Specific protein synthesis in cellular differentiation: IV. The chorion proteins of Bombyx mori and their program of synthesis

Detailed analysis of the chorion proteins of Bombyx mori reveals more than 70 components, each distinguished by electrophoretic mobility, relative abundance, and kinetics of synthesis. Many proteins are strain specific. A protein numbering system is established, based on isoelectric point and molecular weight. As in Antheraea polyphemus, chorion proteins are produced asynchronously, individual proteins showing characteristic developmental kinetics. The synthetic program is analyzed in detail. Stages of choriogenesis are defined according to the pattern of protein synthesis, and their relative and absolute durations are determined. In a few stages, synthesis of numerous protein cohorts is coordinately initiated.     

Early establishment and autonomous implementation of a developmental program controlling silkmoth chorion gene expression.

To address the question of whether prechoriogenic follicles of the silkmoth Bombyx mori have the capacity to enter choriogenesis in organ culture and define the stage at which choriogenesis becomes established as a follicle-autonomous program, we have cultured immature ovarioles dissected from developing pupae and examined the protein synthetic profiles of follicular cells of individual follicles at the end of the culture period. The protein synthetic profiles of the cultured follicles were also correlated with corresponding profiles of chorion mRNA accumulation. Our results demonstrate that the last 17 (+/- 2) vitellogenic follicles of Day 5 to 7 pupae are capable of initiating choriogenesis in organ culture. The earliest vitellogenic stage to enter choriogenesis in vitro does so after 34 (+/- 4) hr in culture and follicles entering choriogenesis in vitro are capable of proceeding through all choriogenic stages at a speed comparable to that occurring in vivo. Therefore, once the choriogenic program becomes established in follicular cells, it can be implemented autonomously in the absence of extrafollicular factors. Earlier vitellogenic stages lack this capacity, presumably because they require additional hemolymph factors to establish the choriogenic potential. Our results demonstrate that the choriogenic potential of cultured vitellogenic follicles cannot be influenced by addition of 20-hydroxyecdysone to the culture medium.     

Specific protein synthesis in cellular differentiation: VI. Temporal expression of chorion gene families in Bombyx mori strain C108

Detailed patterns of expression for putative members of 5 major chorion gene families have been obtained by separating labeled proteins using two-dimensional polyacrylamide gel electrophoresis. Proteins fall into 4 temporal cohorts called early, early middle, middle, and late on the basis of when they initiate and terminate synthesis. Proteins synthesized during the early, early middle, and late periods are highly synchronous, exhibiting abrupt onset times and relatively uniform termination times. Middle proteins begin synthesis in small groups at staggered times over a relatively long period, but most cease translation as the late proteins turn on. This data is correlated with a previous follicle staging system based on separation of newly synthesized chorion proteins by isoelectric focusing alone. The absolute timing of choriogenesis was determined in vivo, using trypan blue dye to mark vitellogenic follicles. The relative age difference between chorionating follicles was 2.2–2.6 hr; chorion biosynthesis took 4 days in all. These data are discussed in terms of patterns of activity of chorion gene families, the functions of the temporal cohorts, and regulation of the chorion multigene system.     

BmCAP,a silkmoth gene encoding multiple protein isoforms characterized by SoHo and SH3 domains: Expression analysis during ovarian follicular development

CAP/ArgBP2/vinexin family proteins, adaptor proteins characterized by three SH3 domains at their C-termini and a SoHo domain towards their N-termini, are known to regulate cell adhesion, cytoskeletal organization, and growth factor signaling. Here we present the isolation and ovarian expression of the BmCAP gene which encodes CAP/ArgBP2/vinexin family proteins in the silkmoth, Bombyx mori. Screening for full-length cDNA clones identified three mRNA isoforms, BmCAP-A1, BmCAP-A2 and BmCAP-B, which show expression throughout ovarian follicular development. Using an antibody raised against a unique region between the SoHo and SH3 domains, BmCAP-A protein isoforms were identified that show specific expression in different compartments of the ovarian follicles. Immunofluorescence staining of the cells of the follicular epithelium establishes a dynamic pattern of BmCAP-A protein localization during choriogenesis. During early choriogenesis, BmCAP-A has a diffuse localization in the cytoplasm but could also be found concentrated at the apical and basal sides at the cell–cell junctions. During late choriogenesis, the diffuse cytoplasmic staining of BmCAP-A disappears while the staining pattern at the apical side resembles a blueprint for the eggshell surface structure. We suggest that BmCAP-A isoforms have important functions during ovarian development, which involve not only the traditional roles in actin organization or cell–cell adhesion but also the regulation of secretion of chorion proteins and the sculpting of the chorion surface.     

