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.     

The effect of locus ecs in Drosophila melanogaster on fertility of females

A total of 13 ecs mutations affecting female fertility were isolated by complementation analysis. Seven of them were rearrangements with the br complementation group phenotype. Six other mutations had no cytologically detectable rearrangements and behaved as completely or partially non-complementing alleles of the ecs locus. All viable combinations of the above 13 mutations disturbed female fertility. Sterile were all fully viable compounds carrying any of these mutations and rearrangements Df (1) sta, T(1; 3)sta, Df(1)St490, previously localized on the molecular map distally to the ecs locus. According to data on location on molecular map of lesions affecting fertility, at least two elements at the ecs locus seem essential for this function: the most distal (left) cis-acting zone with no effect on viability and a sequence within the limits of the essential part of the ecs locus. Disturbance of any of these zones or their separation in the rearranged chromosomes lead to female sterility.     

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.     

Drosophila bearing the ocelliless mutation underproduce two major chorion proteins both of which map near this gene.

Two bands of putative Drosophila chorion mRNA, E3 and E4, have been shown to hybridize in situ near 7E11 (Spradling and Mahowald, 1979) within a region known to contain a gene, ocelliless, which may be involved in chorion production (Johnson and King, 1974). We have investigated the synthesis of “chorion mRNAs” and chorion proteins in flies carrying this mutation. A reduction of labeling of both E3 and E4 was observed in stage 12 egg chambers from homozygous ocelliless females. In addition, they produce mature oocytes which contain greatly reduced amounts of several major chorion proteins, including those normally produced in stage 12, c36 and c38. To investigate whether the reduction was due to a direct effect of the mutation, the genes for these proteins were mapped. Recombination analysis using electrophoretic variants of c36 and c38 showed that both proteins are coded on the X chromosome at a site between crossveinless and vermillion. Further mapping with the deficiency chromosomes Df(1)KA14 and Df(1)RA2 narrowed the region containing the structural genes to a 16 band region between 7E10 and 8A4. The ocelliless gene, as well as the site of in situ hybridization, are located within this same interval. In normal ovarian follicles, both c36 and c38 are produced in equal amounts and with the same developmental specificity (Waring and Mahowald, 1979). In the mutant, both are reduced to a similar extent. In oc⁺/oc heterozygotes, both the c36 and c38 genes on the mutant chromosome produce much less product than the corresponding genes on the oc⁺ chromosome. The cis-acting nature of the ocelliless mutation suggests that it may disrupt sequences involved in controlling the expression of the structural information for these proteins.     

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.     

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

About 160 kb of DNA were cloned from the 2B region of the X chromosome, where the early ecdysone puff develops and the ecs locus is located. On the physical map of this sequence the positions of 13 chromosome rearrangement breakpoints interfering with both puff development and the ecs locus proximally and distally, were plotted by means of in situ hybridization. The maximal size of the ecs locus is about 100 kb (between the breakpoint of In(1)Hw ^49c and the proximal end of Df(1)St472) The DNA sequences essential for normal puffing are located within the ecs locus between the In(1)br ^lt103 and Df(1)St472 breakpoints and comprise about 65 kb. Thus the puff develops as a result of ecs activation. Since Df(1)P154, which reduces the puff size and removes the proximal part of the ecs locus, does not prevent puff induction by ecdysone, while removing the distal part of the locus by Df(1)St469 completely stops development of the puff, we conclude that the regulatory zone of the locus, which reacts to hormone is located in the distal parts of both the puff and the locus, proximal to the breakpoint of In(1)br ^lt103 .Since In(1)br ^lt103 , Df(1)pn7b and Df(1)br ^R1 damage ecs but do not prevent puffing it is proposed that there is a second regulatory zone for this locus with a minimal size of 15–20 kb (between the breakpoints of Df(1)br ^R1 and In(1)br ^lt103). After cytogenetic and electron microscopic analysis of 2B puff formation it seems very likely that the site of puff formation is situated in the proximal part of 2B3-4 and after enhancement of ecs expression by hormone it spreads proximally to the 2B6 band which does not puff. When the puff regresses at puff stages (PS)10-11 its material does not condense completely and a zone of residual puffing joins the condensed material located distal to it. This material can give the impression of a separate band, designated 2B5 in Bridges' map. For convenience we propose to call the site giving rise to the puff as 2B3-5.     

