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.     

Analysis of cell movements and fate mapping during early embryogenesis in Drosophila melanogaster

Four spatially differentiated surface regions, called aeropyle crown, flat, stripe, and micropyle, are found on the mature eggshell (chorion). Specializations of the apical surfaces of the secretory follicular epithelial cells are implicated in the formation of regional patterns on the chorion. Some of these specializations are restricted to cells overlying certain regions; others are shared by more than one region. Differences between regions are more apparent on the surface than within the bulk of the chorion. Evidence is presented that distinct cell populations, corresponding to the regions, are present long before the start of choriogenesis. One hundred eighty-six chorion-specific polypeptides have been resolved by two-dimensional gel electrophoresis. Fifteen of these are found entirely or predominantly in the aeropyle crown and stripe regions, while eight others are restricted to the aeropyle crown region. Certain of the spatially restricted components are quite unusual in their amino acid compositions when compared with previously analyzed chorion components. Others are closely related, although clearly distinct.     

Phylogenetics of eggshell morphogenesis in Antheraea (lepidoptera: saturniidae): unique origin and repeated reduction of the aeropyle crown

Integrated phylogenetic and developmental analyses should enhance our understanding of morphological evolution and thereby improve systematists' ability to utilize morphological characters, but case studies are few. The eggshell (chorion) of Lepidoptera (Insecta) has proven especially tractable experimentally for such analyses because its morphogenesis proceeds by extracellular assembly of proteins. This study focuses on a morphological novelty, the aeropyle crown, that arises at the end of choriogenesis in the wild silkmoth genus Antheraea. Aeropyle crowns are cylindrical projections, ending in prominent prongs, that surround the openings of breathing tubes (aeropyle channels) traversing the chorion. They occur over the entire egg surface in some species, are localized to a circumferential band in many others, and in some are missing entirely, thus exhibiting variation typical of discrete characters analyzed in morphological phylogenetics. Seeking an integrated developmental-phylogenetic view, we first survey aeropyle crown variation broadly across Antheraea and related genera. We then map these observations onto a robust phylogeny, based on three nuclear genes, to test the adequacy of character codings for aeropyle crown variation and to estimate the frequency and direction of change in those characters. Thirdly, we draw on previous studies of choriogenesis, supplemented by new data on gene expression, to hypothesize developmental-genetic bases for the inferred chorion character transformations. Aeropyle crowns are inferred to arise just once, in the ancestor of Antheraea, but to undergo four or more subsequent reductions without regain, a pattern consistent with Dollo's Law. Spatial distribution shows an analogous trend, though less clear-cut, toward reduction of coverage by aeropyle crowns. These trends suggest either that there is little or no natural selection on the details of the aeropyle crown structure or that evolution toward functional optima is ongoing, although no direct evidence exists for either. Genetic, biochemical, and microscopy studies point to at least two developmental changes underlying the origin of the aeropyle crown, namely, reinitiation of deposition of chorionic lamellae after the end of normal choriogenesis (i.e., heterochrony), and sharply increased production of underlying "filler" proteins that push the nascent final lamellae upward to form the crown (i.e., heteroposy). Identification of a unique putative cis-regulatory element shared by unrelated genes involved in aeropyle crown formation suggests a possible simple mechanism for repeated evolutionary reduction and spatial restriction of aeropyle crowns.     

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.     

Organization of regionally expressed silkmoth chorion genes.

We described the organization of two silkmoth chorion genes, called E1 and E2, whose expression is largely restricted in time to the very late period of choriogenesis and in space to one of two major subpopulations of follicle cells. Using E1 and E2 clone cDNAs as probes, we showed that gene copy numbers per haploid genome remain constant throughout silkmoth development despite major changes in total DNA content per nucleus. Furthermore, gene copy numbers are the same in both cellular regions of the choriogenic follicle despite differences in nuclear size and levels of E gene expression. Southern analysis indicated between two and four copies each for E1 and E2 genes. Analysis of chromosomal clones showed that single copies of E1 and E2 are separated by about 7.5 kilobases and are transcribed from the same DNA strand. Two distinct pairs of cloned E1 and E2 genes were characterized. No other chorion genes were in their immediate vicinity.     

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.     

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.     

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.     

GrB deletion of the chorion locus of the silkmoth Bombyx mori. Localization of the left breakpoint and isolation of the deletion junction

In the silkmoth Bombyx mori, choriogenesis occurs through the developmentally controlled deposition of several related classes of chorion proteins onto the oocyte by surrounding follicular cells. In the GrB mutant strain, a distinctive family of proteins (Hc) normally expressed late in choriogenesis, as well as several proteins of middle development specificity, are missing due to the deletion of the corresponding genes from the chorion locus. In addition, a smaller set of proteins normally confined to mid-choriogenesis is found to be prolonged in expression in homozygote mutant but not heterozygote individuals. To elucidate the molecular organization of the chorion locus in the GrB genotype, we scanned a part of the wild-type locus represented by a chromosomal walk of 270,000 bases through library screening and genomic DNA hybridizations using a series of unique probes. A chromosomal clone, GrB4, whose sequences showed the expected characteristics of the deletion junction, was isolated from a partial EcoRI library of mutant genomic DNA. Through comparative hybridizations, mapping and sequencing, the precise location of one of the deletion breakpoints was identified on one of the clones mapping in the characterized part of the wild-type locus. Attempts to locate the other breakpoint in wild-type DNA and to extend the structural characterization past the deletion junction through chromosomal walking were unsuccessful, due to the apparent absence of these sequences from libraries of wild-type and mutant genomic DNA, respectively. Hybridizations of the deletion region on clone GrB4 to cDNA derived from follicular RNA indicate that no gene sequences are directly interrupted by the deletion, and reveal the presence of a gene sequence of unknown function 1000 to 5000 bases to the right of deletion junction.     

