecified by the action of negative regulators, including SpGsc. Accumulation of SpGsc in oral ectoderm depends on cell-cell interactions initiated by nuclear β-catenin function, which is known to be required for specification of vegetal tissues, because transcripts are undetectable in dissociated or in cadherin mRNA-injected embryos. This is the first identified molecular mechanism underlying the known dependence of oral-aboral ectoderm polarity on intercellular signaling.

SpKrl: a direct target of beta-catenin regulation required for endoderm differentiation in sea urchin embryos

Localization of nuclear beta-catenin initiates specification of vegetal fates in sea urchin embryos. We have identified SpKrl, a gene that is activated upon nuclear entry of beta-catenin. SpKrl is upregulated when nuclear beta-catenin activity is increased with LiCl and downregulated in embryos injected with molecules that inhibit beta-catenin nuclear function. LiCl-mediated SpKrl activation is independent of protein synthesis, indicating that SpKrl is a direct target of beat-catenin and TCF. Embryos in which SpKrl translation is inhibited with morpholino antisense oligonucleotides lack endoderm. Conversely, SpKrl mRNA injection rescues some vegetal structures in beta-catenin-deficient embryos. SpKrl negatively regulates expression of the animalizing transcription factor, SpSoxB1. We propose that SpKrl functions in patterning the vegetal domain by suppressing animal regulatory activities.

A BMP pathway regulates cell fate allocation along the sea urchin animal-vegetal embryonic axis

To examine whether a BMP signaling pathway functions in specification of cell fates in sea urchin embryos, we have cloned sea urchin BMP2/4, analyzed its expression in time and space in developing embryos and assayed the developmental consequences of changing its concentration through mRNA injection experiments. These studies show that BMP4 mRNAs accumulate transiently during blastula stages, beginning around the 200-cell stage, 14 hours postfertilization. Soon after the hatching blastula stage, BMP2/4 transcripts can be detected in presumptive ectoderm, where they are enriched on the oral side. Injection of BMP2/4 mRNA at the one-cell stage causes a dose-dependent suppression of commitment of cells to vegetal fates and ectoderm differentiates almost exclusively as a squamous epithelial tissue. In contrast, NOGGIN, an antagonist of BMP2/4, enhances differentiation of endoderm, a vegetal tissue, and promotes differentiation of cells characteristic of the ciliated band, which contains neurogenic ectoderm. These findings support a model in which the balance of BMP2/4 signals produced by animal cell progeny and opposing vegetalizing signals sent during cleavage stages regulate the position of the ectoderm/ endoderm boundary. In addition, BMP2/4 levels influence the decision within ectoderm between epidermal and nonepidermal differentiation.

Animal-vegetal axis patterning mechanisms in the early sea urchin embryo

We discuss recent progress in understanding how cell fates are specified along the animal-vegetal axis of the sea urchin embryo. This process is initiated by cell-autonomous, maternally directed, mechanisms that establish three unique gene-regulatory domains. These domains are defined by distinct sets of vegetalizing (beta-catenin) and animalizing transcription factor (ATF) activities and their region of overlap in the macromeres, which specifies these cells as early mesendoderm. Subsequent signaling among cleavage-stage blastomeres further subdivides fates of macromere progeny to yield major embryonic tissues. Zygotically produced Wnt8 reinforces maternally regulated levels of nuclear beta-catenin in vegetal derivatives to down regulate ATF activity and further promote mesendoderm fates. Signaling through the Notch receptor from the vegetal micromere lineages diverts adjacent mesendoderm to secondary mesenchyme fates. Continued Wnt signaling expands the vegetal domain of beta-catenin's transcriptional regulatory activity and competes with animal signaling factors, including BMP2/4, to specify the endoderm-ectoderm border within veg(1) progeny. This model places new emphasis on the importance of the ratio of maternally regulated vegetal and animal transcription factor activities in initial specification events along the animal-vegetal axis.

SpSoxB1, a maternally encoded transcription factor asymmetrically distributed among early sea urchin blastomeres

We have identified a Sox family transcription factor, SpSoxB1, that is asymmetrically distributed among blastomeres of the sea urchin embryo during cleavage, beginning at 4th cleavage. SpSoxB1 interacts with a cis element that is essential for transcription of SpAN, a gene that is activated cell autonomously and expressed asymmetrically along the animal-vegetal axis. In vitro translated SpSoxB1 forms a specific complex with this cis element whose mobility is identical to that formed by a protein in nuclear extracts. An anti-SpSoxB1 rabbit polyclonal antiserum specifically supershifts this DNA-protein complex and recognizes a single protein on immunoblots of nuclear proteins that comigrates with in vitro translated SpSoxB1. Developmental immunoblots of total proteins at selected early developmental stages, as well as EMSA of egg and 16-cell stage proteins, show that SpSoxB1 is present at low levels in unfertilized eggs and progressively accumulates during cleavage. SpSoxB1 maternal transcripts are uniformly distributed in the unfertilized egg and the protein accumulates to similar, high concentrations in all nuclei of 4- and 8-cell embryos. However, at fourth cleavage, the micromeres, which are partitioned by asymmetric division of the vegetal 4 blastomeres, have reduced nuclear levels of the protein, while high levels persist in their sister macromeres and in the mesomeres. During cleavage, the uniform maternal SpSoxB1 transcript distribution is replaced by a zygotic nonvegetal pattern that reinforces the asymmetric SpSoxB1 protein distribution and reflects the corresponding domain of SpAN mRNA accumulation at early blastula stage (approximately 150 cells). The vegetal region lacking nuclear SpSoxB1 gradually expands so that, after blastula stage, only cells in differentiating ectoderm accumulate this protein in their nuclei. The results reported here support a model in which SpSoxB1 is a major regulator of the initial phase of asymmetric transcription of SpAN in the nonvegetal domain by virtue of its distribution at 4th cleavage and is subsequently an important spatial determinant of expression in the early blastula. This factor is the earliest known spatially restricted regulator of transcription along the animal-vegetal axis of the sea urchin embryo.

Regulative development of the sea urchin embryo: signalling cascades and morphogen gradients

Differentiation of sea urchin embryo ectoderm, endoderm and mesenchyme cells, whose anlagen are arrayed along the animal-vegetal axis, relies on both maternally regulated localized transcription factor activities and cell-cell signalling. Classic models proposed that fates are determined by opposing animal and vegetal morphogenetic gradients, whereas current models emphasize unidirectional and sequential vegetal-to-animal signalling cascades between adjacent blastomeres. Recent data support aspects of both models: the vegetal micromeres send one or more signals, which depend on a nuclear beta-catenin-dependent pathway, that both activate Notch signalling required for secondary mesenchyme fate and promote endoderm differentiation and gastrulation. This is opposed by an animalizing domain of BMP4 signals that regulates ectodermal cell fates and establishes the ectoderm-endoderm border.

