The Autosomal Chorion Locus of the Medfly Ceratitis Capitata. I. Conserved Synteny, Amplification and Tissue Specificity but Sequence Divergence and Altered Temporal Regulation

We report the isolation, full sequence characterization, amplification and expression properties of medfly chorion genes corresponding to the autosomal chorion locus of Drosophila. These genes are found adjacent to the paramyosin gene and are organized in the same order and tandem orientation as their Drosophila homologues, although they are spaced further apart. They show substantial sequence divergence from their Drosophila homologues, including novel peptide repeats and a new spacing of the tyrosines, which are known to be cross-linked in Dipteran chorion. The genes are amplified and expressed during oogenesis, as in Drosophila. Three of them are expressed in the same relative temporal order as in Drosophila but the fourth gene, the homologue of s15, shows a clear shift to an earlier expression period. This is the first known instance of changed temporal regulation in dipteran chorion genes.     

Gene regulation and evolution in the chorion locus of Bombyx mori. Structural and developmental characterization of four eggshell genes and their flanking DNA regions

We report on the detailed structural and developmental characterization of four chorion genes and a truncated pseudogene located within a 9.5 X 10(3) base chromosomal segment. These genes belong to the A and B multigene families and, like previously characterized moth chorion genes, are arranged in tightly linked pairs, which are divergently transcribed (A/B.L11 and A/B.L12). On the basis of their high degree of sequence divergence, the A genes define two distinct subfamilies, while the more homologous B genes represent different copies of the same gene type. The A.L11 and B.L11 introns are much longer, in each case because of a single inserted DNA segment that is missing from A.L12 or B.L12. The 2.1 X 10(3) base insertion in A.L11 is the first retrovirus-like transposable element characterized in Bombyx mori. The very short 5' flanking sequences of A/B.L11 and A/B.L12 (277 and 276 base-pairs) are distinct as shown by hybridization but both recur in additional chorion gene pairs, forming two respective classes that are expressed during distinctly different developmental periods. The divergently transcribed genes of each pair, which border the same 5' flanking sequence, are expressed co-ordinately, during the same developmental period. Detailed comparisons of the 5' flanking regions, and of the corresponding region of the Drosophila s15-1 chorion gene, revealed numerous, very short sequence elements that are shared. One such element, T-C-A-C-G-T, is also associated with all five sequenced Drosophila chorion genes. Some elements are repeated in a dyad symmetrical pattern, i.e. are associated with each of the two genes in a pair, while others, including T-C-A-C-G-T, occur only once per 5' flanking region, and, if functionally important, would presumably act bi-directionally on both genes of the pair.     

Isolation of two Drosophila melanogaster genes abundantly expressed in the ovary during vitelline membrane synthesis

Several genomic clones were isolated from a Drosophila library screened with cDNA prepared from abundant adult female mRNA. Cytoplasmic dot hybridizations have shown that the genes in all of these clones are expressed only in posteclosion (stages 8-14) follicles. One set of overlapping clones (lambda 20, lambda 28, and lambda 30) was localized by in situ hybridization to 66D, a previously described locus for chorion genes. Restriction mapping demonstrated that these clones contained chorion genes which had been isolated previously. Another clone, lambda 7, was mapped to chromosomal region 26A. This clone carries genes that hybridized to mRNA species similar or identical in size to the known chorion genes encompassed by lambda 28. Furthermore, one of these genes shows homology to the 66D chorion locus, apparently with the s18-1 gene. R-loop and S1-nuclease mapping indicated that lambda 7 contains two genes of 700-800 base pairs in length. Dot hybridization of cytoplasmic RNA from egg chambers demonstrated that these genes are expressed predominantly during stages 9 + 10, the time of vitelline membrane synthesis. Analysis of DNA extracted from embryos and various female tissues by dot hybridization showed that lambda 7 sequences are not amplified in the mature ovary. These results suggest that the two genes carried by lambda 7 and derived from region 26A may code for protein components of the vitelline membrane. In addition it appears that some evolutionary relatedness exists between one of these genes and a member of the chorion multigene family.     

Characterization by isoelectric focusing of chorion protein variants inDrosophila melanogaster and their use in developmental and linkage analysis

Summary Drosophila melanogaster chorion proteins are characterized on one-dimensional isoelectric focusing (IF) gels. The six major chorion components previously identified on SDS gels are shown to resolve into at least 11 components in our IF system. IF screening of 102 geographic strains ofDrosophila melanogaster revealed seven cases of variation in major chorion components. Two strains, Crimea and Falsterbo, which were monomorphic for a variant B1 protein and two strains, Skafto and Lausanne, which were monomorphic for a variant C1 protein, were chosen for further study. After IF developmental analysis of F1 hybrids had indicated that the sources of the variation resided in the structural genes for these proteins, each variant was crossed to a multiply marked and inverted strain (BLT) to determine the linkage group of the variant gene. To localize genes to more specific sites multiply marked 3rd (SKERO) or X-chromosomal (CB1) (X-PLE) mapping strains were used. In both Crimea and Falsterbo the gene for the B1 protein is located near map location 26 on the 3rd chromosome. In both Lausanne and Skafto the C1 gene is located on the X chromosome. Hence, for the first time, we have demonstrated genetically the non-linkage of two chorion genes, B1 and C1.     