The silkmoth chorion: Morphogenesis of surface structures and its relation to synthesis of specific proteins

The morphogenesis of four spatially differentiated surface regions of the silkmoth eggshell (chorion) has been documented and correlated with differing patterns of chorion protein synthesis within the corresponding secretory cells. During the first half of choriogenesis the polygonal pattern of ridges which cover the entire chorion appears. Regional differences in the morphology of developing ridges are not accompanied by significant protein differences, and thus presumably reflect differences in secretory cell behavior and shape. During the second half of choriogenesis expanding domes of the chorion located immediately beneath three-cell junctions of the overlying secretory surface become prominent surface features exclusively in the aeropyle crown region. Domes are composed of a thin lamellar skin and an inner buttressing “filler.” Continued filler deposition appears to cause a ripping of the lamellar skin, transforming the dome into a multiple-pronged crown that overflows with filler. Continued synthesis of lamellar chorion components elongates and strengthens the crowns until they can stand alone without the support of filler. In the aeropyle crown region, synthesis of regionally specific proteins begins in the second half of choriogenesis and accelerates until the final stages, in parallel with dome/crown formation. The more numerous proteins which are common to all regions are synthesized at approximately equal rates within all regions, and their synthesis decelerates toward the end of choriogenesis. Fifteen of the proteins (excluding filler) which are found predominantly in the aeropyle crown region may be necessary but not sufficient for crown formation, since they also occur in the stripe region (1); presumably the secretory cell surfaces mold the same components differently in the two regions. Filler appears to play an important scaffolding role in crown formation. A group of eight aeropyle crown region-specific chorion proteins which compose filler have been identified on two-dimensional gels and shown to be restricted to one of five previously described classes of chorion proteins.     

In vitro analysis of Bombyx mori early chorion gene regulation: stage specific expression involves interactions with C/EBP-like and GATA factors

This is the first attempt to identify regulatory elements that are involved in early choriogenesis of the silkworm Bombyx mori. A new cis element in the promoter region of five early chorion genes was identified. The consensus sequence of this element matches the consensus of the C/EBP DNA binding site. Moreover, this sequence interacts with a 70 kD protein (pX2) present in follicular nuclear extracts and complex formation exhibits early developmental specificity. There is strong evidence that this factor belongs to the C/EBP family. Surprisingly, the same protein binds with the same developmental specificity to a similar sequence of a late chorion gene promoter, which has been previously defined as the binding site for a putative late specific factor, BCFII. The possibility that pX2 and BCFII are isoforms or modifications of the same protein factor, which is presumably able to bind to the highly similar sequence elements of both early and late genes, is discussed. A hypothesis involving protein-protein interactions between C/EBP (pX2/BCFII) and GATA during choriogenesis is presented to explain the temporal specificity of chorion genes.     

SPECIFIC PROTEIN SYNTHESIS IN CELLULAR DIFFERENTIATION : Production of Eggshell Proteins by Silkmoth Follicular Cells

Silkmoth follicles, arranged in a precise developmental sequence within the ovariole, yield pure and uniform populations of follicular epithelial cells highly differentiated for synthesis of the proteinaceous eggshell (chorion). These cells can be maintained and labeled efficiently in organ culture; their in vitro (and cell free) protein synthetic activity reflects their activity in vivo. During differentiation the cells undergo dramatic changes in protein synthesis. For 2 days the cells are devoted almost exclusively to production of distinctive chorion proteins of low molecular weight and of unusual amino acid composition. Each protein has its own characteristic developmental kinetics of synthesis. Each is synthesized as a separate polypeptide, apparently on monocistronic messenger RNA (mRNA), and thus reflects the expression of a distinct gene. The rapid changes in this tissue do not result from corresponding changes in translational efficiency. Thus, the peptide chain elongation rate is comparable for chorion and for proteins synthesized at earlier developmental stages (1.3–1.9 amino acids/sec); moreover, the spacing of ribosomes on chorion mRNA (30–37 codons per ribosome) is similar to that encountered in other eukaryotic systems.     

Effect of the pleiotropic GrB mutation of Bombyx mori on chorion protein synthesis

The Gr^B mutation has a profound pleiotropic effect, leading in the homozygous state to the absence or extreme reduction of a substantial number of chorion proteins. The effect shows developmental specificity: most of the proteins normally synthesized beginning with stage III of choriogenesis or later, but possibly none of these normally beginning with stage II, are eliminated in the mutant. More subtle quantitative effects on certain other proteins are also observed, including prolongation of synthesis of some proteins which normally terminate at stage VIII. The proteins eliminated in the mutant are present in the heterozygote at intermediate levels, quantitatively close to those in the wild-type. The differences in chorion protein composition result from correspondingly altered protein synthesis rather than from post-translational degradation or modification. The missing proteins also fall to be synthesized in vitro when total RNA from mutant follicles is translated in the wheat germ system. It appears that as a consequence of the mutation, a set of mRNAs fails to be synthesized or accumulated. These results are consistent with the possibility that Gr^B is a regulatory mutation, or a deletion eliminating multiple chorion genes, clustered predominantly according to the developmental period of their expression.     

