Homology of polytene elements between Drosophila and Zaprionus determined by in situ hybridization in Zaprionus indianus

The drosophilid Zaprionus indianus due to its economical importance as an insect pest in Brazil deserves more investigation into its genetics. Its mitotic karyotype and a line-drawing map of its polytene chromosomes are already available. This paper presents a photomap of Z. indianus polytene chromosomes, which was used as the reference map for identification of sections marked by in situ hybridization with gene probes. Hybridization signals for Hsp70 and Hsr-omega were detected, respectively, in sections 34B and 32C of chromosome V of Z. indianus, which indicates its homology to the chromosomal arm 3R of Drosophila melanogaster and, therefore, to Muller's element E. The main signal for Hsp83 gene probe hybridization was in section 17C of Z. indianus chromosome III, suggesting its homology to arm 3L of D. melanogaster and to element D of Muller. The Ubi probe hybridized in sections 10C of chromosome II and 17A of chromosome III. Probably the 17A is the polyubiquitin locus, with homology to arm 3L of D. melanogaster and to the mullerian D element, as suggested also by Hsp83 gene location. The Br-C gene was mapped in section 1D, near the tip of the X chromosome, indicating its homology to the X chromosome of D. melanogaster and to mullerian element A. The Dpp gene probe hybridized mainly in the section 32A of chromosome V and, at lower frequencies to other sections, although no signal was observed as expected in the correspondent mullerian B element. This result led to the suggestion of a rearrangement including the Dpp locus in Z. indianus, the secondary signals possibly pointing to related genes of the TGF-beta family. In conclusion, the results indicate that chromosomes X, III, V of Z. indianus are respectively correspondents to elements A, D, and E of Muller. At least chromosome V of Z. indianus seems to share synteny with the 3R arm of D. melanogaster, as indicated by the relative positions of Hsp70 and Hsr-omega, although the Dpp gene indicates a disruption of synteny in its distal region.     

Homology Requirements for Targeting Heterologous Sequences during P-Induced Gap Repair in Drosophila Melanogaster

The effect of homology on gene targeting was studied in the context of P-element-induced double-strand breaks at the white locus of Drosophila melanogaster. Double-strand breaks were made by excision of P-w(hd), a P-element insertion in the white gene. A nested set of repair templates was generated that contained the 8 kilobase (kb) yellow gene embedded within varying amounts of white gene sequence. Repair with unlimited homology was also analyzed. Flies were scored phenotypically for conversion of the yellow gene to the white locus. Targeting of the yellow gene was abolished when all of the 3' homology was removed. Increases in template homology up to 51 base pairs (bp) did not significantly promote targeting. Maximum conversion was observed with a construct containing 493 bp of homology, without a significant increase in frequency when homology extended to the tips of the chromosome. These results demonstrate that the homology requirements for targeting a large heterologous insertion are quite different than those for a point mutation. Furthermore, heterologous insertions strongly affect the homology requirements for the conversion of distal point mutations. Several aberrant conversion tracts, which arose from templates that contained reduced homology, also were examined and characterized.     

Genotype-environment interactions and the maintenance of polygenic variation

The Enhancer of wa [E(wa)] mutation was shown to interact strongly with 4 of 41 tested alleles of the white (w) eye color locus. All four of the affected w alleles result from the insertion of a transposable element. E(wa) was further localized cytogenetically. The locus lies between the breakpoints of T(Y;2)L11 and T(Y;2)H137 (section 60) in 2R. The original mutation was shown to be antimorphic on the basis of its action in the presence of additional normal copies and the ability to revert the original allele to one that mimics the effect of a deficiency for the locus. The RNA transcribed from wa was analyzed from flies segregating for E(wa) and normal. The low level of normal functional messenger RNA present in white-apricot is reduced further in Enhancer homozygotes. Total copia RNA was also examined on Northern analyses from the segregating population but no quantitative change in the major copia RNA was produced by E(wa) homozygotes compared to normal.     

Mapping of the azh locus to mouse chromosome 4.

