Drosophila melanogaster eggshell development: Localization of the s19 chorion gene

Summary Further IF screening ofDrosophila melanogaster geographic strains has revealed a variant of the s19 major chorion protein. Developmental analysis of F1 hybrids indicates that the source of the variation is found in the structural gene for this protein. The linkage group of the variant gene was determined to be the third, and the gene was localized by several methods of recombination analysis. The s19 gene was found to be tightly linked to thesepia locus, as had been previously found for the s18 gene (Yannoni and Petri 1980). Lack of recombination between the s19 and s18 genes in double heterozygotes suggested that these two genes are within 0.3 map units of each other. Although more precise localization of the s19 gene failed, the s18 gene could be more specifically located to the right ofsepia, betweensepia andhairy. Contrary to our prediction (ibid.), the s19 and s18 genes have been found to be tightly linked in spite of the fact that they display somewhat different developmental stage specificity.     

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.     

Localization of a gene for a minor chorion protein in Drosophila melanogaster: a new chorion structural locus

A minor chorion protein (called s70) with an approximate molecular weight of 70,000 D has been characterized in Drosophila melanogaster. The Staket geographic strain was found to carry an electrophoretic variant of this eggshell component and was used to determine the chromosomal location of the s70 gene. Our results establish a new locus for a chorion gene near yellow on the X chromosome and represent the first mapping of a quantitatively minor eggshell protein.     

Cytogenetical analysis of the 2B3-4-2B11 region of the X chromosome of Drosophila melanogaster

Summary Of 13 ecs mutations, which affect female fertility, as revealed by complementation analysis, 7 are chromosome rearrangements involving the br complementation group. The other six show no cytologically detectable rearrangements and behave as completely or partially noncomplementing ecs alleles. All viable combinations of these 13 mutations were characterized by partial or complete female sterility. Viable heterozygotes carrying any of these mutations and the rearrangements Df(1)sta, T(1,3)sta, Df(1)St490, previously localized distal to the ecs locus, were also sterile. Using deletions and an electrophoretic mobility variant from the Staket strain, a minor chorion gene S70 has been mapped. It had been thought this gene was located in the 2B3-5 region, and corresponded to the ecs locus. However, in the present study, this gene was shown to map in the region removed by Df(1)sta (1E1-2-2B3-4) but outside that removed by Df(1)At127 (1E1-2-2A1-2), i.e. within the 2A1-2-2B3-4 region which is distal to the ecs locus. Rearrangements and point mutations at the ecs locus that result in female sterility had no effect on synthesis of the chorion protein s70. It may therefore be suggested that the chorion protein gene is not functionally associated with the ecs locus and that sterility is caused not by disruptions of the chorion protein gene but by lesions in the ecs gene itself. Thus, an ecs product, which controlls cell sensitivity to ecdysterone is also necessary for female fertility. Data on the locations of lesions affecting female fertility indicate that at least two elements at the ecs locus are essential for this function: a cis-acting distal zone with no effect on viability and a sequence within the essential part of the ecs locus. A defect in either of these zones or their separation by chromosomal rearrangement leads to female sterility.     

Genetic variability of the tumorous-head maternal effect in Drosophila melanogaster

Summary The tumorous-head maternal effect in Drosophila melanogaster is produced by a recessive gene (tuh-1) in chromosome 1. Polymorphism exists at this locus. This maternal effect, which is part of the normal variation found in this species, is detected with the aid of a mutant gene. In the presence of the maternal effect, a semi-dominant mutant gene (tuh-3) causes homoeotic changes in the eye-antennal imaginal discs. The phenotype in the adult is known as the tumorous-head abnormality. The mutant gene, which is located in the right arm of chromosome 3, is characterized by reduced penetrance. Using the penetrance of the mutant gene as the criterion, the results of these experiments show that the level of the maternal effect activity is influenced remarkably by modifiers present in wild type strains. The assay is to mate females homozygous for tuh-1 with males homozygous for tuh-3 and to determine the percent of the offspring showing the tumorous head abnormality. Using this procedure, it was observed that parental females with various combinations of chromosomes 1 and 3 from Lausanne and Stephenville wild type strains show great variability in the level of maternal effect activity. Modifiers in chromosome 1 and 3 from the Stephenville strain increase the level of the maternal effect activity. The level is reduced if these chromosomes are replaced by those from the Lausanne strain. A major locus in chromosome 3 is in the same region occupied by clusters of functionally related genes with regulating action. These results demonstrate that the penetrance of a mutant gene, which acts during embryogenesis, is influenced by modifiers which act during oogenesis.This investigation was supported by Public Health Service Research Grant GM 18664 to Arizona State University from the National Institute of General Medical Sciences     

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.     