Heterochrony and the introduction of novel modes of morphogenesis during the evolution of moth choriogenesis

Summary Choriogenesis in silkmoths (superfamily Bombycoidea) and in a sphingid moth (super-family Sphingoidea) differ in major, but discrete, ways. In silkmoths, the predominant lamellar component assembles early in choriogenesis to form a thin framework. Subsequently, the lamellar framework is modified, first by expansion, and then by densification. Finally, ornate surface structures called aeropyle crowns form in some silkmoths, but they are absent in the species described here. In the sphingid, lamellar framework formation occurs throughout choriogenesis rather than largely during the early stages as in silkmoths. Lamellar densification occurs, but lamellar expansion and aeropyle crown formation do not. An evolutionary model is presented that accounts for the observed morphogenetic differences. Patterns of chorion protein synthesis in the sphingid differ from those in silkmoths in ways that are interpretable in light of the observed morphogenetic differences and the previously postulated functions of the proteins in silkmoths.     

Ovarian 3-hydroxy-3-methylglutaryl-CoA reductase in Blattella germanica (L.): pattern of expression and critical role in embryogenesis

In the ovary of adult Blattella germanica, the enzyme 3-hydroxy-3-methylglutaryl-CoA reductase (HMG-CoA reductase) is highly expressed in mid-late vitellogenesis, suggesting a functional link of the mevalonate pathway with choriogenesis. The inhibitor of HMG-CoA reductase, fluvastatin, applied in females in late vitellogenesis, inhibits the activity of the enzyme in the ovary and in the developing embryos within the ootheca. This does not affect choriogenesis or ootheca formation but reduces the number of larvae per ootheca. Our results suggest that fluvastatin is incorporated into the oocytes and has delayed inhibitory effects on the oviposited eggs. HMG-CoA reductase is essential for embryogenesis, but not for chorion formation.     

Specific protein synthesis in cellular differentiation: V. A secretory defect of chorion formation in the Grcol mutant of Bombyx mori

When homozygous, the Gr^col mutation of Bombyx mori causes the production of an eggshell in which most proteins are underrepresented to varying degrees. Neither the relative rates nor the timing of chorion protein synthesis appear to be affected; instead, the mutant phenotype results from the post-translational loss of normally synthesized proteins. The extent of loss of each protein correlates with its developmental timing, being maximal at early to middle stages. At the same stages, secretion appears to be deficient: chorion proteins overaccumulate within mutant cells, and slowly disappear. A preliminary electron microscopic examination has revealed the presence of mutant-specific cytoplasmic vesicles. The deficient complement of secreted proteins fails to form the highly ordered structure characteristic of normal chorion.     

Specific protein synthesis in cellular differentiation: III. The eggshell proteins of Drosophila melanogaster and their program of synthesis

The eggshell of Drosophila melanogaster is composed of a set of proteins synthesized by the follicular epithelium during the last third of oogenesis and organized into an inner zone (vitelline membrane) and an outer zone (chorion). To study these proteins, the authors developed techniques for mass-isolating follicles of mixed stages, mature (stage 14) follicles, chorion from stage 14 follicles, and chorion and vitelline membrane from laid eggs. The eggshell is composed mainly of protein and is unusually rich in proline and alanine. Six proteins of the chorion have been identified on polyacrylamide gels. The program of synthesis of these proteins was studied by incubating follicles of different developmental stages in culture with ³H-labeled amino acids and displaying the labeled proteins on gels with the aid of autofluorography. The proteins are synthesized in a specific overlapping sequence during stages 10–14, a period when chorion deposition is known to occur. In addition, putative vitelline membrane proteins have been identified by their preferential incorporation of [³H]proline and [³H]alanine during stages of active vitelline membrane synthesis.     

Cell-free translation of silkmoth chorion mRNAs: Identification of protein precursors and characterization of cloned DNAs by hybrid-selected translation

The secretory silkmoth chorion proteins are synthesized as precursors bearing signal peptides. Precursors are detected upon cell-free translation of chorion mRNAs in the wheat germ system; they are processed into products identical in size to authentic chorion proteins when translation is performed in the presence of microsomal membranes from dog pancreas. Precursors corresponding to specific protein size classes and subclasses are identified by three approaches: comparison of precursors and products encoded by stage-specific mRNAs, comparison of precursors and products encoded by mRNAs specifically hybridizing to individual chorion cDNA clones, and comparison of relative amino acid compositions of precursors and authentic chorion proteins. Translation of stage-specific mRNA preparations indicates that, in general, the developmental changes of in vivo chorion protein synthesis are based on changes in concentrations of the corresponding mRNAs. Characterization of the precursors makes it possible to identify, for any chorion DNA clone, the protein subclass, a member of which is encoded by the clone sequence.