Spatially regulated SpEts4 transcription factor activity along the sea urchin embryo animal-vegetal axis

Because the transcription of the SpHE gene is regulated cell-autonomously and asymmetrically along the maternally determined animal-vegetal axis of the very early sea urchin embryo, its regulators provide an excellent entry point for investigating the mechanism(s) that establishes this initial polarity. Previous studies support a model in which spatial regulation of SpHE transcription relies on multiple nonvegetal positive transcription factor activities (Wei, Z., Angerer, L. M. and Angerer, R. C. (1997) Dev. Biol. 187, 71–78) and a yeast one-hybrid screen has identified one, SpEts4, which binds with high specificity to a cis element in the SpHE regulatory region and confers positive activation of SpHE promoter transgenes (Wei, Z., Angerer, R. C. and Angerer, L. M. (1999) Mol. Cell. Biol. 19, 1271–1278). Here we demonstrate that SpEts4 can bind to the regulatory region of the endogenous SpHE gene because a dominant repressor, created by fusing SpEts4 DNA binding and Drosophila engrailed repression domains, suppresses its transcription. The pattern of expression of the SpEts4 gene is consistent with a role in regulating SpHE transcription in the nonvegetal region of the embryo during late cleavage/early blastula stages. Although maternal transcripts are uniformly distributed in the egg and early cleaving embryo, they rapidly turn over and are replaced by zygotic transcripts that accumulate in a pattern congruent with SpHE transcription. In addition, in vivo functional tests show that the SpEts4 cis element confers nonvegetal transcription of a beta-galactosidase reporter gene containing the SpHE basal promoter, and provide strong evidence that the activity of this transcription factor is an integral component of the nonvegetal transcriptional regulatory apparatus, which is proximal to, or part of, the mechanism that establishes the animal-vegetal axis of the sea urchin embryo.

Regulation of BMP signaling by the BMP1/TLD-related metalloprotease, SpAN

We have used the Xenopus embryo as a test system for analyzing the activity of SpAN, a sea urchin metalloprotease in the astacin family containing BMP1 and tolloid. Embryos expressing SpAN initiated gastrulation on a time scale indistinguishable from controls, but invagination of the vegetal pole was subsequently delayed by several hours. At tailbud stages the most severely affected embryos were completely ventralized, lacking all dorsal structures. Molecular analysis of injected embryos, using probes for both dorsal (xgsc and xnot) and ventral (xhox3 and xwnt8) mesoderm, indicates that SpAN ventralizes dorsal mesoderm during gastrula stages. These results mirror those previously obtained with BMP4, suggesting that SpAN may enhance the activity of this ventralizing factor. Consistent with this suggestion, we have shown that SpAN blocks the dorsalizing activity of noggin and chordin, two inhibitory binding proteins for BMP4, but not that of a dominant-negative receptor for BMP4. In contrast, a dominant-negative SpAN, in which the metalloprotease domain has been deleted, dorsalizes ventral mesoderm, a phenotype that can be rescued by coexpressing either SpAN or XBMP1. This suggests that SpAN is mimicking a Xenopus metalloprotease responsible for regulating the activity of Xenopus BMPs during gastrulation. Moreover, our results raise the possibility that SpAN may function to facilitate BMP signaling in early sea urchin embryos.

Identification of a new sea urchin ets protein, SpEts4, by yeast one-hybrid screening with the hatching enzyme promoter

We report the use of a yeast one-hybrid system to isolate a transcriptional regulator of the sea urchin embryo hatching enzyme gene, SpHE. This gene is asymmetrically expressed along the animal-vegetal axis of sea urchin embryos under the cell-autonomous control of maternal regulatory activities and therefore provides an excellent entry point for understanding the mechanism that establishes animal-vegetal developmental polarity. To search for transcriptional regulators, we used a fragment of the SpHE promoter containing several individual elements instead of the conventional bait that contains a multimerized cis element. This screen yielded a number of positive clones that encode a new member of the Ets family, named SpEts4. This protein contains transcriptional activation activity, since expression of reporter genes in yeast does not depend on the presence of the yeast GAL4 activation domain. Sequences in the N-terminal region of SpEts4 mediate the activation activity, as shown by deletion or domain-swapping experiments. The newly identified DNA binding protein binds with a high degree of specificity to a SpHE promoter Ets element and forms a complex with a mobility identical to that obtained with 9-h sea urchin embryo nuclear extracts. SpEts4 positively regulates SpHE transcription, since mutation of the SpEts4 site in SpHE promoter transgenes reduces promoter activity in vivo while SpEts4 mRNA coinjection increases its output. As expected for a positive SpHE transcriptional regulator, the timing of SpEts4 gene expression precedes the transient expression of SpHE in the very early sea urchin blastula.

Sea urchin FGFR muscle-specific expression: posttranscriptional regulation in embryos and adults

We have shown previously by in situ hybridization that a gene encoding a fibroblast growth factor receptor (SpFGFR) is transcribed in many cell types during the initial phases of sea urchin embryogenesis (Strongylocentrotus purpuratus) (McCoon et al., J. Biol. Chem. 271, 20119-20195, 1996). Here we demonstrate by immunostaining with affinity-purified antibody that SpFGFR protein is detectable only in muscle cells of the embryo and appears at a time suggesting that its function is not in commitment to a muscle fate, but instead may be required to support the proliferation, migration, and/or differentiation of myoblasts. Surprisingly, we find that SpFGFR transcripts are enriched in embryo nuclei, suggesting that lack of processing and/or cytoplasmic transport in nonmuscle cells is at least part of the posttranscriptional regulatory mechanism. Western blots show that SpFGFR is also specifically expressed in adult lantern muscle, but is not detectable in other smooth muscle-containing tissues, including tube foot and intestine, or in coelomocytes, despite the presence of SpFGFR transcripts at similar concentrations in all these tissues. We conclude that in both embryos and adults, muscle-specific SpFGF receptor synthesis is controlled primarily at a posttranscriptional level. We show by RNase protection assays that transcripts encoding the IgS variant of the ligand binding domain of the receptor, previously shown to be enriched in embryo endomesoderm fractions, are the predominant, if not exclusive, SpFGFR transcripts in lantern muscle. Together, these results suggest that only a minority of SpFGFR transcripts are processed, exported, and translated in both adult and embryonic muscle cells and these contain predominantly, if not exclusively, IgS ligand binding domain sequences.

