Transcription of three actin genes and a repeated sequence in isolated nuclei of sea urchin embryos

Specification of cell fate in the sea urchin embryo: summary and some proposed mechanisms

An early set of blastomere specifications occurs during cleavage in the sea urchin embryo, the result of both conditional and autonomous processes, as proposed in the model for this embryo set forth in 1989. Recent experimental results have greatly illuminated the mechanisms of specification in some early embryonic territories, though others remain obscure. We review the progressive process of specification within given lineage elements, and with reference to the early axial organization of the embryo. Evidence for the conditional specification of the veg2 lineage subelement of the endoderm and other potential interblastomere signaling interactions in the cleavage-stage embryo are summarized. Definitive boundaries between mesoderm and endoderm territories of the vegetal plate, and between endoderm and overlying ectoderm, are not established until later in development. These processes have been clarified by numerous observations on spatial expression of various genes, and by elegant lineage labeling studies. The early specification events depend on regional mobilization of maternal regulatory factors resulting at once in the zygotic expression of genes encoding transcription factors, as well as downstream genes encoding proteins characteristic of the cell types that will much later arise from the progeny of the specified blastomeres. This embryo displays a maximal form of indirect development. The gene regulatory network underlying the embryonic development reflects the relative simplicity of the completed larva and of the processes required for its formation. The requirements for postembryonic adult body plan formation in the larval rudiment include engagement of a new level of genetic regulatory apparatus, exemplified by the Hox gene complex.

Transcripts containing the sea urchin retroposon family 1 (SURF1) in embryos of the sea urchin Anthocidaris crassispina

We isolated two cDNAs, termed D7 and C2 in the present study, from a cDNA library of the 16-cell embryo of the sea urchin Anthocidaris crassispina. The nucleotide sequence was determined completely for D7, and partially for C2. D7 does not have any significant open reading frames. Both D7 and C2 contain a common sequence that is 62% homologous to the sea urchin retroposon family 1 (SURF1). The SURF1 is a short interspersed repetitive element identified from the sea urchin Strongylocentrotus purpuratus, and is reported to be transcribed by RNA polymerase III. The structural feature of D7 and C2, however, suggests that they may be transcribed by RNA polymerase II. RT-PCR analyses revealed that (1) both D7 and C2 transcripts exist as a maternal RNA in the egg, (2) they appear evenly distributed in the 16-cell embryo, and (3) C2 transcripts are present throughout the development up to the gastrula, while D7 transcripts decrease in amount after the early cleavage stage.

Altering cell fates in sea urchin embryos by overexpressing SpOtx, an orthodenticle-related protein

While many general features of cell fate specification in the sea urchin embryo are understood, specific factors associated with these events remain unidentified. SpOtx, an orthodenticle-related protein, has been implicated as a transcriptional activator of the aboral ectoderm-specific Spec2a gene. Here, we present evidence that SpOtx has the potential to alter cell fates. SpOtx was found in the cytoplasm of early cleavage stage embryos and was translocated into nuclei between the 60- and 120-cell stage, coincident with Spec gene activation. Eggs injected with SpOtx mRNA developed into epithelial balls of aboral ectoderm suggesting that SpOtx redirected nonaboral ectoderm cells to an aboral ectoderm fate. At least three distinct domains on SpOtx, the homeobox and regions in the N-terminal and C-terminal halves of the protein, were required for the morphological alterations. These same N-terminal and C-terminal regions were shown to be transactivation domains in a yeast transactivation assay, indicating that the biological effects of overexpressing SpOtx were due to its action as a transcription factor. Our results suggest that SpOtx is involved in aboral ectoderm differentiation by activating aboral ectoderm-specific genes and that modulating its expression can lead to changes in cell fate.