The azh (abnormal spermatozoon headshape) mutation in the mouse, which results in abnormal sperm head formation, was demonstrated to display an autosomal recessive pattern of inheritance. The azh locus was mapped by crossing mice with the mutation on a relatively pure C57BL/6J(B6) background with C3H/HeKam and backcrossing the F1 mice to B6-azh/azh mice. Up to 60 backcross progeny were typed for azh, by microscopic examination of sperm heads, and for other markers. Eleven loci on chromosomes other than 4 showed no significant linkage with azh. Glucose 6-phosphate dehydrogenase-1 (Gpd-1), located on the distal part of chromosome 4, showed 26% recombination frequency with azh, indicating significant linkage (P less than .001). Linkage with an anonymous DNA probe for the D4Rp1 locus in the central region of chromosome 4 was then analyzed, and only a 5% recombination frequency was observed. The map location indicates that azh is distinct from other known mutations that also result in abnormal sperm heads.     

On the Identification of the ROSY Locus DNA in DROSOPHILA MELANOGASTER: Intragenic Recombination Mapping of Mutations Associated with Insertions and Deletions

DNA extracts of several rosy-mutation-bearing strains were associated with large insertions and deletions in a defined region of the molecular map believed to include the rosy locus DNA. Large-scale, intragenic mapping experiments were carried out that localized these mutations within the boundaries of the previously defined rosy locus structural element. Molecular characterization of the wild-type recombinants provides conclusive evidence that the rosy locus DNA is localized to the DNA segment marked by these lesions. One of the mutations, ry2101, arose from a P-M hybrid dysgenesis experiment and is associated with a copia insertion. Experiments are described which suggest that copia mobilizes in response to P-M hybrid dysgenesis. Relevance of the data to recombination in higher organisms is considered.     

Deletion of an insulator element by the mutation facet-strawberry in Drosophila melanogaster

Eukaryotic chromosomes are thought to be subdivided into a series of structurally and functionally independent units. Critical to this hypothesis is the identification of insulator or boundary elements that delimit chromosomal domains. The properties of a Notch mutation, facet-strawberry (fa(swb)), suggest that this small deletion disrupts such a boundary element. fa(swb) is located in the interband separating polytene band 3C7, which contains Notch, from the distal band 3C6. The fa(swb) mutation alters the structural organization of the chromosome by deleting the interband and fusing 3C7 with 3C6. Genetic studies also suggest that fa(swb) compromises the functional autonomy of Notch by allowing the locus to become sensitive to chromosomal position effects emanating from distal sequences. In the studies reported here, we show that a DNA fragment spanning the fa(swb) region can insulate reporter transgenes against chromosomal position effects and can block enhancer-promoter interactions. Moreover, we find that insulating activity is dependent on sequences deleted in fa(swb). These results provide evidence that the element defined by the fa(swb) mutation corresponds to an insulator.     

Localizing genes in Drosophila melanogaster polytene chromosomes by fluorescence in situ hybridization

This paper describes a method for the identification of single copy genes in Drosophila melanogaster polytene chromosomes, using fluorescence in situ hybridization (FISH). We demonstrate the detection of white (w) , a gene previously mapped to 1-1.5 region of the linkage map, and to 3C2 region of the cytogenetic map of X chromosome. Squash preparations of polytene chromosomes from salivary glands dissected out from third instar larvae of Drosophila melanogaster were denatured and subjected to hybridization with a digoxigenin labeled probe, corresponding to mini-white gene. The preparations were then washed and incubated with antidigoxigenin-fluorescein antibodies. After removal of the nonspecifically bound antibodies, the polytene chromosomes were counterstained with propidium iodide. Fluorescence microscopy revealed white locus in the X chromosome in a subterminal location, in agreement with the above mentioned maps. The protocol is efficient and adaptable for simultaneously multiple signal detection.     