Multiple structural genes for mouse amylase

Salivary and pancreatic amylases from the mouse show both structural and quantitative genetic variation encoded within a gene complex on chromosome 3. Two fundamental questions prompted by this variation are whether salivary and pancreatic amylases are derived from different structural genes and whether multiple structural genes are causing the quantitative variation observed in each of the two amylases. These questions were approached by comparing the amylase protein from 12 congenic lines carrying amylase gene complexes derived from different origins. The amylases were purified by affinity chromatography employing the inhibitor cyclohepta-amylose and characterized in terms of amino acid composition, specific activity, molecular weight, and heat stability. They were analyzed by native electrophoresis in polyacrylamide gels and by peptide mapping employing both cyanogen bromide cleavage and restricted proteolysis in the presence of dodecylsulfate. By these techniques, many differences in the structure of pancreatic amylase that were not reflected in the salivary amylase were found among mouse strains. Likewise, a distinct salivary amylase variant was found. These results suggest that independent structural genes exist for the two amylases. Furthermore, by all criteria used, pancreatic amylase from single strains exhibits molecular heterogeneity, whereas heterogeneity was never found for salivary amylase. We conclude that at least four structural genes code for pancreatic amylase while only a single gene, different from any of the pancreatic genes, codes for salivary amylase.This work was supported by grants from the Danish Natural Science Research Council and a grant from the United States Public Health Service (Grant GM-19521). Part of the study was made during a 1-month visit of A. J. L. in Aarhus, which was supported by grants from NATO and the University of Aarhus.     

Silk moth chorion pseudogenes: Hallmarks of genomic evolution by sequence duplication and gene conversion

The part of the genetic locus of the domesticated silk moth,Bombyx mori, in which high cysteine (Hc) chorion genes of late developmental specificity reside contains regions encompassing genelike sequences which exhibit properties distinct from those of functional Hc genes. One of these regions has been characterized and shown to contain a chorion pseudogene, ψHcB.15, which shares pronounced similarities with a transcribed chorion pseudogene, ψHcB.12/13, which was characterized previously. Both pseudogenes are homologous to HcB chorion genes but bear multiple single nucleotide substitutions and short segmental mutations (insertions and deletions) which introduce translational frame shifts and termination codons in the coding regions. Structural characteristics unique to the two pseudogenes suggest that ψHcB.15 was generated first from a functional HcB gene and gave rise subsequently to ψHcB 12/13 as a result of a sequence duplication event. The two pseudogenes can be distinguished from each other by the presence of distinct regions of similarity to the consensus sequence of functional HcB genes which appear to have arisen from gene-conversionmediated correctional events. These findings lend support to the hypothesis that chorion pseudogene sequences represent reservoirs of genetic information that participates in the evolution of the chorion locus rather than relics of inactivated genes passively awaiting extinction. Presented at the NATO Advanced Research Workshop onGenome Organization and Evolution, Spetsai, Greece, 16–22 September 1992     

The Genetic and Cytogenetic Localization of the Three Structural Genes Coding for the Major Protein of Drosophila Larval Serum

The alpha, beta and gamma polypeptides that make up Drosophila Larval Serum Protein-1 seem to be coded for by genes that have evolved by duplication of a common ancestral gene. We have found variants of all three polypeptides, and these are variants of the coding sequences. The alpha-chain variant mapped to 39.5 on the X chromosome and to the polytene interval 11A7-11B9. The beta-chain variant mapped to 1.9 on chromosome 2L and to 21D2-22A1. The gamma-chain variant was mapped as 0.13 map units from the tip of chromosome 3L or to --1.41 with respect to ru, which has been defined as 0.0, and to 61A1-61A6.     

Drosophila vitelline membrane cross-linking requires the fs(1)Nasrat, fs(1)polehole and chorion genes activities

Abstract. During the final step of Drosophila vitelline membrane formation, the structural proteins composing this layer become cross-linked by covalent bonds. In the present report, we analyzed the vitelline membrane cross-linking in mutants having defects either in this layer or in the chorionic layers. In the fs(1)Nasrat and fs(1)polehole mutant alleles conferring defects in vitelline membrane formation, disruption of vitelline membrane cross-linking was observed, indicating the involvement of these two genes in the process. On the contrary, in the fs(1)Nasrat and fs(1)polehole alleles showing defects only at the termini of the embryo the vitelline membrane is properly formed, confirming a multifunctional activity of their gene products. Altered vitelline membrane cross-linking was also detected in a mutant of the chorion protein gene Cp36and in the chorion amplification mutant fs(1)K1214, suggesting a role of the structural components of chorion layers in the process of vitelline membrane hardening.     