The SpHE gene is downregulated in sea urchin late blastulae despite persistence of multiple positive factors sufficient to activate its promoter

Previous studies of the regulatory region of the SpHE (hatching enzyme) gene of the sea urchin Strongylocentrotus purpuratus (Wei, Z., Angerer, L.M., Gagnon, M.L. and Angerer, R.C. (1995) Characterization of the SpHE promoter that are spatially regulated along the animal-vegetal axis of the sea urchin embryo. Dev. Biol. 171, 195-211) have shown that approximately 330 bp is necessary and sufficient to promote high level expression in embryos of transgenes that reproduce the spatially asymmetric pattern of endogenous gene activity along the maternally determined animal-vegetal embryonic axis. Furthermore, SpHE regulatory elements appear to be redundant since several different combinations are sufficient to elicit strong promoter activity and many subsets function like the endogenous gene only in non-vegetal cells of the blastula (Wei, Z., Angerer, L.M. and Angerer, R.C. (1997) Multiple positive cis-elements regulate the asymmetric expression of the SpHE gene along the sea urchin embryo animal-vegetal axis. Dev. Biol., 187, 71-88). Here we demonstrate by in vivo footprinting that many cis elements on the endogenous promoter are occupied when the gene is active in early blastulae, but the binding of corresponding trans factors is significantly reduced when the gene becomes inactive in late blastulae. In addition, downregulation of the promoter is accompanied by a transition from a non-nucleosomal to a nucleosome-like chromatin structure. Surprisingly, in vitro DNase I footprints of the 300 bp promoter using nuclear protein extracts from early and late blastulae are not detectably different and neither this sequence, nor a longer one extending to -1255, reproduces the loss of endogenous SpHE transcriptional activity after very early blastula stage. These observations imply that temporal repression of SpHE transcription involves a decrease in accessibility of the promoter to activators that are nevertheless present in nuclei and capable of activating transgene promoters. Temporal, but not spatial, downregulation is therefore likely to be regulated by negative activities functioning outside the -1255 promoter region which may serve as direct repressors or mediate an inactive chromatin structure.

Multiple positive cis elements regulate the asymmetric expression of the SpHE gene along the sea urchin embryo animal-vegetal axis

The mechanism that establishes the maternally determined animal-vegetal axis of sea urchin embryos is unknown. We have analyzed the cis-regulatory elements of the SpHE gene of Strongylocentrotus purpuratus, which is asymmetrically expressed along this axis, in an effort to identify components of maternal positional information. Previously, we defined a regulatory region that is sufficient to provide correct nonvegetal expression of a beta-galactosidase reporter gene (Wei, Z., Angerer, L. M., Gagnon, M. L., and Angerer, R. C., Dev. Biol. 171, 195-211, 1995). We have now analyzed this region intensively in order to determine if the spatial pattern is controlled by nonvegetal-positive activities or by vegetal-negative activities. The regulatory sequences, except the basal promoter, were mutated by either deletion or sequence replacement. None of these mutations resulted in ectopic beta-gal expression in vegetal cells, showing that no single negative cis element is responsible for the lack of vegetal SpHE transcription. Surprisingly, even short segments of the regulatory region containing only several identified cis elements also direct nonvegetal expression. Furthermore, the SpHE basal promoter functions effectively in vegetal cells in combination with cis-acting elements derived from the PMC-specific gene, SM50. We conclude that the spatial pattern of SpHE transcription is achieved by multiple positive activities concentrated in nonvegetal cells. The vegetal expression of SM50 also is regulated only by positive activities (Makabe, K. W., Kirchhamer, C. V., Britten, R. J., and Davidson, E. H., Development 121, 1957-1970, 1995). A chimeric promoter containing both SpHE and SM50 regulatory sequences is active ubiquitously, suggesting that these regulators are not reciprocally repressive. These observations suggest a model in which the SpHE and SM50 genes are activated by separate sets of positive maternal activities concentrated, respectively, in nonvegetal and vegetal domains of the early embryo.

SpFGFR, a new member of the fibroblast growth factor receptor family, is developmentally regulated during early sea urchin development

We describe the cloning of a new fibroblast growth factor receptor, SpFGFR1, that is differentially regulated at the level of transcript abundance during sea urchin embryogenesis. Sequence representing the conserved tyrosine kinase domain was obtained by reverse transcription-polymerase chain reaction using degenerate primers, and the entire open reading frame was obtained by standard cDNA library screening methods. SpFGFR contains a series of domains characteristic of FGFRs: three immunoglobulin-like motifs, an acid box, a transmembrane domain, a relatively long juxtamembrane sequence, a split tyrosine kinase domain, and two conserved intracellular tyrosine residues. Alternative splicing of SpFGFR generates two variants (Ig3L and Ig3S), which differ by insertion in the center of the Ig3 domain of 34 extra amino acids, encoded by an additional exon. Transcripts encoding both variants accumulate when morphogenesis begins with mesenchyme cell ingression and gastrulation. SpFGFR transcripts accumulate in all cell types of the embryo, although in situ hybridization shows that they are somewhat enriched in cells of oral ectoderm and endoderm. Transcripts encoding the Ig3S variant, whose structure resembles more closely that of vertebrate receptors, are enriched in endomesoderm, suggesting that the SpFGFR variants could play distinct roles in the sea urchin embryo.

Characterization of a SpAN promoter sufficient to mediate correct spatial regulation along the animal-vegetal axis of the sea urchin embryo

In order to investigate how the maternally specified animal-vegetal axis of the sea urchin embryo is established, we have examined the molecular basis of regulation of several genes transcribed differentially in nonvegetal and vegetal domains of the very early blastula. Here we present an initial characterization of the regulatory region of one of these, SpAN, which encodes a protease in the astacin family related to Drosophila tolloid and vertebrate BMP-1 (Reynolds et al., Development 114, 769-786). Tests of SpAN promoter function in vivo show that high-level activity and correct not-vegetal expression are mediated by sequences within 300 bp upstream of the basal promoter. In vitro studies have identified six protein binding sites serviced by at least five different proteins. Comparison of the structure of the SpAN promoter to that of SpHE, whose expression pattern is identical, shows that both promoters contain multiple positively acting upstream elements close to the basal promoter. We show that two elements are critical for high-level transcription of SpAN, since exact replacement of either results in 10- to 20-fold reduction in promoter strength. These shared elements are, however, not essential for spatially correct SpHE gene transcription. We conclude that the coordinate strong activities of the SpAN and SpHE promoters in the nonvegetal domain of the embryo rely primarily on different transcription factor activities.