Spatial and temporal information processing in the sea urchin embryo: modular and intramodular organization of the CyIIIa gene cis-regulatory system

The CyIIIa cytoskeletal actin gene of Strongylocentrotus purpuratus is expressed specifically in the aboral ectoderm. In earlier work we identified a 2.3 kb cis-regulatory region that is necessary and sufficient for correct spatial and temporal expression of a CyIIIa.CAT gene. This region includes about 20 sites of specific protein-DNA interaction, at which at least nine different transcription factors may be bound. All except two of these factors have been cloned. In this work we have analyzed by deletion or mutagenesis each specific interaction. A specific function was identified for every binding site examined. These individual functions include control of amplitude and timing of expression at different phases of embryogenesis, and control of spatial expression. We show that particular negative regulatory interactions are required to repress expression of the CyIIIa.CAT construct in oral ectoderm and in skeletogenic mesenchyme at different stages. In further experiments we determined the overall functional organization of the CyIIIa cis-regulatory system, and we show that this system is modular in its regulatory structure. The ‘proximal module’ (with respect to the transcription start site) extends upstream for about 800 base pairs, and includes nine target sites serviced by six different transcription factors. Its major role is to establish CyIIIa expression in the aboral ectoderm territory as the blastomere founder cells are specified and the oral-aboral axis is determined, and to activate the CyIIIa gene late in cleavage. The ‘middle module,’ which lies upstream of the proximal module, acquires major control of CyIIIa function after the blastula stage. It includes six target sites, serviced by four different factors. The middle module is responsible for a sharp increase in expression occurring during gastrulation, mediated by the positively acting factors that bind within it. The middle module also includes sites at which two different negatively acting spatial control factors bind, the functions of which are required for correct spatial expression late in embryogenesis. The ‘distal module’ contains a number of sites at which a positively acting factor binds, but this module exercises no spatial regulatory function. Interactions within the distal module are required for the normal levels of function of both the proximal and middle modules.

SpZ12-1, a negative regulator required for spatial control of the territory-specific CyIIIa gene in the sea urchin embryo

The CyIIIa cytoskeletal actin gene of the sea urchin Strongylocentrotus purpuratus is activated in late cleavage and expressed exclusively in the aboral ectoderm territory of the embryo. Previous gene transfer studies defined a 2.3 kb cis-regulatory region that is necessary and sufficient for correct temporal and spatial expression of a CyIIIa.CAT fusion gene. In this paper, a negative regulatory element within this region was identified that is required for repression of the CyIIIa gene in skeletogenic mesenchyme cells. The repression mediated by this regulatory element takes place after initial territorial specification. A cDNA clone encoding a DNA-binding protein with twelve Zn fingers (SpZ12-1) was isolated by probing an expression library with this cis-element. Deletion analysis of the SpZ12-1 protein confirmed that a DNA-binding domain is located within the Zn finger region. SpZ12-1 is the only DNA-binding protein in embryo nuclear extract that interacts with the specific cis-target sites required for repression of CyIIIa.CAT in skeletogenic mesenchyme and is likely to be the trans factor that mediates this repression.

Territorial expression of three different trans-genes in early sea urchin embryos detected by a whole-mount fluorescence procedure

We have developed a new procedure for detection of the protein product of chloramphenicol acetyltransferase (CAT) reporter genes in whole mounted sea urchin embryos. The position of a commercially available anti-CAT antibody is visualized by video or confocal microscopy, and thus the spatial domains of exogenous reporter gene expression can be determined with regard to the intact three-dimensional structures of the embryo. We show that in pluteus stage embryos CAT protein expression patterns for SM50 . CAT or CyIIIa . CAT reporter genes are similar to those previously obtained by in situ hybridizations with radioactive probes. Taking advantage of the superior resolution of cellular CAT expression patterns using the antibody visualization method, we found for the first time that, in addition to the expression in aboral ectoderm, some cells in the ciliated band of the pluteus express CyIIIa . CAT. The expression of a new fusion construct, CyIIa . CAT, was also examined. As expected from the localization of endogenous CyIIa mRNA, CAT protein was expressed under control of the CyIIa promoter in gut and skeletogenic mesenchyme cells.

Expression of spatially regulated genes in the sea urchin embryo

Spatially controlled genes expressed in the early sea urchin embryo have been characterized, and the patterns of expression in terms of the mechanisms by which this embryo accomplishes its initial set of founder cell specifications are the subject of current discussion. Sea urchin transcription factors that have been cloned are classified with respect to their target sites and the genes they regulate. Among the best known of the sea urchin cis-regulatory systems is that controlling expression of the Cyllla gene, which encodes an aboral ectoderm-specific cytoskeletal actin. The Cyllla regulatory domain includes approximately 20 sites of DNA-protein interaction, serviced by about ten different factors. Certain of these factors are known to negatively control spatial expression, while others positively regulate temporal activation and the level of Cyllla gene expression. Differential, lineage-specific gene expression is instituted in the sea urchin embryo by mid-late cleavage, prior to any cell migration or overt differentiation, and shortly following lineage segregation.

