Developmental control and evolution in the chorion gene families of insects

RNA Interference-Mediated Suppression of Ecdysone Signaling Inhibits Choriogenesis in Two Coleoptera Species

During choriogenesis in insects, chorion (eggshell) is formed by surrounding follicular epithelial cells in ovarioles. However, the regulatory endocrine factor(s) activating choriogenesis and the effect of chemical components on eggshell deserve further exploration. In two representative coleopterans, a coccinellid Henosepilachna vigintioctopunctata and a chrysomelid Leptinotarsa decemlineata, genes encoding the 20-hydroxyecdysone (20E) receptor heterodimer, ecdysone receptor (EcR) and ultraspiracle (USP), and two chitin biosynthesis enzymes UDP-N-acetylglucosamine pyrophosphorylase (UAP) and chitin synthase (ChS1), were highly expressed in ovaries of the young females. RNA interference (RNAi)-aided knockdown of either HvEcR or Hvusp in H. vigintioctopunctata inhibited oviposition, suppressed the expression of HvChS1, and lessened the positive signal of Calcofluor staining on the chorions, which suggests the reduction of a chitin-like substance (CLS) deposited on eggshells. Similarly, RNAi of LdEcR or Ldusp in L. decemlineata constrained oviposition, decreased the expression of LdUAP1 and LdChS1, and reduced CLS contents in the resultant ovaries. Knockdown of LdUAP1 or LdChS1 caused similar defective phenotypes, i.e., reduced oviposition and CLS contents in the L. decemlineata ovaries. These results, for the first time, indicate that 20E signaling activates choriogenesis in two coleopteran species. Moreover, our findings suggest the deposition of a CLS on the chorions.

Egg Coat Proteins Across Metazoan Evolution

All animal oocytes are surrounded by a glycoproteinaceous egg coat, a specialized extracellular matrix that serves both structural and species-specific roles during fertilization. Egg coat glycoproteins polymerize into the extracellular matrix of the egg coat using a conserved protein-protein interaction module-the zona pellucida (ZP) domain-common to both vertebrates and invertebrates, suggesting that the basic structural features of egg coats have been conserved across hundreds of millions of years of evolution. Egg coat proteins, as with other proteins involved in reproduction, are frequently found to be rapidly evolving. Given that gamete compatibility must be maintained for the fitness of sexually reproducing organisms, this finding is somewhat paradoxical and suggests a role for adaptive diversification in reproductive protein evolution. Here we review the structure and function of metazoan egg coat proteins, with an emphasis on the potential role their evolution has played in the creation and maintenance of species boundaries.

Analysis of developmentally regulated chorion gene promoter architecture via electroporation of silk moth follicles

In the silk moth Bombyx mori, chorion genes of the same developmental specificity are organized in divergently transcribed α/β gene pairs, sharing a common 5' flanking promoter region. This bidirectional promoter contains a complete set of cis-elements responsible for developmentally accurate gene expression. In the present paper, based on the observation that Bombyx chorion gene promoters contain cis-elements for the same transcription factors without concrete evidence on which of them are essential, we address the question as to how promoter architecture (number, orientation and position of common factor binding sites) facilitates developmentally accurate chorion gene regulation. To this end, we constructed several mutated promoter regions of an early-middle gene pair and cloned them upstream of a reporter gene to introduce these plasmid constructs into silk moth follicle epithelial cells via electroporation as an efficient and quick method for transient expression. This is the first time that an ex vivo method had been applied to test the impact of systematic cis-element mutations on a chorion gene promoter. Our results confirmed the importance of the HMGA factor and the role of the GATA factor as an early repressor, and led to a more detailed understanding of which C/EBP sites participate in the regulation of early-middle chorion gene expression.

Chorion genes: a landscape of their evolution, structure, and regulation

Differential regulation at the level of transcription provides a means for controlling gene expression in eukaryotes, especially during development. Insect model systems have been extensively used to decipher the molecular basis of such regulatory cascades, and one of the oldest such model systems is the regulation of chorion gene expression during ovarian follicle maturation. Recent experimental and technological advances have shed new light onto the system, allowing us to revisit it. Thus, in this review we try to summarize almost 40 years' worth of studies on chorion gene regulation while-by comparing Bombyx mori and Drosophila melanogaster models-attempting to present a comprehensive, unified model of the various regulatory aspects of choriogenesis that takes into account the evolutionary conservation and divergence of the underlying mechanisms.