Characterization of the SpHE promoter that is spatially regulated along the animal-vegetal axis of the sea urchin embryo

To understand how the maternally determined animal-vegetal polarity of the sea urchin embryo is established, we have begun to examine the regulatory apparatus of the gene encoding the Strongylocentrotus purpuratus hatching enzyme (SpHE). Previous studies have shown that the pattern of SpHE mRNA accumulation reflects the animal-vegetal developmental axis in that transcription is strongly upregulated during early cleavage in more animal blastomeres, but not in those around the maternally specified vegetal pole of the 16-cell embryo [Reynolds et al., Development 114, 769-786 (1992)]. Tests of SpHE promoter function in vivo using chloramphenicol acetyltransferase and beta-galactosidase enzymatic reporters define a regulatory region within several hundred nucleotides of the transcription initiation site. This region is sufficient to mediate both strong expression in the early blastula and spatially correct transcription. However, neither this region nor longer upstream sequences are sufficient to reproduce the transcriptional downregulation after very early blastula stage that is observed for endogenous genes. Biochemical assays of protein-DNA interactions within the regulatory region identify at least nine sites binding at least six different factors. These cis elements include Otx (an orthodenticle homologue), CCAAT, ets-related, and three unidentified motifs. Deletions and/or replacements of these cis-elements, alone and in combination, indicate that no single factor is essential for SpHE promoter activity, but instead that various combinations of subsets of these elements are capable of eliciting levels of transcription similar to those of the unaltered regulatory region. This density of regulatory elements is consistent with the intense transcription of endogenous SpHE genes during cleavage.

An orthodenticle-related protein from Strongylocentrotus purpuratus

Orthodenticle-related proteins function as regulators of head formation and other developmental events in flies and mice. Here, we characterize a cDNA clone encoding an orthodenticle-related protein from the sea urchin Strongylocentrotus purpuratus. The cDNA, termed SpOtx, has a highly conserved orthodenticle homeobox but otherwise diverges in sequence from its fly and mouse counterparts. Orthodenticle-related proteins bind with high affinity to DNA containing the sequence motif TAATCC/T. The S. purpuratus aboral ectoderm-specific Spec2a gene has several TAATCC/T sites in its control region, and we provide evidence, using bandshift analysis, that Spec2a may be target gene for SpOtx. Two SpOtx transcripts accumulate during embryogenesis, an early transcript whose level peaks at blastula stage and a late transcript accumulating to highest concentrations at gastrula stage. SpOtx transcripts were found initially in all cells of the cleaving embryo, but they gradually became restricted to oral ectoderm and endoderm cells. In contrast, SpOtx protein was found in nuclei of all cells at both blastula and pluteus stages. Our results suggest that SpOtx plays a role in the activation of the Spec2a gene and most likely has additional functions in the developing sea urchin embryo.

The univin gene encodes a member of the transforming growth factor-beta superfamily with restricted expression in the sea urchin embryo

We have identified a gene in the sea urchin Strongylocentrotus purpuratus that encodes a member of the transforming growth factor beta (TGF-beta) gene superfamily. We have named the gene univin, and it is the first member of this superfamily to be reported in echinoderms. The cDNA sequence predicts a 383-amino-acid residue protein with 7 cysteine residues characteristic of members of this superfamily and with a cluster of basic residues appropriately situated to signal proteolytic cleavage. Sequence comparisons place univin in the bone morphogenetic protein (BMP) group of the TGF-beta superfamily along with the vertebrate BMPs, decapentaplegic protein from Drosophila, and Vg-1 from Xenopus. Analyses of univin expression in early embryos by RNA blots and in situ hybridization revealed the highest levels of expression in the egg and prehatching blastula. During late cleavage stages, univin mRNA accumulation is progressively restricted to a circumequatorial band. Expression is further restricted during gastrulation when univin transcripts are detected primarily in the presumptive foregut and ciliated band. By pluteus stage, signals are detectable only in these cell types. The restricted temporal and spatial patterns of expression of univin during early blastula stages parallel those of SpAN, which encodes an astacin-like protease related to tolloid and BMP-1 (Reynolds et al., 1992). The fact that these proteases are thought to function in the proteolytic activation of TGF-beta-related proteins that, respectively, regulate Drosophila embryonic dorsal-ventral patterning and vertebrate bone development suggests that SpAN and univin could also have critical roles in early developmental decisions in the sea urchin embryo.

Distinct pattern of embryonic expression of the sea urchin CyI actin gene in Tripneustes gratilla

Cloning and sequencing of Tripneustes gratilla genomic DNA and cDNA encoding a developmentally regulated, embryonic messenger RNA, referred to as Tg616, revealed an actin-encoding gene orthologous to the CyI actin gene described from Strongylocentrotus purpuratus. Tg616 and SpCyI share: (1) 150 nucleotides of highly conserved sequence 5' of the transcription start site, (2) 95% nucleotide sequence identity in the protein encoding regions, which specify identical amino acid residues in 375 of 377 positions, and (3) extensive nucleotide sequence identity in the 3' untranslated region of their messenger RNAs. Tg616 was therefore designated TgCyI. In situ hybridization shows sequential activation of TgCyI in various cells of the embryo. TgCyI mRNA becomes abundant in primary and secondary mesenchyme cells as they prepare to enter the blastocoel, in prospective aboral ectoderm cells at blastula stage, in gut cells during gut differentiation, and in oral ectoderm at pluteus stage. This pattern of embryonic gene expression is more complex than any of the major patterns of developmentally upregulated genes observed in S. purpuratus embryos and is distinct from SpCyI expression which is progressively restricted to the gut and oral ectoderm.

Major temporal and spatial patterns of gene expression during differentiation of the sea urchin embryo

We have investigated the temporal and spatial patterns of accumulation of mRNAs randomly selected from the sea urchin gastrula polyadenylated RNA population. Three different assays show that the predominant temporal pattern of expression, exhibited by about three-fourths of these messages, consists of a large (mean 80-fold) increase in mRNA abundance between egg and gastrula stages. Most mRNAs are present in the maternal population and are detectable on blots as single mature-sized messages; however, a large number of high-molecular-weight, heterodisperse transcripts containing these same sequences also exist in the egg cytoplasm. The majority of gastrula messages are not embryo specific but are present in total adult urchin RNA at concentrations similar to those in embryos. Fine-scale RNA blot analysis indicates that the majority of mRNAs begin to accumulate at very early blastula stages, although there is considerable diversity in the time when these messages reach peak abundance. Most gastrula mRNAs are also spatially regulated during development. The observed distributions can be categorized into three major functional or regulatory classes: (1) Forty percent of mRNAs accumulate in cells which are cycling or preparing for growth. (2) About one-third of the messages accumulate in one or more differentiating cell types. (3) Only slightly more than one-fourth of the messages are present in all cell types throughout development. Most tissue-specific messages are relatively abundant, indicating that the differentiated functions of cells are executed through mRNAs operating at the level of hundreds of copies per cell. In contrast, most rare messages are expressed in most or all cell types, in which they function at only a few copies per cell. All messages which begin to accumulate before hatching blastula stage are initially distributed broadly, and their distribution becomes progressively restricted during embryogenesis. In contrast, all messages which begin to accumulate after the onset of gastrulation accumulate only in discrete subsets of cells. The results presented here illustrate much more extensive temporal regulation of gene expression during sea urchin embryogenesis than previously detected. This is accompanied by spatial regulation of expression of most genes which is itself temporally modulated as the cellular requirements for cell division and differentiation change during development.