Molecular mapping of murine I region recombinants: crossing over in the E beta gene

The parental origin of genomic DNA from two independently derived murine I-region recombinants, B10.ASR7 [as3] and B10.BASR1 [as4], was determined by Southern blot hybridization by using DNA probes corresponding to A beta, A alpha, 5'-E beta, 3'-E beta, and A alpha genes. New E beta gene probes were specifically constructed to make analysis of the E beta gene region definitive. Although the immune response phenotypes of the recombinants had suggested an I-A subregion cross-over, a number of restriction fragment length polymorphisms distinguishing the k and the s haplotypes showed that both recombinations mapped within a 7-kb segment of the E beta gene. The validity of these results was tested by analysis of two other H-2k/s recombinants. One of them, B10.S(8R) [as1], mapped within the same 7-kb region of the E beta gene, whereas the other, B10.BASR2 [as5], mapped outside the I-region as expected. Including those studied here, there are a dozen I region recombinants whose cross-over positions have been determined at a molecular genetic level, and all of the cross-overs occurred within the E beta gene.     

Fine cytogenetical analysis of the band 10A1-2 and the adjoining regions in the Drosophila melanogaster X chromosome

The X chromosome region 9F12-10A7 (7 bands removed by Df(1)v ^l3) was saturated with lethal, semi-lethal, visible and male sterile mutations. A total of 11 complementation groups were found. In the more narrow interval of Df(1)v ^l1 which removes 3 bands (10A1-2, 10A3, 10A4-5) 6 loci were localised. — The band 10A1-2 consists of a sereis of 5 different subunits: (i) silent DNA where no functions were found — at the distal edge of the band; (ii) and (iii) two genes: v and 1(1)BP4; (iv) silent DNA in middle of the band, (v) locus sev on the proximal edge of the band. About 70% of the band's DNA was found to be silent. — Using the set of chromosome rearrangements removing different parts of the band it was shown that these five sequences may function independently from each other.     

A Diphenol Oxidase Gene Is Part of a Cluster of Genes Involved in Catecholamine Metabolism and Sclerotization in Drosophila. II. Molecular Localization of the Dox-A2 Coding Region

Mutations at the Dox-A2 (2-53.9) locus alter the A2 component of diphenol oxidase, an enzyme having an important role in cuticle formation. This locus is in the dopa decarboxylase, Df(2L)TW130 region, which contains a cluster of at least 14 genes involved in catecholamine metabolism and the formation, sclerotization and melanization of cuticle in Drosophila. The region is subdivided by deficiencies, and localization of breakpoints in cloned DNA reveals a dense subcluster of six genes in the 23 kb proximal to Ddc. Five lethal loci distal to Ddc comprise a second such subcluster. The proximal breakpoints of deficiencies Df(2L)hk18 and Df(2L)OD15 define a 14.3- to 16.8-kb region containing Dox-A2 and l(2)37Bb, and those of Df(2L)OD15 and Df(2L)TW203 define a 9.3- to 12.1-kb region containing l(2)37Ba, l(2)37Bc and l(2)37Be. Southern blots show two of the Dox-A2 mutations are small deletions (0.1 and 1.1 kb). The Dox-A2 locus mRNA is 1.7 kb. cDNA clones indicate that the 3' end is centromere proximal and that the coding region contains at least one small intron. The Dox-A2 locus is within 3.4 to 4.4 kb of the Df(2L)OD15 breakpoint, placing four of the vital loci within a maximum of 15.5 kb. The location of Dox-A2 in a cluster of genes affecting cuticle formation is discussed.     