Weakener of White (Wow), a Gene That Modifies the Expression of the White Eye Color Locus and That Suppresses Position Effect Variegation in Drosophila Melanogaster

A locus is described in Drosophila melanogaster that modifies the expression of the white eye color gene. This trans-acting modifier reduces the expression of the white gene in the eye, but elevates the expression in other adult tissues. Because of the eye phenotype in which the expression of white is lessened but not eliminated, the newly described locus is called the Weakener of white (Wow). Northern analysis reveals that Wow can exert an inverse or direct modifying effect depending upon the developmental stage. Two related genes, brown and scarlet, that are coordinately expressed with white, are also affected by Wow. In addition, Wow modulates the steady state RNA level of the retrotransposon, copia. When tested with a white promoter-Alcohol dehydrogenase reporter, Wow confers the modifying effect to the reporter, suggesting a requirement of the white regulatory sequences for mediating the response. In addition to being a dosage sensitive regulator of white, brown, scarlet and copia, Wow acts as a suppressor of position effect variegation. There are many dosage sensitive suppressors of position effect variegation and many dosage-sensitive modifiers of gene expression. The Wow mutations provide evidence for an overlap between the two types of modifiers.     

Comparative analysis of the localization and mobility of retrotransposons in sibling species Drosophila simulans and Drosophila melanogaster]

The distribution of four retrotransposon families (MDG1, MDG3, MDG4 and copia) on polytene chromosomes of different (from 9 to 15) Drosophila simulans strains is studied. The mean number of MDG1 and copia euchromatic hybridization sites (3 sites for each element) is drastically decreased in D. simulans in comparison with D. melanogaster (24 and 18 sites respectively). The mean number of MDG3 sites of hybridization is 5 in D. simulans against 12 in D. melanogaster. As for MDG4 both species have on the average about 2-3 euchromatic sites. The majority of MDG1 and copia and about a half of MDG3 euchromatic copies are localized in restricted number of sites (hot spots) on D. simulans polytene chromosomes. In D. melanogaster these elements are scattered along the chromosomes though there are some hot spots too. It appears that euchromatic copies of MDG1 and copia are considerably less mobile in D. simulans in contrast to D. melanogaster. Some common hot spots of retrotransposon localization in D. simulans and D. melanogaster were earlier described as intercalary heterochromatin regions in D. melanogaster. The level of interstrain variability of MDG4 hybridization sites is comparable in both species. Comparative blot-analysis of adult and larval salivary gland DNA shows that MDG1 and copia are situated mainly in euchromatic regions of D. melanogaster chromosomes. In D. simulans genome they are located mainly in heterochromatic regions underreplicated in salivary gland polytene chromosomes. There are interspecies differences in the distribution of retrotransposons in beta-heterochromatic chromosome regions.     

RXRA and HSPA5 map to the telomeric end of dog chromosome 9

Previous results showed that loci from human chromosome 17q (HSA17q) map to the centromeric two-thirds of dog chromosome 9 (CFA9). In these studies fluorescence in situ hybridization (FISH) using a human total chromosome 17 painting probe, indicated that the telomeric one-third of CFA9 must have homology to one or more human chromosomes other than HSA17. Here we report that this distal part of CFA9 contains a segment syntenic to the telomeric end of HSA9q and mouse chromosome 2 (MMU2). The gene loci encoding retinoid X receptor, alpha (RXRA) and heat shock protein 5 (HSPA5 or GRP78), which are found on HSA9q34 and MMU2, occupy a region on CFA9 distal to NF1 and CRYBA1. FISH of a canine specific genomic cosmid clone for RXRA demonstrated the more telomeric localization of this locus to NF1 on CFA9. A linkage map developed for the distal region of CFA9 included: NF1-(2·7 CM )-CRYBA1-(6·5 CM )-RXRA-(22 CM )-HSPA5. The next best order, RXRA-NF1-CRYBA1-HSPA5 with a difference in the log odds of 1·43 does not correspond to our findings with FISH. The most probable map order places HSPA5 distal to RXRA on CFA9 whereas in humans it lies centromeric of RXRA on HSA9q34.     

A clone contig of 12q24.3 encompassing the distal hereditary motor neuropathy type II gene

We previously assigned the disease locus for autosomal dominant hereditary motor neuropathy type II (distal HMN II) within a 13-cM interval at chromosome 12q24.3. We constructed a physical map of the distal HMN II region based on yeast artificial chromosomes (YACs), P1 artificial chromosomes (PACs), and bacterial artificial chromosomes (BACs) using an STS content mapping approach. The contig contains 26 YAC, 15 PAC, and 60 BAC clones and covers a physical distance of approximately 5 Mb. A total of 99 STS markers, including 25 known STSs and STRs, 49 new STSs generated from clone end-fragments, 20 ESTs, and 5 known genes, were located on the contig. This physical map provides a valuable resource for mapping genes and markers located within the distal HMN II region and facilitates the positional cloning of the distal HMN II gene.     