Modulation of sea urchin actin mRNA prevalence during embryogenesis: nuclear synthesis and decay rate measurements of transcripts from five different genes

The parameters determining the prevalence of the five actin gene transcripts that are differentially expressed during embryogenesis in the sea urchin Strongylocentrotus purpuratus were measured in vivo. These results and previous studies show that the developmental appearance of the cytoskeletal actin mRNA, CyI, CyIIa, CyIIb, and CyIIIa, and the muscle-specific actin message M, is transcriptionally regulated. The cytoskeletal actin genes are activated at the 64-cell stage or shortly thereafter. At this stage the specification of the early embryonic lineages has just completed. M gene transcription was detected only after muscle cells appear in the late embryo. The CyI, CyIIa, and CyIIb genes are transcribed at a moderate rate that does not vary significantly during development. In contrast, during late cleavage CyIIIa transcripts are produced at the maximum rate observed for structural genes in this embryo. In later stages, CyIIIa transcription is reduced at least 30-fold. The rate at which new actin transcripts enter the cytoplasm was also measured. The data show that essentially all primary actin gene transcripts are processed into mature messages. Actin message stability does not change during development. The mRNA half-life of the various messages was found to range from 4 hr to greater than 14 hr.

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.

Intersecting batteries of differentially expressed genes in the early sea urchin embryo

We determined the distribution of cis-regulatory sites, previously identified in the control domain of the CyIIIa gene, in three other genes displaying diverse spatial patterns of expression in the sea urchin embryo. Competitive gel-shift reactions were carried out using probes from the CyIIIa gene, with competitor fragments isolated from the previously defined control domains of the other genes. CyIIIa is expressed only in aboral ectoderm lineages; the other genes studied were Spec1, also expressed in aboral ectoderm; CyI, expressed in many different cell types; and SM50, expressed only in skeletogenic mesenchyme. All four genes are activated at about the same time in late cleavage. Where competitive interactions indicated a functionally comparable binding site (in vitro), a sequence homology was sought, and in most cases could be identified. An interesting pattern of putative regulatory site usage emerges: Of 10 CyIIIa interactions tested, three only were unique to the CyIIIa gene with respect to the set of four genes tested; one believed on previous evidence to be a temporal regulator was shared by all four genes, and the remainder were shared in various subsets of the four genes.

Rare maternal mRNAs code for regulatory proteins that control lineage-specific gene expression in the sea urchin embryo

The prevalence of mRNAs coding for the sea urchin embryo regulatory factors P3A1 and P3A2 was measured by single-strand probe excess solution hybridization. P3A1 and P3A2 are not homologous proteins, though they both bind specifically to a particular cis-regulatory sequence. Interaction at this target site is known to be required for lineage-specific expression of an aboral ectoderm-specific gene and probably for several other genes as well. Genome blot hybridizations show that both factors are encoded by single-copy genes. Maternal mRNAs for both factors are present at less than 10(3) molecules per egg, which places them in the rare mRNA class. During development to the mesenchyme blastula stage, the amount of P3A1 mRNA (per embryo) increases severalfold while that of P3A2 remains approximately constant. Specification of the aboral ectoderm founder cells and of their initial patterns of gene expression must occur during early to mid-cleavage stage. Therefore, the regulatory proteins needed for this process must be produced by this stage. We show that the quantities of the P3A proteins that can be synthesized from the numbers of mRNA molecules present in the large blastomeres of the early embryo are sufficient to be functional, because these proteins will be accumulated in the nuclei. Thus maternal P3A1 or P3A2 proteins asre not required, nor were these detected in earlier studies. Furthermore, differential spatial (as well as temporal) distribution of both of these newly synthesized factor species could result from the unequal cleavage pattern utilized in the sea urchin egg.

Functions of maternal mRNA in early development

In this review, the types of mRNAs found in oocytes and eggs of several animal species, particularly Drosophila, marine invertebrates, frogs, and mice, are described. The roles that proteins derived from these mRNAs play in early development are discussed, and connections between maternally inherited information and embryonic pattern are sought. Comparisons between genetically identified maternally expressed genes in Drosophila and maternal mRNAs biochemically characterized in other species are made when possible. Regulation of the meiotic and early embryonic cell cycles is reviewed, and translational control of maternal mRNA following maturation and/or fertilization is discussed with regard to specific mRNAs.