Centrifugal elutriation of large fragile cells: isolation of RNA from fixed embryonic blastomeres

In order to analyze the RNA populations present in different cells of very early embryos, we have developed a protocol to purify these large blastomeres using counterflow centrifugal elutriation (CCE). This procedure employs ethanol fixation to stabilize the cells against shear forces encountered during CCE. Using this method, we fractionated the three different blastomere types of the 16-cell sea urchin embryo, the micromeres, mesomeres, and macromeres, achieving 96, 94, and 96% mean purities, respectively. We show here that intact RNA is recovered with equal efficiency from each blastomere preparation. Using this method, we have identified several RNAs that are distributed non-uniformly among these cells.

Early mRNAs, spatially restricted along the animal-vegetal axis of sea urchin embryos, include one encoding a protein related to tolloid and BMP-1

The cloning and characterization of cDNAs representing four genes or small gene families that are coordinately expressed in a spatially restricted pattern during the very early blastula (VEB) stage of sea urchin development are presented. The VEB genes encode multiple transcripts that are expressed transiently in embryos of Strongylocentrotus purpuratus between 16-cell stage and hatching, with peak abundance 12 to 15 hours post-fertilization (approximately 150–250 cells). The VEB transcripts share the same spatial pattern in the early blastula embryo: they are asymmetrically distributed along the animal-vegetal axis but their distribution around this axis is uniform. Thus, the VEB transcripts are the earliest messages to reveal asymmetry along the primary axis in the sea urchin embryo. The temporal and spatial patterns of VEB transcript accumulation are not consistent with involvement of these gene products in cell division or in tissue-specific functions. Furthermore, VEB messages cannot be detected in either ovary or adult tissues, suggesting that these genes function exclusively during embryogenesis. We suggest that the VEB genes function in constructing the early blastula. Two VEB genes encode metalloendoproteases: one (SpHE) is hatching enzyme and the other (SpAN) is similar to bone morphogenetic protein-1 (BMP-1; Wozney et al., Science 242: 1528–1534, 1988) and the Tolloid gene product (tld) (Shimell et al., Cell 67: 459–482, 1991). Several lines of evidence suggest that the VEB genes are regulated directly by factors or regulatory activities localized along the maternally specificed animal-vegetal axis.

Posttranscriptional regulation of ectoderm-specific gene expression in early sea urchin embryos

During development of the sea urchin Strongylocentrotus purpuratus embryo, transcription of the Spec1 and actin CyIIIa genes is activated and the corresponding mRNAs accumulate specifically in ectoderm cells. We show that in gastrulae this tissue specificity of mRNA accumulation is regulated largely if not entirely at a posttranscriptional level. We used RNAase protection assays with intron and exon probes to measure the levels of nuclear precursors and mature message, respectively, in total RNA from embryo fractions enriched for ectoderm (Ect) or endoderm+mesenchyme (E/M) cells. These measurements demonstrate that E/M cells, which do not accumulate Spec1 and actin CyIIIa mRNAs, contain high levels of intron transcripts, indicating that cells of the E/M tissues transcribe these genes. At later stages, transcripts containing intron sequences are restricted to ectoderm cells. These results indicate that there is a transition from posttranscriptional to transcriptional regulation of tissue-specific mRNA accumulation during the gastrula stage. Measurements of transcription rate by nuclear run-on assays substantiate this conclusion for Spec1 and extend it to two other genes, SpEGFI and Spec2c, which also encode ectoderm-specific mRNAs. Posttranscriptional regulation was not observed for the SM50 gene whose mRNA accumulates only in primary mesenchyme cells, or for actin CyI which is expressed predominantly in E/M cells of gastrulae.

Tissue-restricted accumulation of a ribosomal protein mRNA is not coordinated with rRNA transcription and precedes growth of the sea urchin pluteus larva

We have identified an mRNA that encodes a protein, SpS24, of the small ribosomal subunit in the sea urchin, Strongylocentrotus purpuratus. RNA blot and in situ hybridization analyses show that the SpS24 gene is active during early oogenesis, downregulated in the mature egg and during cleavage, and reactivated in the early blastula. The mRNA then increases in abundance at least 100-fold. Later in development, expression of SpS24 mRNA becomes restricted primarily to cells in the oral ectoderm and endoderm of the pluteus larva, and the message is undetectable in aboral ectoderm cells and most mesenchyme cells. To determine whether transcription of the ribosomal RNA genes occurs at a higher rate in oral ectoderm and endoderm tissues, a probe for the transcribed spacer was used in RNase protection and in situ hybridization assays. High concentrations of rRNA-processing intermediates were observed in unfertilized eggs and shown to reside primarily, if not exclusively, in the cytoplasm. The spatial and temporal distributions of these sequences strongly suggest that they are associated with heavy bodies. New embryonic rRNA transcripts are first detectable at the very early blastula stage. In later embryos, the content of this transcribed spacer sequence is similar in all but a few cells, which implies that they synthesize rRNA at a similar low rate. Comparison of available estimates of rRNA transcription rate with the potential rate of SpS24 protein synthesis, calculated from SpS24 mRNA prevalence, shows that oral ectoderm and endoderm cells have the capacity to synthesize 15- to 30-fold more SpS24 protein than is required to keep pace with rRNA synthesis in these cells. Because the sea urchin embryo develops from an egg to a pluteus larva in the absence of growth, this stockpiling of SpS24 mRNA anticipates rather than accompanies the onset of growth, which does not begin until after feeding. Upregulation of this gene is therefore part of the developmental program, rather than a physiological response to nutrient availability.

Expression of two mRNAs encoding EGF-related proteins identifies subregions of sea urchin embryonic ectoderm

Many proteins containing domains related to epidermal growth factor (EGF) function in intercellular interactions that mediate specification of cell fate. We have used in situ hybridization to show that the expression of two EGF-related genes (SpEGF I and SpEGF II) is restricted to the same subset of ectodermal cells in sea urchin pluteus larvae. However, the concentration of EGF I mRNA in different epithelial cells of aboral ectoderm and postoral facial epithelium is constant while that of EGF II mRNA is highly modulated. RNase protection assays show that both genes are activated during the period when ectoderm funder cells are established, i.e., between fourth and fifth and between fifth and sixth cleavages for EGF I and EGF II, respectively. By mesenchyme blastula stage EGF I mRNA reaches maximum abundance (800-1000 copies/expressing cell) as a result of a high transcription rate, while EGF II mRNA peaks at about half that concentration by gastrula stage. EGF I expression begins at early stages of oogenesis while EGF II expression appears to be confined to embryogenesis.