Conservation of the syntenies between porcine chromosome 7 and human chromosomes 6, 14 and 15 demonstrated by radiation hybrid mapping and linkage analysis

Comparative mapping studies facilitate the identification of genes located in quantitative trait locus (QTL) regions in domestic animals by utilizing information from the human genome. Radiation hybrid (RH) mapping is effective for this purpose because of its high resolution in ordered gene mapping on chromosomes. We constructed an RH map of pig chromosome 7, by adding 23 markers associated with genes. This RH map clearly demonstrated the mosaic of homology between pig chromosome 7 (SSC7) and human chromosomes 6, 14 and 15 at a 'gene' level, and was confirmed by linkage analysis. Clarification of the homology of SSC7 to human chromosomes will contribute to the elucidation of the gene(s) responsible for QTL detected on this chromosome.     

Genetic and Physical Mapping of the Mouse Ulnaless Locus

The mouse Ulnaless locus is a semidominant mutation which displays defects in patterning along the proximal-distal and anterior-posterior axes of all four limbs. The first Ulnaless homozygotes have been generated, and they display a similar, though slightly more severe, limb phenotype than the heterozygotes. To create a refined genetic map of the Ulnaless region using molecular markers, four backcrosses segregating Ulnaless were established. A 0.4-cM interval containing the Ulnaless locus has been defined on mouse chromosome 2, which has identified Ulnaless as a possible allele of a Hoxd cluster gene(s). With this genetic map as a framework, a physical map of the Ulnaless region has been completed. Yeast artificial chromosomes covering this region have been isolated and ordered into a 2 Mb contig. Therefore, the region that must contain the Ulnaless locus has been defined and cloned, which will be invaluable for the identification of the molecular nature of the Ulnaless mutation.     

Genetic mapping near the myd locus on mouse Chromosome 8

Myodystrophy (myd), an autosomal recessive mutation of the mouse characterized by progressive weakness and dystrophic muscle histology, maps to the central portion of Chromosome (Chr) 8 (Lane et al. J. Hered 67, 135, 1976). This portion of Chr 8 contains the genes for a mitochondrial uncoupling protein (Ucp) and kallikrein (Kal3), which map to distal 4q in the human, providing evidence for a segment of homology. Characteristics of the myd phenotype coupled with this homology suggest that myd may be a mouse homolog of facioscapulohumeral muscular dystrophy (FSHD), which maps to human 4q35. We have confirmed and expanded the region of mouse 8-human 4 homology by generating a map of Chr 8 in an interspecific backcross of C57BL/6J and a partially inbred strain derived from M. spretus. The map is comprised of the genes for Ucp, coagulation factor XI (Cf11), and chloride channel 5 (Clc5), all of which have homologs on distal human 4q, 15 microsatellite loci, and the membrane cofactor protein pseudogene (Mcp-ps). To place myd in the genetic map, 75 affected progeny from an intersubspecific backcross of animals heterozygous for myd with Mus musculus castaneus were genotyped with Chr 8 microsatellite loci. The mutation maps between D8Mit30 and D8Mit75, an interval that is flanked by genes with human homologs at distal 4q. These results are consistent with the possibility that myd is the mouse homolog of FSHD.     

A centromere-based genetic map of the short arm of human chromosome 6

A genetic map of the short arm of chromosomes 6 (6p) has been constructed with 20 genetic markers that define 16 loci, including a locus at the centromere. The 40 CEPH families and, for 4 loci, 13 additional Utah families were genotyped. All 16 loci form a single linkage group extending from near the telomeric region to the centromere, covering 159 cM (Haldane) on the female map and 94 cM on the male map. Sex differences in recombination frequencies are noted for the 6p map, with an excess occurring in males at the distal end. The genetic order of loci is consistent with their physical localization on 6p. Proximal to the three most distal loci on the map, markers are especially dense, providing an extended region on 6p useful for localizing genes of interest.