BmVMP90, a large vitelline membrane protein of the domesticated silkmoth Bombyx mori, is an essential component of the developing ovarian follicle

We present the characterization of BmVMP90, a vitelline membrane protein (VMP) of the silkmoth Bombyx mori bearing similarities with dipteran VMPs whose existence had recently been suggested by an in silico analysis of the silkmoth genome and follicular cell RNA expression analyses. Using a specific antibody, we determine the presence of BmVMP90 protein in ovarian follicular cell extracts at the end of vitellogenesis and in vitelline membrane extracts but not in the chorion of fractionated eggshells isolated from ovulated follicles. Whole mount follicle immunofluorescence studies reveal a pattern of BmVMP90 deposition matching the «imprinted» pattern of follicular cells on the vitelline membrane surface. Antisense DNA-directed inhibition BmVMP90 expression in ex vivo cultures of early vitellogenic follicles produced a phenotype of kidney- or bean-shaped follicles with detached follicular epithelia, suggestive of the importance of BmVMP90 for the integrity of developing follicles and normal deposition of the chorion structure that follows vitelline membrane formation but no adverse effects on the execution of the follicular cell-imprinted program of choriogenesis per se.

Characterization of development-related genes for the cestode Bothriocephalus acheilognathi

Differential gene expression of mature and immature Bothriocephalus acheilognathi cestodes was analyzed using the suppression subtractive hybridization technique. Five mature-associated cDNAs were isolated and characterized. Virtual Northern blot and RT-PCR analyses confirmed that four of the five genes were upregulated in mature parasites. The sequence analysis revealed that one gene encoded the structural protein chorion precursor, and the three encoded functional proteins homologous to yolk ferritin, sodium/hydrogen exchanger and muscin-like protein. Another gene appeared to be specific to B. acheilognathi, encoding a putative metal-bound protein. Although results obtained in the present study are preliminary, the information about the five genes may provide clues for further investigation on the decline in parasite numbers during the maturation of B. acheilognathi.

Schistosoma mansonimale–female interactions

Schistosome parasites are muticellular eucaryotic organisms with a complex life cycle that involves mammalian and snail hosts. Unlike other trematode parasites, schistosomes (along with the Didymozoidae) have evolved separate sexes or dioecy. Sex is determined by a chromosomal mechanism. The dioecious state created an opportunity for the sexes to play a role in schistosome evolution that has resulted in an interesting interplay between the sexes. The classical observation, made more than 50 years ago, is that female schistosomes do not develop unless a male worm is present. Studies up through the 1990s focused on dissecting the role of the sexes in mate attraction, mate choice, mating behavior, female growth, female reproductive development, egg production, and other sex-evolved functions. In the mid-1980s, studies began to address the molecular events of male–female interactions. The classic morphological observation that female schistosomes do not complete reproductive development unless a male worm is present has been redefined in molecular terms. The male by an unknown mechanism transduces a signal that regulates female gene expression in a stage-, tissue-, and temporal-specific manner. A number of female-specific genes have been identified, along with signaling pathways and nuclear receptors, that play a role in female reproductive development. In addition, a number of host factors such as cytokines have also been demonstrated to affect adult male and female development and egg production. This review focuses on the biological interactions of the male and female schistosome and the role of parasite and host factors in these interactions as they contribute to the life cycle of Schistosoma mansoni.

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.

The biolistic method as a tool for testing the differential activity of putative silkmoth chorion gene promoters

Bombyx mori unpaired early chorion gene copies 6F6.1,.2 and.3 are exceptions to the typical organization and distribution pattern of known early ErA/ErB, middle A/B and late HcA/HcB divergently transcribed gene pairs. Contrary to such pairs, the boundaries of the 6F6 regulatory sequences are not easily defined; moreover, they share common sequence elements with the regulatory sequences of middle and late genes. In order to perform a functional study of the tissue and temporal specificity of the 6F6 putative promoter region, we decided to apply biolistics. In the present work, use of a region from the 6F6.2 5' untranslated sequence, spanning nucleotides -138 to the cap site, gave an expected expression pattern of a lacZ reporter gene. Temporal specificity was further verified by control experiments using the cloned intergenic sequence of the late gene pair HcA/B.12, which resulted in lacZ expression in late choriogenic follicles. At present, despite the recent successful germinal transgenesis of Bombyx mori, the biolistic transient expression system seems to be the most rapid technique to pursue the functional study of the promoter region of early chorion genes, including the three unconventional early 6F6 genes.