Temporal and spatial transcriptional regulation of the aboral ectoderm-specific Spec genes during sea urchin embryogenesis

mRNAs for Spec 1 and Spec 2 of Strongylocentrotus purpuratus and LpS1 of Lytechinus pictus accumulate only in the aboral ectoderm of developing embryos. In vitro nuclear transcription assays were done to study the transcriptional regulation of these cell type-specific genes. Spec 1, Spec 2c, and Spec 2d genes all appeared to be transcriptionally activated at the late cleavage-early blastula stage of S. purpuratus. Differences in the relative transcription rates during development appeared to play a major role in determining the relative levels of the various Spec mRNAs. The L. pictus LpS1 gene was transcriptionally activated at a similar developmental time as the corresponding S. purpuratus genes. Nuclei from gastrula or pluteus ectodermal and endodermal/mesodermal cell fractions were used to demonstrate that Spec 1 and LpS1 genes were transcriptionally active in ectoderm nuclei but not in endoderm/mesoderm nuclei, suggesting that in vivo the Spec 1 and LpS1 genes are spatially controlled at the transcriptional level. Estimations of the absolute rate constants for Spec 1 transcription were made at the late cleavage, mesenchyme blastula, and midgastrula stages. Calculations using these rate constants and the known levels of Spec 1 mRNA suggested that Spec 1 mRNA stability gradually increased throughout development.

Sequences of the CyIIIa actin gene regulatory domain bound specifically by sea urchin embryo nuclear proteins

Expression of the CyIIIa cytoskeletal actin gene is a marker of differential gene activation in the aboral ectoderm of the early sea urchin embryo. Gene transfer experiments have defined a 2,300 nucleotide cis-regulatory domain required for the correct spatial and temporal control of this gene. This domain includes at least 20 sites at which relatively stable DNA--protein complexes form in vitro on reaction with embryo nuclear extracts. We report the nucleotide sequence of the whole regulatory domain and map the sites at which high-specificity DNA--protein interactions occur. These were located initially by gel shift assays carried out on progressive restriction digests of given subfragments of the large regulatory domain and were located more exactly by oligonucleotide gel shift competitions. Eight of the sites of specific interaction are unique within the CyIIIa regulatory domain, and the remainder consist of five different sites that occur more than once. We observe some well known sequences also found in regulatory regions of other genes, e.g., "CCAAT" and "octamer" elements. The various sites have been classified regarding putative biological function in other work, and the present studies permit an assessment of the number and complexity of interactions constituting each functional class and of the relative locations of sites of each class.

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.

The accumulation and translation of a spicule matrix protein mRNA during sea urchin embryo development

In this report we further characterize the expression of the gene that encodes the 50-kDa spicule matrix protein (SM50) during development of the sea urchin Strongylocentrotus purpuratus. Quantitative measurements of SM50 mRNA levels using the single-stranded probe excess titration technique indicate that SM50 transcript levels attain a maximum level of 8000 to 10,000 transcripts per embryo by the gastrula stage, representing 120 to 200 SM50 mRNAs per primary mesenchyme cell. Experiments analyzing run-on transcription in nuclei isolated at different stages of development indicate that the sharp increase in SM50 mRNA levels occurring at the time of primary mesenchyme ingression is concomitant with an increase in transcription of the SM50 gene. We have also analyzed the RNA sequences present on polyribosomes at different stages of development. These studies indicate that SM50 mRNA is present on polyribosomes as soon as it begins to accumulate (which is well in advance of overt spicule formation) and SM50 mRNA remains on polyribosomes through subsequent development. From estimates of the rate of SM50 protein synthesis based on these data, we calculated that the maximum amount of SM50 accumulated during development through the 4-day pluteus stage is approximately 7.4 pg/embryo. This approximation is concordant with the amount of SM50 actually found in the sea urchin embryo.