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.     

The cephalochordate Branchiostoma genome contains 26 intermediate filament (IF) genes: Implications for evolution of chordate IF proteins

We analyzed the draft genome of the cephalochordate Branchiostoma floridae (B. floridae) for genes encoding intermediate filament (IF) proteins. From 26 identified IF genes 13 were not reported before. Four of the new IF genes belong to the previously established Branchiostoma IF group A, four to the Branchiostoma IF group B, one is homologous to the type II keratin E2 while the remaining four new IF sequences N1 to N4 could not be readily classified in any of the previously established Branchiostoma IF groups. All eleven identified A and B2-type IF genes are located on the same genomic scaffold and arose due to multiple cephalochordate-specific duplications. Another IF gene cluster, identified in the B. floridae genome, contains three keratins (E1, Y1, D1), two keratin-like IF genes (C2, X1), one new IF gene (N1) and one IF unrelated gene, but does not show any similarities to the well defined vertebrate type I or type II keratin gene clusters. In addition, some type III sequence features were documented in the new IF protein N2, which, however, seems to share a common ancestry with the Branchiostoma keratins D1 and two keratin-related genes C. Thus, a few type I and type II keratin genes existed in a common ancestor of cephalochordates and vertebrates, which after separation of these two lineages gave rise to the known complexities of the vertebrate cytoplasmic type I–IV IF proteins, as well as to the multiple keratin and related IF genes in cephalochordates, due to multiple gene duplications, deletions and sequence divergences.     

Relationship between the female fertility function of the ecs locus and the gene for a minor chorion s70 protein of Drosophila melanogaster

The staket strain carrying an electrophoretic variant of the minor chorion protein was used to determine the chromosomal location of the s70 gene. The gene was shown to locate within the Df(1)sta (1E1-2-2B3-4) and outside the Df(1)At127 (1E1-2-2A1-2). Therefore, the s70 chorion gene resides within the region 2A1-2-2B3-4 on the X-chromosome, i.e. outside the ecs locus. Female-sterile mutations of the ecs locus do not interfere with expression of the chorion gene.     

Major chorion proteins and their crosslinking during chorion hardening in Aedes aegypti mosquitoes

The chorion of Aedes aegypti eggs undergoes a hardening process following oviposition and individual chorion proteins become insoluble thereafter. Our previous studies determined that peroxidase-catalyzed chorion protein crosslinking and phenoloxidase-mediated chorion melanization are primarily responsible for the formation of a hardened, desiccation resistant chorion in A. aegypti eggs. To gain further understanding of peroxidase- and phenoloxidase-catalyzed biochemical processes during chorion hardening, we analyzed chorion proteins, identified three low molecular weight major endochorion proteins that together constituted more than 70% of the total amount of endochorion proteins, and assessed their insolubilization in relation to phenoloxidase- and peroxidase-catalyzed reactions under different conditions. Our data suggest that the three low molecular weight endochorion proteins undergo disulfide bond crosslinking prior to oviposition in A. aegypti eggs, and that they undergo further crosslinking through dityrosine or trityrosine formation by peroxidase-catalyzed reactions. Our data suggest that chorion peroxidase is primarily responsible for the irreversible insolubilization of the three major endochorion proteins after oviposition. The molecular mechanisms of chorion hardening are also discussed.     

Identification and time of synthesis of chorion proteins in Drosophila melanogaster.

The chorion of Drosophila melanogaster consists of proteins secreted by the follicular epithelium during late oogenesis. Petri, Wyman and Kafatos (1976) have described six major protein components of the Drosophila chorion and reported the synthesis of these proteins in vitro by mass-isolated egg chambers. We have used two-dimensional gel electrophoresis to identify approximately twenty components in highly purified chorion preparations. The synthesis patterns of these proteins in vivo were determined by isolating egg chambers of different developmental stages from flies injected with 14C amino acids. Chorion proteins constitute a large fraction of the protein synthesized by ovarian egg chambers in stages 12--14. The sizes and times of synthesis of the chorion proteins correlate closely with the production of poly(A)-containing RNAs by the follicle cells (Spradling and Mahowald, 1979).