Identification and genetic localization of mRNAs from ovarian follicle cells of Drosophila melanogaster.

RNA synthesis in ovarian follicles of Drosophila melanogaster was studied by methods which eliminate experimentally induced alterations in gene expression. Gel electrophoresis of follicular RNA, labeled after injection of precursors into females, revealed qualitative and quantitative differences in synthesis during the course of oogenesis. A highly heterogeneous group of poly(A)-containing RNAs is produced during much of the course of follicular development. However, post-vitellogenic stages synthesize a small number of stage-specific poly(A)-containing RNAs. During this period, RNA synthesis is known to take place primarily in the follicle cells, which are engaged in the production of the endochorion and exochorion. Two intense bands of nonmitochondrial poly(A)⁺ RNA are labeled between stage 11 and early stage 13. The synthesis of a more heterogeneous group of very small poly(A)-containing RNAs characterizes the last part of oogenesis, stages 13 and 14. Evidence is presented to show that these RNAs are specifically localized in the follicle cells of the egg chamber. We propose that they represent mRNAs for chorion proteins. In situ hybridization of preparations of late stage poly(A)-containing RNA to salivary gland chromosomes revealed two major sites of complementarity, 7E11 and 12E, as well as several minor sites. Experiments in which RNAs were separated on gels prior to hybridization in situ suggested that both the major stage 12-specific RNA bands contained molecules which were complementary to DNA in the 7E11 region. It is particularly interesting that this site is within a small chromosomal interval known to contain the gene ocelliless. Females homozygous for ocelliless have been shown to produce structurally abnormal chorions (Johnson and King, 1974).     

Isolation of germ line-dependent female-sterile mutation that affects yolk specific sequestration and chorion formation in Drosophila

Two loci on the X chromosome have been implicated in choriogenesis by in situ hybridization of poly A-containing RNA from choriogenic eggchambers to Drosophila polytene chromosomes (A. C. Spradling and A. P. Mahowald (1979): 7E and 12E. At least two genes coding for major eggshell proteins map to region 7E (A. C. Spradling, M. E. Digan, A. P. Mahowald, M. Scott, and E. A. Craig (1980). In an effort to elucidate the functional role of the 12E gene product, 3600 EMS-treated X chromosomes were screened for recessive female-sterile mutations that mapped within the region 11F10-12F1. Four independent female-sterile mutations were recovered, three of which fell into one complementation group (fs29, fs117, and fs445). Mapping by analysis of recombinant progeny as well as of trans heterozygotes utilizing other deficiency chromosomes showed that the three noncomplementing mutations all mapped to region 12E1-12F1. Studies comparing chorion morphology and protein synthesis indicate localized perturbations in the extracellular assembly of eggshell components in mutant eggchambers. The germ line dependence of the mutations was established using germ line mosaics constructed by pole cell transplantation. Analysis of eggchamber protein accumulation patterns showed reduced amounts of yolk polypeptides (YPs) in the mutants. The elevated concentrations of YPs found in mutant hemolymph coupled with the normal YP biosynthetic patterns and active uptake of trypan blue by mutant oocytes suggest that 12E sequences play a role in yolk-specific sequestration.     

Measles virus synthesizes both leaderless and leader-containing polyadenylated RNAs in vivo

The minus-sense RNA genome of measles virus serves as a template for synthesizing plus-sense RNAs of genomic length (antigenomes) and subgenomic length [poly(A)+ RNAs]. To elucidate how these different species are produced in vivo, RNA synthesized from the 3'-proximal N gene was characterized by Northern RNA blot and RNase protection analyses. The results showed that measles virus produced three size classes of plus-sense N-containing RNA species corresponding to monocistronic N RNA, bicistronic NP RNA, and antigenomes. Unlike vesicular stomatitis virus, measles virus does not produce a detectable free plus-sense leader RNA. Instead, although antigenomes invariably contain a leader sequence, monocistronic and bicistronic poly(A)+ N-containing RNAs are synthesized either without or with a leader sequence. We cloned and characterized a full-length cDNA representing a product of the latter type of synthesis. mRNAs and antigenomes appeared sequentially and in parallel with leaderless and leader-containing RNAs. These various RNA species accumulated concurrently throughout infection. However, cycloheximide preferentially inhibited accumulation of antigenomes and leader-containing RNA but not leaderless and subgenomic RNAs late in infection, suggesting that synthesis of the former RNA species requires a late protein function or a continuous supply of structural proteins or both. These results reveal a previously undescribed mechanism for RNA synthesis in measles virus.