Disparate tissue-specific expression of members of the tissue kallikrein multigene family of the rat

To understand the regulatory diversity of the rat family of linked kallikrein genes, we have assayed the expression of family members in 20 major organs. Reverse transcription-polymerase chain reaction analysis using primers and hybridization probes specific for each of the 10 expressed kallikrein genes showed that no two family members share the same organ-specific pattern of expression. The only common site of expression for all 10 known active genes is the submandibular gland. The presence of the mRNA for at least one family member is detected in 19 of these 20 organs (liver excepted), from as few as three organs to as many as 18 for individual family members. For individual genes there can be more than a 10(5)-fold variation in mRNA levels among organs, from a limit of detection of slightly less than 1 mRNA molecule/10 cells to more than 10,000 mRNA molecules/cell. Despite high sequence conservation and close linkage, the members of this family are expressed in very different and complex patterns. A gradient of diversity of expression corresponds to the order of the genes within the kallikrein family locus.

The two duplicated insecticyanin genes, ins-a and ins-b are differentially expressed in the tobacco hornworm, Manduca sexta

Two gene-specific probes were generated from the unique sequences in the 3' non-coding regions of the two insecticyanin genes, ins-a and ins-b to study the developmental expression of these genes in Manduca sexta. Both genes were initially transcribed in the freshly hatched first instar larvae and then expressed in the epidermis and to a lesser degree in the fat body during every larval feeding stage. In the epidermis of the 4th and 5th instar larvae, both mRNAs appeared shortly before ecdysis and accumulated to maximal levels within a day. As the larval epidermis became pupally committed on day 3 of the 5th (final) instar, INS-a mRNA quickly decreased, whereas INS-b mRNA showed a second peak of accumulation. In the fat body, both genes showed a similar expression pattern within the 4th instar to that of the epidermis except that levels were lower and ins-b mRNA dominated. In the final instar, only ins-b mRNA was present in significant amount. These findings not only reveal that the two duplicated insecticyanin genes have diverged in their expression pattern but also demonstrate, for the first time, that fat body also expresses insecticyanin genes.

Elements controlling follicular expression of the s36 chorion gene during Drosophila oogenesis

An 84-bp proximal regulatory protein (PRR) of the Drosophila melanogaster s36 chorion gene is sufficient for directing proper temporal and spatial expression of a reporter gene in three domains of the follicle: anterior, posterior, and main body. Here we show that the fidelity of PRR-directed s36 expression is dependent on the proper dorsal-ventral differentiation of the follicular epithelium, which requires the Drosophila epidermal growth factor receptor homolog. Transgenic analysis of site-directed mutants of the PRR suggests that s36 expression is regulated by the concerted action of multiple positive activators. Several cis-acting transcriptional elements have been identified: some appear to function in a quantitative manner, while others either are essential or appear to regulate expression in particular spatial domains. The approximate locations of these regulatory elements have been defined; some map within sequences that are strongly conserved in widely divergent dipteran species. In fact, the PRR analog of the medfly Ceratitis capitata Ccs36 gene directs expression in a manner similar to the D. melanogaster s36 PRR. We propose a model for transcriptional regulation of s36 based on the prechoriogenic polarization of the follicular epithelium that surrounds the developing egg chamber.

Elements controlling follicular expression of the s36 chorion gene during Drosophila oogenesis

An 84-bp proximal regulatory protein (PRR) of the Drosophila melanogaster s36 chorion gene is sufficient for directing proper temporal and spatial expression of a reporter gene in three domains of the follicle: anterior, posterior, and main body. Here we show that the fidelity of PRR-directed s36 expression is dependent on the proper dorsal-ventral differentiation of the follicular epithelium, which requires the Drosophila epidermal growth factor receptor homolog. Transgenic analysis of site-directed mutants of the PRR suggests that s36 expression is regulated by the concerted action of multiple positive activators. Several cis-acting transcriptional elements have been identified: some appear to function in a quantitative manner, while others either are essential or appear to regulate expression in particular spatial domains. The approximate locations of these regulatory elements have been defined; some map within sequences that are strongly conserved in widely divergent dipteran species. In fact, the PRR analog of the medfly Ceratitis capitata Ccs36 gene directs expression in a manner similar to the D. melanogaster s36 PRR. We propose a model for transcriptional regulation of s36 based on the prechoriogenic polarization of the follicular epithelium that surrounds the developing egg chamber.