Unusual pattern of accumulation of mRNA encoding EGF-related protein in sea urchin embryos

A sea urchin (Strongylocentrotus purpuratus) messenger RNA encoding a protein (SpEGF2) related to epidermal growth factor (EGF) was identified. The full-length complementary DNA sequence predicts a protein with an unusually simple structure, including four tandem EGF-like repeats and a hydrophobic leader, but lacking a potential transmembrane domain. Sequence similarities suggest that the peptides are homologous to two peptides from a different sea urchin species, which cause a classic developmental defect, exogastrulation, when added to the seawater outside of embryos. The SpEGF2 messenger RNA begins to accumulate at blastula stage, and in pluteus larvae it is distributed in discrete regions of ectoderm that are not congruent with known histological borders. One region corresponds to that expressing the homeodomain-containing protein, SpHbox1. The structure of the SpEGF2 protein and the pattern of accumulation of its messenger RNA suggest that it may have important functions as a secreted factor during development of sea urchin embryos.

Structure and tissue-specific developmental expression of a sea urchin arylsulfatase gene

Arylsulfatases are a group of enzymes that remove sulfate moieties from a diverse set of substrates including glycoproteins, steroids, and cerebrosides. We have isolated recombinant cDNA clones corresponding to an arylsulfatase (SpARS) message that encodes an abundant protein of pluteus larvae of the sea urchin Strongylocentrotus purpuratus. Although vertebrate arylsulfatases have broad tissue distributions, in situ hybridization with a probe for SpARS shows that the sea urchin message accumulates in the embryo only in the single cell type of aboral ectoderm and its precursors. The message is first detectable by RNase protection assays around hatching blastula stage and accumulates through pluteus larva stage. The open reading frame of cDNA clones is 1701 nt long and encodes a deduced protein with a predicted molecular mass of 61 kDa. Analysis of corresponding genomic DNA clones reveals that the pre-mRNA contains six exons. Consistent with the fact that arylsulfatase enzyme activity is extracellular, this polypeptide has a hydrophobic leader sequence and three potential glycosylation sites. Furthermore, hybridization in situ shows that in blastulae arylsulfatase message is preferentially concentrated around nuclei at the basal sides of cells. The S. purpuratus sequence is very similar to that recently reported for the same enzyme from Hemicentrotus pulcherrimus and 30% of the amino acid residues are also identical to those of both human arylsulfatase C (steroid sulfatase) and arylsulfatase A. Sequence relationships among these four mRNAs suggest that, assuming equal rates of evolution, the duplication separating the human genes occurred at about the time of separation of the echinoderm and vertebrate lineages.

Altered expression of spatially regulated embryonic genes in the progeny of separated sea urchin blastomeres

We have examined the importance of the extracellular environment on the ability of separated cells of sea urchin embryos (Strongylocentrotus purpuratus) to carry out patterns of mRNA accumulation and decay characteristic of intact embryos. Embryos were dissociated into individual blastomeres at 16-cell stage and maintained in calcium-free sea water so that daughter cells continuously separated. Levels of eleven different mRNAs in these cells were compared to those in control embryos when the latter reached mesenchyme blastula stage, by which time cells in major regions of the intact embryo have assumed distinctive patterns of message accumulation. Abrogation of interactions among cells resulted in marked differences in accumulation and/or turnover of the individual mRNAs, which are expressed with diverse temporal and spatial patterns of prevalence in intact embryos. In general, separated cells are competent to execute initial events of mRNA accumulation and decay that occur uniformly in most or all blastomeres of the intact embryo and are likely to be regulated by maternal molecules. The ability of separated cells to accumulate mRNAs that appear slightly later in development depends upon the presumptive tissue in which a given mRNA is found in the normal embryo. Messages that normally accumulate in cells at the vegetal pole also accumulate in dissociated cells either at nearly normal levels or at increased levels. In one such case, that of actin CyIIa, which is normally restricted to mesenchyme cells, in situ hybridization demonstrates that the fraction of dissociated cells expressing this message is 4- to 5-fold higher than in the normal embryo. In contrast, separated cells accumulate significant levels of a message expressed uniformly in the early ectoderm but are unable to execute accumulation and decay of different messages that distinguish oral and aboral ectodermal regions. These data are consistent with the idea that interactions among cells in the intact embryo are important for both positive and negative control of expression of different genes that are early indicators of the specification of cell fate.

Progressively restricted expression of a homeo box gene within the aboral ectoderm of developing sea urchin embryos

A homeo box-containing gene, Hbox1 is expressed in an unusual and highly conserved spatial pattern in embryos of two different species of sea urchin, Tripneustes gratilla and Strongylocentrotus purpuratus. Hybridization in situ shows that this mRNA accumulates initially throughout the aboral ectoderm; however, between blastula and pluteus stages, the region containing Hbox1 mRNA retracts gradually until only a small area around the vertex is labeled in pluteus larvae. Aboral ectoderm appears cytologically uniform and also accumulates uniform levels of other tissue-specific mRNAs. Therefore, the Hbox1 pattern reveals a previously unsuspected heterogeneity of aboral ectoderm cells and a polarity within this tissue. In S. purpuratus, the Hbox1 gene product probably is not involved in initial specification of cell fate, as this message does not achieve a significant fraction of its peak abundance until almost hatching blastula stage, well after the time aboral ectoderm cells have initiated a tissue-specific program of gene expression. RNA blot and RNase protection analyses revealed low levels of Hbox1 mRNA in all adult tissues examined. However, this message was not detectable in mature eggs, suggesting that the Hbox1 gene does not have a maternal function. In addition to highly conserved spatial and temporal patterns of expression, the homeo box genes of these two urchin species also are conserved highly in sequences outside the homeo domain, despite the divergence of these two species (30-45 my). Two notable features of the protein shared with several vertebrate homeo proteins are a short conserved sequence encoded by an exon upstream of that encoding the homeo domain and a large region of high serine and proline content.

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.

A histone H1 protein in sea urchins is encoded by a poly(A)+ mRNA

Typical histone genes lack intervening sequences and encode small mRNAs (400-800 nucleotides) with short leader and trailer regions. Most histone mRNAs are not polyadenylylated but rather terminate in a highly conserved stem and loop structure. The early, late, and testis-specific histone genes of sea urchins, described to date, have this typical histone gene structure. We have identified an unusual H1 gene, H1-delta, in sea urchins that encodes a poly(A)+ mRNA. This mRNA is one of a group of polyadenylylated transcripts homologous with H1 gene probes. The sequence of H1-delta had been determined. H1-delta encodes a different H1 protein. Although the temporal expression of H1-delta mRNA is similar to that of other late H1 (beta and gamma) mRNAs, its spatial distribution at the time of maximal accumulation is distinct and confirms that H1-delta is regulated differently than other H1 genes.