Nature of female sterility in mutants at the ecs locus controlling sensitivity to ecdysterone in Drosophila melanogaster]

Using interstrain level ovary transplantations function of ovaries was estimated in females bearing mutations at the ecs locus mapped in the 2B3-5 region of the X-chromosome of Drosophila melanogaster. Dissection of recipient flies and genetic analysis of their progeny demonstrated that the donor ovary in fertile flies was capable of normal functioning in the case of connection of the donor ovary in fertile flies with the recipient oviducts. Therefore, female-sterile mutations at the ecs locus are somatic line specific. SDS-PAGE electrophoresis revealed normal level of the yolk proteins in such females. Thus, the sterility of the ecs mutants may arise from abnormal morphogenesis of their genital disc, due to the loss of normal sensitivity to ecdysterone.     

The Cytogenetic Analysis of a Fractured Gene in Drosophila

The data presented in this study are derived from the analyses of Notch mutants known to be associated with visible cytological deficiencies. One mutant, Df(1)N(62b1), described as a right-side deficiency, bears a deletion that apparently initiates within the Notch locus and extends to the right as far as the locus of dm. Recombination experiments using heterozygotes of Df(1)N(62b1) with a series of intragenic point mutants within the Notch cistron suggest that this deficiency represents a deletion for the right-end portion of the gene. A consideration of the cytology of Df(1)N(62b1) supports the cytogenetic inference that, if a Notch locus-3C7 relationship is valid, the missing portion of the gene as assayed by recombination experiments has an interband position between 3C7 and 8.-The data derived from two left-side deficiencies with a genetic lesion in Notch and a deletion extending to w are somewhat equivocal, but they do support the presumed Notch locus-3C7 band relationship and thereby enhance the likelihood that Df(1)N(62b1) is correctly interpreted.-Cytogenetic information presently available suggests that, although a significant portion of the Notch cistron has a position on the salivary map identified as interband 3C7 to 8, the 3C7 band is part of the total picture of the Notch gene.     

The Genetics of the Dras3-Roughened-Ecdysoneless Chromosomal Region (62b3-4 to 62d3-4) in Drosophila Melanogaster: Analysis of Recessive Lethal Mutations

The genetic organization of interval 62B3-4 to 62D3-4 on the Drosophila third chromosome was investigated. The region (designated DRE) includes four known loci: Roughened (R; 3-1.4), defined by a dominant mutation disrupting eye morphology; the nonvital locus Aprt, structural gene for adenine phosphoribosyltransferase; Dras3, a homolog of the vertebrate ras oncogene; and 1(3)ecdysoneless (1(3)ecd), a gene that has been implicated in the regulation of larval molting hormone (ecdysteroid) synthesis. Overlapping chromosomal deletions of the region were generated by gamma-ray-induced reversion of the R mutation. Recessive lethal mutations were isolated based upon failure to complement the recessive lethality of Df(3L)RR2, a deletion of the DRE region that removes 16-18 polytene chromosome bands. A total of 117 mutations were isolated following ethyl methanesulfonate and gamma-ray mutagenesis. These and two additional define 13 lethal complementation groups. Mutations at two loci were recovered at disproportionately high rates. One of these loci is preferentially sensitive to radiation-induced mutational alterations. Additionally, an unusually low recovery rate for cytologically detectable rearrangement breakpoints within the gamma-ray-sensitive locus suggests that an interval of the DRE region closely linked to the R locus may be dominantly sensitive to position effects. Lethal phase analysis of mutant hemizygotes indicates that a high proportion of DRE-region loci (11 of 13) are necessary for larval development. Mutations in five loci cause predominantly first-instar larval lethality, while mutations in four other loci cause predominantly second-instar lethality. Mutations in two loci cause late-larval lethality associated with abnormal imaginal disc development. A temperature-sensitive allele of one newly identified complementation group blocks ecdysteroid-induced pupariation. This developmental block is overcome by dietary 20-hydroxyecdysone, suggesting that a second locus in the region in addition to l(3)ecd may play a role in the regulation of late larval ecdysteroid levels.     