Chorion gene amplification in Drosophila: A model for metazoan origins of DNA replication and S-phase control.

The mechanisms controlling duplication of the metazoan genome are only beginning to be understood. It is still unclear what organization of DNA sequences constitutes a chromosomal origin of DNA replication, and the regulation of origin activity during the cell cycle has not been fully revealed. We review recent results that indicate that chorion gene amplification in follicle cells of the Drosophila ovary is a model for investigating metazoan replication. Evaluation of cis sequence organization and function suggests that chorion loci share attributes with other replicons and provides insights into metazoan origin structure. Moreover, recent results indicate that chorion origins respond to S-phase control, but escape mechanisms that inhibit other origins from firing more than once in a cell cycle. Several identified genes that mediate amplification are critical for the cell cycle control of replication initiation. It is likely that further genetic screens for mutations that disrupt amplification will identify the cadre of proteins associated with origins and the regulatory pathways that control their activity. Furthermore, the recent development of methods to detect amplification in situ has uncovered new aspects of its developmental control. Examining this control will reveal links between developmental pathways and the cell cycle machinery. Visualization of amplifying chorion genes with high resolution also represents an opportunity to evaluate the influence of nuclear and chromosome structure on origin activity. The study of chorion amplification in Drosophila, therefore, provides great potential for the genetic and molecular dissection of metazoan replication.     

In situ study of chorion gene amplification in ovarian follicle cells ofDrosophila nasuta

The temporal and spatial pattern of replication of chorion gene clusters in follicle cells during oogenesis inDrosophila melanogaster andDrosophila nasuta was examined by [^3H thymidine autoradiography and byin situ hybridization with chorion gene probes. When pulse labelled with [³H] thymidine, the follicle cells from stage 10–12 ovarian follicles of bothDrosophila melanogaster and,Drosophila nasuta often showed intense labelling at only one or two sites per nucleus.In situ hybridization of chorion gene probes derived fromDrosophila melanogaster with follicle cell nuclei ofDrosophila melanogaster andDrosophila nasuta revealed these discrete [³H] thymidine labelled sites to correspond to the two amplifying chorion gene clusters. It appears, therefore, that in spite of evolutionary divergence, the organization and programme of selective amplification of chorion genes in ovarian follicle cells have remained generally similar in these two species. The endoreplicated and amplified copies of each chorion gene cluster remain closely associated but the two clusters occupy separate sites in follicle cell nucleus.     

The chorion genes of the medfly, Ceratitis capitata. II. Characterization of three novel cDNA clones obtained by differential screening of an ovarian library

We have isolated three new chorion cDNA clones from a Ceratitis capitata ovarian library. Their isolation was accomplished by differential screening of the library using as probes 32P-labeled poly(A)+ mRNAs obtained from hand-staged medfly choriogenic versus prechoriogenic follicles. RNA blot hybridization analysis revealed that the genes corresponding to these clones have unique temporal profiles of mRNA accumulation, restricted to specific choriogenic stages. In addition, in vitro translation products encoded by these cDNAs approximately comigrated with polypeptides synthesized de novo in culture by choriogenic follicles. All three genes are located in regions of the medfly genome that are specifically amplified in female ovaries. DNA sequence analysis has revealed that one of these clones is derived from a homolog of the Drosophila melanogaster s38 chorion gene. It appears that, although D. melanogaster and C. capitata are separated by at least 120 million years of evolution, the mechanisms by which chorion genes are expressed and regulated during development have been well maintained. We suggest that the regulatory elements controlling the expression of sex-specific (e.g., chorion) genes may be isolated and used to construct transgenic medfly strains from which females could be eliminated by negative selection; such strains could be used as part of an effort to control this agricultural pest.     

Evolution of the Autosomal Chorion Locus in Drosophila. I. General Organization of the Locus and Sequence Comparisons of Genes S15 and S19 in Evolutionarily Distant Species

We have isolated clones corresponding to the autosomal chorion locus of Drosophila melanogaster, from two distantly (D. virilis and D. grimshawi) and one closely (D. subobscura) related species. In all the species the locus is unique within the genome and encompasses the same four chorion genes and an adjacent nonchorion gene, in the same order. In all species the locus specifically amplifies in the ovary, as in D. melanogaster. We present the nucleotide sequences of DNA segments that total 8.3 kb in length and include gene s15-1 from D. subobscura, D. virilis, and D. grimshawi as well as gene s19-1 from D. subobscura and D. grimshawi. They show clearly nonuniform rates of divergence, both within and outside the limits of the genes. Highlighted by a background of extensive sequence divergence elsewhere in the extragenic region, highly conserved elements are observed in the 5' flanking DNA and might represent regulatory elements.     

A genome analysis of endoreplication in the Drosophila ovary

Gene amplification is used by follicle cells to increase the copy number of Drosophila chorion genes, which encode structural components of the eggshell. A new study by Claycomb et al. in this issue of Developmental Cell raises the possibility that gene amplification might also be used for the developmental patterning of the egg chamber and oocyte.