Expression of a collagen gene in mesenchyme lineages of the Strongylocentrotus purpuratus embryo

We have previously described cloning of an exon of a sea urchin collagen gene and shown that its expression is temporally regulated during embryogenesis, beginning during blastula formation. We have now localized the protein encoded by the gene and the sites of its mRNA synthesis in the developing embryo. Antibody to a synthetic peptide reacts with a 208,000 Mr protein that is digestible by collagenase. Fractionation of pluteus stage embryos demonstrates that the protein is localized primarily with cells that form the syncytium of primary mesenchyme that elaborates the larval endoskeleton; furthermore, immunofluorescence localizes the epitope to the periphery of the endoskeleton in situ. Transcripts of the gene accumulate only in mesenchyme cells, especially those of the primary mesenchyme lineage. Measurements of absolute transcript abundance show that collagen mRNA is present in blastula primary mesenchyme cells at 600-700 copies per cell and at about fourfold lower amounts in other mesenchyme cells.

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.

Sea urchin maternal and embryonic U1 RNAs are spatially segregated in early embryos

We have used in situ hybridization and cell fractionation methods to follow the distribution of U1 RNA and immunofluorescence microscopy to follow the distribution of snRNP proteins in oocytes, eggs, and embryos of several sea urchin species. U1 RNA and U1-specific snRNP antigens are concentrated in germinal vesicles of oocytes. Both appear to relocate after oocyte maturation because they are found primarily, if not exclusively, in the cytoplasm of mature unfertilized eggs. This cytoplasmic residence is maintained during early cleavage and U1 RNA is first detectable in nuclei of micromeres at the 16-cell stage. Between morula and gastrula stages the steady-state concentrations of both RNA and antigens gradually increase in nuclei and decrease in cytoplasm. Surprisingly, analysis of the distribution of newly synthesized U1 RNA shows that it does not equilibrate with the maternal pool. Instead new transcripts are confined to nuclei, while cytoplasmic U1 RNAs are of maternal origin. This lack of equilibration and the conversion of maternal U1 RNAs from nuclear species in oocytes to cytoplasmic in embryos suggests that these RNPs (or RNAs) are structurally altered when released to the cytoplasm at oocyte maturation.

Human T-cell lymphotropic virus type III infection of the central nervous system. A preliminary in situ analysis

Patients with the acquired immunodeficiency syndrome (AIDS) are subject to a spectrum of central nervous system (CNS) disorders. Recent evidence implicates the human T-cell lymphotropic virus type III (HTLV-III) in the pathogenesis of some of these illnesses, although, the cells infected by the virus have yet to be identified. Using in situ hybridization, we examined brain tissue from two patients with AIDS encephalopathy for the presence of HTLV-III RNA. In both cases, viral RNA was detected and concentrated in, though not limited to, the white matter. The CNS cells most frequently infected included macrophages, pleomorphic microglia, and multinucleated giant cells. Less frequently, cells morphologically consistent with astrocytes, oligodendroglia, and rarely neurons were also infected. The findings strengthen the association of HTLV-III with the pathogenesis of AIDS encephalopathy. In situ hybridization can be applied to routinely prepared biopsy tissue in the diagnosis of HTLV-III infection of the CNS.

Spatial patterns of metallothionein mRNA expression in the sea urchin embryo

Metallothioneins (MTs) are small, cysteine-rich proteins that bind heavy metals which induce their synthesis. Tissue fractionation of embryos at pluteus stage previously demonstrated that in the absence of added zinc, basal expression of MT mRNA is confined to ectoderm, whereas induction by zinc results in increased expression in the endoderm + mesoderm tissue fraction. Using in situ hybridization we now show that expression in the pluteus larva is restricted almost exclusively to the single cell type comprising the aboral ectoderm. Induction by Zn results in a marked accumulation of MT mRNA in gut and oral ectoderm to levels at least as high as that in aboral ectoderm. MT mRNA is also expressed in presumptive aboral ectoderm at earlier stages of normal development. In addition it is transiently expressed at variable levels in oral ectoderm and, to a lesser extent, in presumptive gut.

Activation of sea urchin actin genes during embryogenesis. Measurement of transcript accumulation from five different genes in Strongylocentrotus purpuratus

The number of molecules of mRNA transcribed from each of five different actin genes are reported for developing embryos of the sea urchin Strongylocentrotus purpuratus. Transcripts of the cytoskeletal actin genes CyI, CyIIa, CyIIb and CyIIIa, and of the muscle actin gene M, were measured in unfertilized egg and embryo RNAs of cleavage, blastula, gastrula and pluteus stages. The measurements were obtained by probe excess titrations of these RNAs, using a set of single-stranded RNA probes each identifying the mRNA transcripts of a specific actin gene. These mRNAs can be identified by their distinct 3' non-translated trailer sequences. We confirm prior observations that the prevalence of actin mRNA in the unfertilized egg is low. Cytoskeletal actin genes CyI and CyIIIa each contribute 1 X 10(3) to 2 X 10(3) maternal mRNA molecules, and CyIIb contributes less than 2 X 10(2) mRNA molecules, while no detectable maternal mRNAs derive from cytoskeletal actin gene CyIIa or the muscle actin gene M. During certain periods of development, transcripts derived from the individual cytoskeletal actin genes accumulate rapidly, with kinetics specific to each mRNA. Transcripts of the muscle actin gene are absent until after gastrulation, when the initial muscle progenitor cells are formed. At late stages of development, each of the five genes studied is represented by 10(4) to 10(5) mRNA molecules per embryo. The present measurements permit calculation of the levels of each actin mRNA species in the particular cell types in which each gene functions in the fully differentiated embryo.

Cell lineage-specific programs of expression of multiple actin genes during sea urchin embryogenesis

We have determined spatial patterns of expression of individual actin genes in embryos of the sea urchin Strongylocentrotus purpuratus. Radioactively labeled probes specific for each of five cytoplasmic-type (Cy) and the single muscle-type (M) mRNAs were hybridized in situ to sections of fixed embryos. M actin mRNA appears only late in development and is confined to a few cells associated with the coelomic rudiments. The five Cy mRNAs fall into three sets, whose times and sites of expression during development are highly distinctive. Different cell lineages express messages of one or more of these sets, but never all three. Although all Cy actin mRNAs exhibit monophasic accumulation in the RNA of whole embryos during the course of development, such accumulation in many cases results from the summation of both increases and decreases in abundance within individual sets of cells. Within the genomic linkage group CyI-CyIIa-CyIIb, expression of CyI and CyIIb appears to be co-ordinate, and quite distinct from that of CyIIa. CyI and CyIIb are expressed in all lineages at some point in embryogenesis, but confined mainly to oral ectoderm and portions of the gut of the pluteus larva. CyIIa mRNAs are restricted to mesenchyme lineages throughout late gastrula stage, and subsequently accumulate in parts of the gut. The CyIIIa and CyIIIb genes, which form a separate linkage group, are expressed only in aboral ectoderm and its precursors. Furthermore, CyIII messages are the only detectable actin mRNAs in this cell lineage after late blastula stage.