Three copies of the early gene 6F6 are interspersed in and around the late chorion gene cluster of Bombyx mori

The developmentally regulated chorion genes of the silkmoth, Bombyx mori, are clustered in two genetic loci (Ch1-2 and Ch3) of chromosome 2, which are separated by approximately 4 centiMorgans. Early genes are clustered in chorion locus Ch3, whereas Ch1-2 contains all of the late genes in a continuous region of 140 kb, which is sandwiched between two regions containing most of the middle chorion genes. The late-gene area has been extensively studied and was considered to contain only late genes coding for chorion proteins of exceptionally high cysteine content organized in tightly clustered alpha/beta gene pairs. In the present paper we report the unexpected presence of three dispersed copies (6F6.1, 6F6.2, 6F6.3) of an early beta-gene, which disrupts the continuity of the late locus. Hybridization data indicate that 6F6.2 corresponds to the previously characterized m6F6 cDNA clone and that 6F6.1 and 6F6.3, but not 6F6.2, are adjacent to alpha-type genes. Determination of the complete sequence of 6F6.1 and of the major exon of the A-gene near it shows that these two genes have a convergent rather than a divergent direction of transcription and thus do not constitute a typical gene pair. The sequence data further suggest that 6F6.1 is transcriptionally active. The three dispersed 6F6 gene copies are localized at points of inversion of the polarity of neighboring gene pairs and their locations in this locus indicate complex gene rearrangement events.

The possible evolutionary significance of repeat elements near and within an early chorion gene in the late chorion locus of Bombyx mori

Three beta-type early chorion gene copies (6F6.1, 6F6.2, and 6F6.3) are dispersed in the late region of chorion locus Ch1-2. Detailed analysis of the 5'-flanking region and the intron of 6F6.1 shows that they contain sequences that are homologous to Bombyx mori Bm1 repeat elements. Interestingly, the Bm1-type segment of the intron is interrupted by the insertion of a sequence that shows significant similarities with part of an intron of B. mori and Bombyx mandarina fibroin genes, and with part of the 3'-flanking region of B. mori prothoracicotropic hormone and tRNA-Glu genes; this sequence may represent a new repetitive, possibly transposable, element of B. mori. Following the Bm1-homologous sequence of the 6F6.1 5'-flanking region and preceding the gene promoter region, a short DNA segment shows sequence motifs that are also present in the ErA.1 promoter region. The occurrence of these sequences near one end or within the Bm1 repeat element is suggestive of complex sequence transfer events. Comparative analysis of known B. mori chorion alpha-gene promoters and of Bm1 repeat elements suggests, with marginal statistical significance, that these two sets of sequences contain common elements.

Structural and biochemical studies on four sex-linked chorion mutants of Drosophila melanogaster

Four female-sterile mutants, fs(1)K451, fs(1)K1214, fs(1)K575TS, and fs(1)384, were studied in terms of chorion structure and chorion protein composition. The first three of these mutants cause morphological defects, ie, substantial underproduction and disruption of the endochorion, correlated with underproduction of the six major chorion proteins, s15-s38; the phenotypes are consistent with the observation that these mutants interfere with amplification of the major chorion genes that encode the s15-s38 proteins [Orr et al.: Proc Natl Acad Sci USA 81:3773-3777, 1984; Komitopoulou et al.: Dev Genet 7:75-80, 1986]. The fourth mutant, fs(1)384, and its alleles do not interfere with production of the major chorion proteins and the morphologically detectable bulk of the endochorion but lead to failure of endochorionic organization. Apparently this complementation group is responsible for a minor chorion product, which is evidently important morphogenetically and which is processed posttranslationally in a complex manner [Bauer and Waring: Dev Biol 121:349-358, 1987].