The timing of expression of four actin genes and an RNA polymerase III-transcribed repeated sequence is correct in hybrid embryos of the sea urchin species Strongylocentrotus purpuratus and Lytechinus pictus

The accumulation of the mRNAs from four Strongylocentrotus purpuratus actin genes (the single muscle gene M, and three cytoskeletal genes CyI, CyIIIa, and CyIIIb) and of transcripts from an RNA polymerase III-transcribed repeated sequence family (SURF1) was followed throughout the early development of hybrid embryos of S. purpuratus and Lytechinus pictus. Each of the actin mRNAs appeared in hybrid embryos, constructed in either direction (Sp female X Lp male and Lp female X Sp male), at approximately the same time that they appear in normal S. purpuratus embryos. Transcripts of the repeated sequence family SURF1 also appeared at the correct time in the hybrid embryos, but were present at substantially reduced levels when contributed by the paternal genome (Lp female X Sp male). The accurate temporal expression of these genes indicates that both sets of hybrid embryos contain factors which regulate the timing of their transcription.

Developmental appearance of factors that bind specifically to cis-regulatory sequences of a gene expressed in the sea urchin embryo

Previous gene-transfer experiments have identified a 2500-nucleotide 5' domain of the CyIIIa cytoskeletal actin gene, which contains cis-regulatory sequences that are necessary and sufficient for spatial and temporal control of CyIIIa gene expression during embryogenesis. This gene is activated in late cleavage, exclusively in aboral ectoderm cell lineages. In this study, we focus on interactions demonstrated in vitro between sequences of the regulatory domain and proteins present in crude extracts derived from sea urchin embryo nuclei and from unfertilized eggs. Quantitative gel-shift measurements are utilized to estimate minimum numbers of factor molecules per embryo at 24 hr postfertilization, when the CyIIIa gene is active, at 7 hr, when it is still silent, and in the unfertilized egg. We also estimate the binding affinity preferences (Kr) of the various factors for their respective sites, relative to their affinity for synthetic DNA competitors. At least 14 different specific interactions occur within the regulatory regions, some of which produce multiple DNA-protein complexes. Values of Kr range from approximately 2 x 10(4) to approximately 2 x 10(6) for these factors under the conditions applied. With one exception, the minimum factor prevalences that we measured in the 400-cell 24-hr embryo nuclear extracts fell within the range of 2 x 10(5) to 2 x 10(6) molecules per embryo, i.e., a few hundred to a few thousand molecules per nucleus. Three developmental patterns were observed with respect to factor prevalence: Factors reacting at one site were found in unfertilized egg cytoplasm at about the same level per egg or embryo as in 24-hr embryo nuclei; factors reacting with five other regions of the regulatory domain are not detectable in egg cytoplasm but in 7-hr mid-cleavage-stage embryo, nuclei are already at or close to their concentrations in the 24-hr embryo nuclei; and factors reacting with five additional regions are not detectable in egg cytoplasm and are low in 7-hr embryo nuclei, i.e., less than or equal to 10% per embryo of the level they attain in 24-hr embryo nuclei. The rise in concentration of factors of the latter class could provide the proximal cause for the temporal activation of the CyIIIa gene at the early blastula stage.

Mosaic incorporation and regulated expression of an exogenous gene in the sea urchin embryo

A fusion gene construct in which the bacterial chloramphenicol acetyltransferase (CAT) gene is controlled by CyIIIa actin gene cis-regulatory sequences was injected into unfertilized eggs of the sea urchin Strongylocentrotus purpuratus. The distribution of CAT DNA sequences was measured directly by in situ hybridization in squashed 24-hr blastula preparations derived from these eggs. Earlier studies had shown that stable mosaic incorporation of the exogenous DNA occurs during cleavage, after which the exogenous sequences replicate at approximately the pace of the host cell genomes. The fractions of embryonic cells observed in this study to include CAT DNA sequences imply that their stable incorporation into a replicating nuclear form occurs most often in a single cell at the 3rd or 4th cleavage stages, though it may occur as early as 2nd cleavage, or as late as 7th cleavage. Corroborative measurements were carried out by the same method on squashed preparations of embryos at earlier stages, and by in situ hybridizations of CAT mRNA, both in dissociated embryos and in cytological sections of 72-hr pluteus-stage embryos. Hybridizations to CAT mRNA and to CAT DNA were carried out on alternate sections of several embryos. The results confirm unequivocally that although CAT mRNA appears only in the aboral ectoderm in embryos derived from eggs injected with the CyIIIa.CAT fusion gene, the exogenous sequences are indeed present, though silent, in the various other cell types of the late embryo.

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.