Molecular indices of cell lineage specification in sea urchin embryos

The origins of several of the differentiated cell lineages of the advanced sea urchin embryo are well defined. Cytological application of molecular probes to three lineages, those responsible for the formation of the skeleton, the gut, and the aboral ectodermal wall of the late embryo, has demonstrated expression of lineage-specific genes long before overt morphological differentiation. These observations lead to useful generalizations regarding the processes of gene regulation that underlie the molecular biology of cell lineage specification in the embryo.

Delayed accumulation of maternal histone mRNA during sea urchin oogenesis

We have used in situ hybridization and RNA blotting analysis to compare the timing of accumulation of poly(A) and alpha-subtype histone mRNA during oogenesis in the sea urchin Strongylocentrotus purpuratus. In situ hybridization with 3H-poly(U) shows that the content of poly(A) in the developing oocyte increases four- to sixfold during vitellogenesis, implying a similar increase for polyadenylated maternal RNAs. In contrast, both RNA blotting and in situ hybridization demonstrate that there is little, if any, alpha-subtype histone mRNA in large oocytes. These results suggest that these maternal mRNAs accumulate in the pronucleus of the haploid egg after completion of meiotic maturation where they are stored until their release during the breakdown of the pronucleus during prophase.

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.

Most early-variant histone mRNA is contained in the pronucleus of sea urchin eggs

Previous studies demonstrated that the pronucleus of the unfertilized sea urchin egg contains a high concentration of transcripts complementary to the early histone repeat unit (D. L. Venezky, L. M. Angerer, and R. C. Angerer (1981). Cell 24, 385-391.) In this paper, in situ hybridization techniques of improved sensitivity are used to show that these nuclear RNAs include authentic histone mRNA but not spacer-complementary sequences. It is estimated that most early-variant histone mRNA contained in the egg is, in fact, restricted to the pronucleus. These mRNAs are released to the cytoplasm at the time of nuclear breakdown of first cleavage and rapidly distribute throughout the cytoplasm.

Regulation of protein synthesis in Tetrahymena. RNA sequence sets of growing and starved cells

The complexity of messenger RNA in growing or starved Tetrahymena thermophila is similar and unusually high (approximately 4.5 X 10(7) nucleotides). The complexity of nuclear RNA in growing cells (approximately 7.8 X 10(7) nucleotides) is only about 1.7 times that of mRNA. The concentration of complex class (rare) messages (approximately 53 copies/growing cell and approximately 11 copies/starved cell) is low in comparison to the size of the cell. The concentration of complex nuclear transcripts is also very low (approximately 0.7 copies/growing cell nucleus and approximately 2.6 copies/starved cell nucleus) considering that the macronucleus contains 45 to 90 copies of each single copy sequence. The complex sequence sets found on polysomes of growing and starved cells overlap about 80% and about 60% of the complex nuclear transcripts appear to be held in common. About 60% of macronuclear single copy DNA is transcribed in one or both physiological states. Although growing and starved cells have extremely different fractions of their messages loaded onto polysomes, within each cell type the complex messages in polysomal and nonpolysomal cytoplasmic fractions are indistinguishable, suggesting that exchange may occur between loaded and unloaded messages. Although T. thermophila DNA has an unusually low G + C content (23%), sequences coding for complex RNAs have base ratios similar to those of total DNA. Therefore, codon usage in Tetrahymena must be extremely biased towards adenine- and uridine-rich codons.

Regulation of protein synthesis in Tetrahymena. Quantitative estimates of the parameters determining the rates of protein synthesis in growing, starved, and starved-deciliated cells

The calculated rate of protein synthesis for growing Tetrahymena is 360 pg/h, whereas starved cells synthesize only about 3 pg of protein/h. Within 50 min after deciliation of starved cells, the rate of protein synthesis increases to about 60 pg/h. The major mechanism to accomplish these large and rapid changes in the rate of bulk protein synthesis involves regulation of the number of messages loaded on polysomes. Logarithmically growing cells contain about 3.2 X 10(7) mRNA molecules/cell, of which approximately 60% is loaded on polysomes. Starved cells contain about 0.8 X 10(7) messages and the percentage of messages loaded is reduced to 4%. Thus, the number of loaded messages is approximately 60-fold lower in starved cells than in growing cells, although the total message content of cells in these two physiological states differs by only a factor of 4. After deciliation of starved cells, message loading increases about 10-fold. It seems likely that much of the message loaded after deciliation is derived from the large pool of nonpolysomal message in starved cells. Although large differences in message loading exist for growing, starved, and starved-deciliated cells, measurements of the rate of polypeptide elongation and the rate of message initiation indicate the translational efficiency of loaded messages (pg of protein synthesized per pg of message/unit time) is very similar under all conditions.

Localization of a family of MRNAS in a single cell type and its precursors in sea urchin embryos

Spec 1 mRNAs increase 100-fold in abundance per embryo during early sea urchin development. Previous studies indicated an enrichment of this mRNA in ectoderm fractions of gastrulae and plutei. We have determined the precise localization of this mRNA by in situ hybridization techniques. In pluteus larvae, the mRNA is highly restricted to a set of morphologically uniform ectoderm cells in the dorsal part of the embryo. The mRNA is not detectable in other regions of ectoderm or in endoderm and mesoderm. The pattern of localization is already established at the gastrula stage, before these cells are distinguishable by morphological criteria. This pattern of distribution of Spec 1 mRNA is distinct from that of bulk poly(A)+ mRNA. Measurements of the amount of Spec 1 mRNA per embryo and the number of cells containing this RNA indicate that there are about 500 Spec 1 mRNA molecules per cell at the pluteus stage and probably twice as many at the gastrula stage. These results indicate that the sensitivity of the in situ hybridization method allows detection of sequences that comprise approximately equal to 0.05% of the embryo mRNA nucleotides.

Regulation of protein synthesis in Tetrahymena: isolation and characterization of polysomes by gel filtration and precipitation at pH 5.3

The fraction of ribosomes loaded on polysomes is about 95% in logarithmically growing Tetrahymena thermophila, and about 4% in starved cells. Cytoplasmic extracts from cells in these two physiological states were used to develop column chromatographic methods for the purification of polysomes. Bio-Gel A 1.5 m was found to separate total cytoplasmic ribosomes from many soluble proteins, including RNAse, with no detectable change in the polysome size distribution. Polysomes can be separated from monosomes and non-polysomal mRNA by chromatography on Bio-Gel A 15 m without size selection. These methods can easily be adapted to large scale preparations of polysomes, even from cells where a small fraction of the ribosomes is on polysomes. A method is described for reversible precipitation of polysomes and monosomes from dilute solutions at pH 5.3 which greatly facilitates polysome isolation. Hybridization of 3H-labeled polyU to RNA isolated from column fractions has been used to demonstrate that purification of EDTA released polysomal mRNA can be performed using the column chromatography procedures described here. These methods have been employed to demonstrate that most of the cytoplasmic mRNA in log-phase Tetrahymena is loaded onto polysomes while most of the mRNA is starved cells exists in a non-polysomal form.