A Cluster of Cuticle Protein Genes of Drosophila Melanogaster at 65a: Sequence, Structure and Evolution

A 36-kb genomic DNA segment of the Drosophila melanogaster genome containing 12 clustered cuticle genes has been mapped and partially sequenced. The cluster maps at 65A 5-6 on the left arm of the third chromosome, in agreement with the previously determined location of a putative cluster encompassing the genes for the third instar larval cuticle proteins LCP5, LCP6 and LCP8. This cluster is the largest cuticle gene cluster discovered to date and shows a number of surprising features that explain in part the genetic complexity of the LCP5, LCP6 and LCP8 loci. The genes encoding LCP5 and LCP8 are multiple copy genes and the presence of extensive similarity in their coding regions gives the first evidence for gene conversion in cuticle genes. In addition, five genes in the cluster are intronless. Four of these five have arisen by retroposition. The other genes in the cluster have a single intron located at an unusual location for insect cuticle genes.     

Two gene families clustered in a small region of the Drosophila genome

Three Drosophila genes that are clustered within 8 X 10(3) bases of DNA at the chromosomal region 44D have been identified and mapped, and the gene cluster entirely sequenced. The three genes are 55 to 60% homologous in DNA sequence. One gene contains an intron in its 5'-proximal protein coding sequence while the other two have none at this position; similarly, another gene has an intron in its 3'-proximal protein coding sequence which is not found in the other genes. All three genes are abundantly expressed together in Drosophila first, second, and early third instar larval stages and in adults, but they are not abundantly expressed in either embryonic, late third instar larval, or pupal stages. This gene family lies 11 X 10(3) bases away from another cluster containing four Drosophila larval cuticle protein genes plus a pseudogene. The cuticle genes are all abundantly expressed throughout third instar larval development. Thus, at least seven protein-coding genes and one pseudogene lie within 27 X 10(3) bases of DNA. Moreover, two small gene families can lie adjacent on a chromosome and exhibit different patterns of developmental regulation, even though individual genes within each clustered family are co-ordinately expressed.     

Mutations affecting the pattern of the larval cuticle inDrosophila melanogaster

Summary The present report describes the recovery and genetic characterization of mutant alleles at zygotic loci on the third chromosome ofDrosophila melanogaster which alter the morphology of the larval cuticle. We derived 12600 single lines from ethyl methane sulfonate (EMS)-treatedst e orrucuca chromosomes and assayed them for embryonic lethal mutations by estimating hatch rates of egg collections. About 7100 of these lines yielded at least a quarter of unhatched eggs and were then scored for embryonic phenotypes. Through microscopic examination of unhatched eggs 1772 lines corresponding to 24% of all lethal hits were classified as embryonic lethal. In 198 lines (2.7% of all lethal hits), mutant embryos showed distinct abnormalities of the larval cuticle. These embryonic visible mutants define 45 loci by complementation analysis. For 32 loci, more than one mutant allele was recovered, with an average of 5.8 alleles per locus. Complementation of all other mutants was shown by 13 mutants. The genes were localized on the genetic map by recombination analysis, as well as cytologically by complementation analysis with deficiencies. They appear to be randomly distributed along the chromosome. Allele frequencies and comparisons with deficiency phenotypes indicate that the 45 loci represent most, if not all, zygotic loci on the third chromosome, where lack of function recognizably affects the morphology of the larval cuticle.     

Genetic regulation of the quinic acid utilization (QUT) gene cluster in Aspergillus nidulans

A large number of quinic acid non-utilizing qut mutants of Aspergillus nidulans deficient in the induction of all three quinic acid specific enzymes have been analysed. One class the qutD mutants, are all recessive and are non-inducible at pH 6.5 due to inferred deficiency in a quinate ion permease. Two regulatory genes have been identified. The QUTA gene encodes an activator protein since most qutA mutants are recessive and non-inducible although a few fully dominant mutants have been found. The QUTR gene encodes a repressor protein since recessive mutations are constitutive for all three enzyme activities. Rare dominant non-inducible mutants which revert readily to yield a high proportion of constitutive strains are inferred to be qutR mutants defective in binding the inducer. The gene cluster has been mapped in the right arm of chromosome VIII in the order: centromere - greater than 50 map units - ornB - 12 map units - qutC (dehydratase)-0.8 map units-qutD (permease), qutB (dehydrogenase), qutE (dehydroquinase), qutA (activator)-4.4 map units - qutR (repressor)-20 map units - galG. This organization differs from that of the qa gene cluster in Neurospora crassa, particularly in the displacement of qutC and qutR.     