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.     

Cytogenetic analysis of variegation suppressors and a dominant temperature-sensitive lethal in region 23–26 of chromosome 2L in Drosophila melanogaster

Three suppressor loci for position-effect variegation, one dominant temperature-sensitive (DTS), three Minute genes, and two recessive visible mutants (ed, tkv) have been cytogenetically localized by using duplications and deficiencies in regions 23-25 of chromosome arm 2L of Drosophila melanogaster. Two of the suppressor loci studied proved to represent haplo-abnormal genes localized in regions 23A6-23F6 and 24E2-25A1, respectively. The third one is a strong triplo-abnormal suppressor mapping in 25F4-26B9 which affects white variegation in wm4h when present in three doses. The l(2)2DTS mutation, which belongs to a group of noncomplementing dominant temperature-sensitive mutations, is localized in the 25A4-B1 region. Furthermore, two Minute genes have been localized in region 24 that are included in Df(2L)M11 and can be separated employing translocation (Y;2)P8 (24E2-4): M(2)LS2 in 24D3-4-24E2-4, and M(2)z in 24E4-5-24F5-7. A third Minute gene (M(2)S1) is localized in 25C3-8-25C9-D1. The usefulness of the isolated chromosomal rearrangements for further genetic studies of region 23-26 is discussed.     

Defects in embryogenesis in mutants associated with the antennapedia gene complex of Drosophila melanogaster

Embryogenesis in individuals with mutations or deficiencies of the genes in the polytene interval 84A-84B1,2 of Drosophila melanogaster was examined using scanning electron microscopy (SEM). The developmental function of this region of chromosome 3 is of particular interest since it contains the Antennapedia Gene Complex (ANT-C), a gene cluster that includes the homoeotic proboscipedia (pb), Sex combs reduced (Scr), and Antennapedia (Antp) loci. The results of SEM studies, clonal analyses, and temperature-shift experiments show that the fushi tarazu (ftz) and zerknullt (zen) genes, which map between pb and Scr, are involved in processes initiated during embryogenesis. The activity of ftz+ appears to be required within the first 4 hr of development for the establishment of the proper number of segments in the embryonic germ band. Individuals with ftz mutations or deficiencies produce only half the normal number of segments. Each of the segments is twice the normal width and is apparently comprised of cells that would normally form two separate metameres. The zen allele is required from about 2-4 hr of embryogenesis. Mutations of this gene result in disturbances of morphogenetic movements during gastrulation. The mutant phenotype is characterized by the absence of the optic lobe, defects in involution of the head segments, and in some cases, failure of germ band elongation. A requirement during embryogenesis for the activities of other genes residing in the 84A-84B1,2 polytene interval is suggested by the phenotypes of individuals heterozygous or homozygous for chromosomal deficiencies. Using the deficiencies Df(3R)AntpNs+R17, Df(3R)Scr, and Df(3R)ScxW+RX2, we examined the effects of deleting the distal portions or all of the 84A-84B1,2 interval. The defects in deletion heterozygotes suggest that the wild-type activity of some gene(s) other than zen, within or just adjacent to the 84B1,2 doublet, is required to complete normal head involution. The deletion of all the loci in the 84A5-84B1,2 interval results in grossly abnormal morphology and morphogenesis of the gnathocephalic appendages of the embryo. From these studies we conclude that mutations and deficiencies of genes associated with the ANT-C have profound effects on embryogenesis. The mutant phenotypes suggest, in addition to ensuring proper segment identity, the wild-type alleles of the 84A-84B1,2 genes are necessary for normal segmentation and elongation of the germ band and normal head involution.