A High-Resolution Genetic Map of the Nervous Locus on Mouse Chromosome 8

The nervous (nr) mutant mouse displays two gross recessive traits: both an exaggeration of juvenile hyperactivity and a pronounced ataxia become apparent during the third and fourth postnatal weeks. Using an intersubspecific intercross, we have established a high-resolution map of a segment of mouse Chromosome 8 that places thenrlocus in a genomic segment defined byD8Rck1on the centromeric end andD8Mit3on the telomeric end. This map position places thenrlocus within the BALB/cGr congenic region of the C3HeB/FeJ-nrstrain, confirming the accuracy of our study. We used this map position to identify and evaluate three genes—ankyrin 1, cortexin, and farnesyltransferase—as candidates for thenrgene. These three genes were eliminated from consideration but allowed us to establish the conservation of synteny between the region containing thenrlocus and a segment of the short arm of human chromosome 8 (8p21–p11.2). Finally, the incomplete penetrance of thenrphenotype led us to perform a screen for modifier loci, and we present evidence that such a nervous modifier locus may exist on mouse Chromosome 5.     

A Diphenol Oxidase Gene Is Part of a Cluster of Genes Involved in Catecholamine Metabolism and Sclerotization in Drosophila. I. Identification of the Biochemical Defect in Dox-A2 [l(2)37Bf] Mutants

Phenol oxidase, a complex enzyme, plays a major role in the processes of sclerotization and melanization of cuticle in insects. Several loci have been reported to affect levels of phenol oxidase activity, but to date only one structural locus has been identified [Dox-3F (2-53.1+)]. Recently isolated Dox-A2 mutations (2-53.9) are recessive, early larval lethals, which as heterozygotes reduce phenol oxidase activity. A homozygous mutant escaper had weak, completely unpigmented cuticle and unpigmented bristles. Enzyme assays show that Dox-A2 heterozygotes have diphenol oxidase activity reduced to 47-79% of wild type, whereas monophenol oxidase activity, at 94-106% of wild type, is normal. Elevated pool sizes of the diphenol oxidase substrates DOPA, dopamine, and N-acetyldopamine are observed in the mutant, confirming the enzyme assay results. Separation of the three phenol oxidase A component activities on polyacrylamide gels shows that Dox-A2 mutations reduce the activity of only the A2 component. Dox-A2 may identify a structural locus for the A2 component of the diphenol oxidase enzyme system. The Dox-A2 locus is one of 18 loci in the dopa decarboxylase, Df (2L)TW130 region of the second chromosome, at least 14 of which affect the formation, melanization or sclerotization of cuticle in some way. These loci form an apparent cluster of functionally related genes.     

The cuticle proteins of Drosophila melanogaster: stage specificity

Five stage-specific cuticles are produced during the development of Drosophila. Urea-soluble proteins were extracted from each developmental stage and compared by gel electrophoresis. Proteins from first and second instar cuticle are identical except for minor differences in two proteins. Each subsequent stage, third instar, pupa, and adult, has a unique set of cuticle proteins. Qualitative changes within stages are seen in proteins from third instar and adult cuticle. Third instar cuticle proteins can be divided into “early” [proteins 2a, 3, 4, 5, 7, and 8] and “late” [proteins 2 and 1] groups. Adult cuticle proteins change in relative amounts during pharate adult development and change mobility at eclosion. The lower abdominal pupal cuticle lacks a protein found in the pupal cuticle covering the head and thorax. Cuticle proteins from each stage are immunologically related. Nonetheless, electrophoretic variants of three larval proteins do not affect any major changes in the electrophoretic mobility of proteins from other stages. We propose that each stage (except first and second instar) has proteins encoded by discrete genes.     

Evidence for a Set of Closely Linked Autosomal Genes That Interact with Sex-Chromosome Heterochromatin in DROSOPHILA MELANOGASTER

It is proposed that there exists a special region in the euchromatin of the left arm of chromosome 2 (contained within sections 31-32 of the standard salivary gland chromosome map) that is defined by a set of genes, each one of which interacts with a specific sex-chromosome heterochromatic segment. The evidence for the existence of this region is, first, the exhibition, mapping, and analysis of five different maternal-effect, embryonic semi-lethals located in region 31-32. Secondly, in each case the consequence of the maternal effect is markedly influenced by the amount of X- or Y-chromosome heterochromatin carried by the progeny of mutant mothers. The nature of this interaction and possible reasons for the existence of the cluster of autosomal genes are discussed.     

Molecular cloning of lin-29, a heterochronic gene required for the differentiation of hypodermal cells and the cessation of molting in C.elegans.

The lin-29 gene product of C.elegans activates a temporal developmental switch for hypodermal cells. Loss-of-function lin-29 mutations result in worms that fail to execute a stage-specific pattern of hypodermal differentiation that includes exist from the cell cycle, repression of larval cuticle genes, activation of adult cuticle genes, and the cessation of molting. Combined genetic and physical mapping of restriction fragment length polymorphisms (RFLPs) was used to identify the lin-29 locus. A probe from the insertion site of a Tc1 (maP1), closely linked and to the left of lin-29 on the genetic map, was used to identify a large set of overlapping cosmid, lambda and yeast artificial chromosome (YAC) clones assembled as part of the C.elegans physical mapping project. Radiolabeled DNA from one YAC clone identified two distinct allele-specific alterations that cosegregated with the lin-29 mutant phenotype in lin-29 intragenic recombinants. lin-29 sequences were severely under-represented in all cosmid and lambda libraries tested, but were readily cloned in a YAC vector, suggesting that the lin-29 region contains sequences incompatible with standard prokaryotic cloning techniques.     

The genetic basis of larval resistance to a host plant toxin in Drosophila sechellia

The larvae of Drosophila sechellia are highly resistant to octanoic acid, a toxin found in D. sechellia's host plant, Morinda citrifolia. In contrast, close relatives of D. sechellia, D. simulans and D. melanogaster, are not resistant. In a series of interspecific backcrosses, 11 genetic markers were used to map factors affecting egg-to-adult ('larval') resistance in D. sechellia. The third chromosome harbours at least one partially dominant resistance factor. The second chromosome carries at least two mostly dominant resistance factors but no recessive factors. However, neither the X chromosome--which contains 20% of D. sechellia's genome--nor the fourth chromosome appear to affect resistance. These data suggest that larval resistance to Morinda toxin may involve only a handful of genes. These results, when compared with a previous analysis of adult resistance to Morinda toxin in D. sechellia, suggest that larval resistance may involve a subset of the genes underlying adult resistance.     

Genetic analysis of the heterochromatin of chromosome 3 in Drosophila melanogaster. I. Products of compound-autosome detachment

The heterochromatin of the third chromosome is the largest uncharacterized region of the Drosophila melanogaster genome, and the last major block of D. melanogaster heterochromatin to be thoroughly analyzed. In the present study, this region was genetically dissected by generating and analyzing a series of attached, detached and reattached third chromosomes. Separate detachment experiments were conducted for all 12 possible combinations of four newly synthesized sister-strand compound-3L and three newly synthesized sister-strand compound-3R chromosomes. A total of 443 recessive lethal detachment products carrying putative heterochromatic deficiencies were tested for complementation in a several-stage complementation analysis. The results revealed the presence of seven separable vital regions in the heterochromatin of chromosome 3. Attempts to reattach deficiency-carrying detachment products established that six of these vital regions are on the left arm, but only one is on the right arm. An analysis of the types and frequencies of detachment-product deficiencies generated in each detachment experiment permitted the genetic characterization of the progenitor compounds. It was also possible to determine the proximal-distal orientation of the genes on each arm, and to identify possible breakpoints for each lethal detachment product produced. The results of this study suggest that vital genes in the heterochromatin of the third chromosome are not randomly distributed between, nor within, the heterochromatic blocks of the left and right arms.     

New genes in the left arm of the bacteriophage phi 80 chromosome.

We describe the isolation and partial genetic characterization of 247 amber (suppressor-sensitive) mutants of temperate bacteriophage phi 80 of Escherichia coli. Of these 247 mutants, the mutations of 201 mapped to the left arm of the phi 809 chromosome and the mutations of 39 mapped to the right arm of the genome. Complementation tests among these and previously described left arm mutants defined five additional genes in the left arm of the chromosome. The positions of these genes are consistent with the hypothesis that four of them represent functions essential for phi 80 tail assembly and one represents a capsid assembly function, probably the major coat protein. The identification of these genes brings the phi 80 genome into closer correspondence with the organization of the phage lambda genome. Two- and three-factor crosses performed between mutants with defects in each of the previously identified genes and mutants with defects in the five new genes allowed us to construct a consistent, roughly additive recombination map of the left arm of the bacteriophage phi 80 genome.     

Genetics of Differences in Pheromonal Hydrocarbons between Drosophila Melanogaster and D. Simulans

Females of Drosophila melanogaster and its sibling species D. simulans have very different cuticular hydrocarbons, with the former bearing predominantly 7,11-heptacosadiene and the latter 7-tricosene. This difference contributes to reproductive isolation between the species. Genetic analysis shows that this difference maps to only the third chromosome, with the other three chromosomes having no apparent effect. The D. simulans alleles on the left arm of chromosome 3 are largely recessive, allowing us to search for the relevant regions using D. melanogaster deficiencies. At least four nonoverlapping regions of this arm have large effects on the hydrocarbon profile, implying that several genes on this arm are responsible for the species difference. Because the right arm of chromosome 3 also affects the hydrocarbon profile, a minimum of five genes appear to be involved. The large effect of the thrid chromosome on hydrocarbons has also been reported in the hybridization between D. simulans and its closer relative D. sechellia, implying either an evolutionary convergence or the retention in D. sechellia of an ancestral sexual dimorphism.     

Two new balancer chromosomes on mouse chromosome 4 to facilitate functional annotation of human chromosome 1p

To facilitate genetic screens to identify and maintain recessive mutations that map to the short arm of human chromosome 1, we have utilized chromosome engineering to generate two mouse strains that carry large inversions on the distal region of mouse chromosome 4. The inversion intervals are 16 and 22 cM in size together they cover approximately half of chromosome 4. Since recombination between the wild-type and inversion chromosomes does not occur within these inversion intervals, mutant alleles of genes mapping to this region can be identified and maintained. Therefore, these inversion chromosomes work as balancer chromosomes. These inversions have the additional advantage that they are tagged with genes encoding the visible coat color markers tyrosinase and agouti, and therefore the dosage of the inversion chromosome (+/+, Inv/+, Inv/Inv) can be visually recognized. These inversion strains will be extremely useful for mutagenesis screens that focus on functional annotation of human chromosome 1p.     

Genetic evidence for linkage with the Z and W sex chromosomes of two distinct couples of alleles controlling larval and postmetamorphic skin pigmentation in salamander

In Pleurodeles waltl, progeny resulting from a cross between 2 individuals of the Z/W sexual genotype include 25% of W/W individuals, while those issued from crossing a Z/W neomale with a W/W thelygenous female include 50% of W/W individuals. W/W individuals can be identified through the peptidase-1 zymogram since, in P. waltl, this enzyme is controlled by codominant alleles which are linked to the sex chromosomes. In such progeny, we discovered 2 mutant phenotypes affecting larval and postmetamorphic skin pigmentation in W/W individuals. These phenotypes are described herein. The study of their inheritance in several offspring provides evidence that they are controlled by 2 distinct genes, the recessive mutant alleles of which are linked to the W sex chromosome; moreover, in thelygenous W/W females, the differential segment does not prevent the occurrence of meiotic recombinations between W sex chromosomes. Mutant skin pigmentary phenotypes are easily identified and constitute a tool for rapid, efficient selection of individuals of the W/W sexual genotype.     

The Molecular through Ecological Genetics of Abnormal Abdomen in DROSOPHILA MERCATORUM. I. Basic Genetics

The abnormal abdomen syndrome (aa) in Drosophila mercatorum is characterized by the persistence of juvenilized cuticle on the adult abdomen. The aa phenotype is shown to depend on at least two X-linked genetic elements that are about one map unit apart near the centromeric end of the X chromosome. These two genetic elements are necessary for aa expression; one behaves as a dominant element and the other as a recessive. Overlaying these genetic studies upon molecular work reported elsewhere, it is argued that the dominant element is the presence of a 5 kb insertion in a majority of the X-linked repeats coding for the 28S ribosomal RNA. The recessive element appears to be a locus controlling differential replication of noninserted over inserted 28S genes during polytenization. The aa syndrome requires both the presence of the inserted repeats and the failure to preferentially amplify noninserted repeats. Given the necessary X-linked elements for aa, a variety of modifiers are revealed. First, aa expression in males is Y-linked, apparently corresponding to a deletion of the 18S/28S rDNA gene cluster normally found on the Y. Moreover, all major autosomes can modify the penetrance of aa.