Sternopleural Is a Regulatory Mutation of Wingless with Both Dominant and Recessive Effects on Larval Development of Drosophila Melanogaster

The Drosophila wingless (wg) gene encodes a secreted signaling protein that is required for many separate patterning events in both embryonic and larval development. wg functions in the development of the adult structures have been studied using the conditional mutant wg(ts) and also using regulatory mutations of wg that reduce larval functions. Here we present evidence that Sternopleural (Sp) is another regulatory allele of wg that affects a subset of larval functions. Sp has both a recessive loss-of-function component and a gain-of-function component. The loss-of-function component reflects a reduction of wg activity in the notum and in the antenna. The gain-of-function component apparently leads to ectopic wg activity in the dorsal first and second leg disc and thereby generates the dominant Sp phenotype. Sp and other wg alleles show a complex pattern of complementation. We present evidence that these genetic properties are due to transvection. These results have implications for the genetic definition of a null allele at loci subject to transvection.     

Characterization of the Adh(sl) Regulatory Mutation in Drosophila Melanogaster

We describe the characterization of a previously reported control mutation, AdhSL, in the alcohol dehydrogenase gene of Drosophila melanogaster, which results in decreased production of ADH molecules and subsequently lower ADH activity in adults. We find that the regulatory element modifies ADH mRNA levels and acts cis on both ADH protein and mRNA. It is not promoter specific but is developmentally specific to the adult stage. The AdhSL allele carries a 4.5-kb insert approximately 3 kb 5' to the distal promoter. This new insertion may be responsible for the regulatory phenotype of AdhSL.     

The Antimorphic Nature of the T(c) Allele at the Mouse T Locus

The T locus on mouse chromosome 17 is haploid-insufficient: deletion/+ heterozygous mice have a short tail. One exceptional allele, Tc, produces a tailless phenotype in heterozygous mice. Thus, Tc has a more severe phenotype than that of a deletion allele, suggesting either that Tc is further deleted for a neighboring locus, resulting in the additional phenotype, or that Tc is a gain-of-function mutation. We have shown that Tc is not deleted for the D17Leh119 and D17RP17 loci flanking T, which are deleted in some T alleles. Thus, the severity of the Tc phenotype is not due to the deletion of an adjacent locus. We have also examined the genetic nature of the Tc allele by placing it in trans with a T-locus duplication, twLub2, which has previously been independently confirmed at the molecular level to have a duplication in the chromosomal region including the T locus. We have shown that Tc is partially complemented by twLub2, unlike a null allele (deletion) which was previously shown to be fully complemented by twLub2. These results indicate that Tc behaves genetically as an antimorph, exerting its effect by antagonizing the function of a wild-type allele at the T locus. The apparent correlation between the gene dosage at the T locus and the length of the body axis is discussed.     

Characterization of PINK1 (PTEN-induced Putative Kinase 1) Mutations Associated with Parkinson Disease in Mammalian Cells and Drosophila

Mutations in PINK1 (PTEN-induced putative kinase 1) are tightly linked to autosomal recessive Parkinson disease (PD). Although more than 50 mutations in PINK1 have been discovered, the role of these mutations in PD pathogenesis remains poorly understood. Here, we characterized 17 representative PINK1 pathogenic mutations in both mammalian cells and Drosophila. These mutations did not affect the typical cleavage patterns and subcellular localization of PINK1 under both normal and damaged mitochondria conditions in mammalian cells. However, PINK1 mutations in the kinase domain failed to translocate Parkin to mitochondria and to induce mitochondrial aggregation. Consistent with the mammalian data, Drosophila PINK1 mutants with mutations in the kinase domain (G426D and L464P) did not genetically interact with Parkin. Furthermore, PINK1-null flies expressing the transgenic G426D mutant displayed defective phenotypes with increasing age, whereas L464P mutant-expressing flies exhibited the phenotypes at an earlier age. Collectively, these results strongly support the hypothesis that the kinase activity of PINK1 is essential for its function and for regulating downstream Parkin functions in mitochondria. We believe that this study provides the basis for understanding the molecular and physiological functions of various PINK1 mutations and provides insights into the pathogenic mechanisms of PINK1-linked PD.     

Dominant Red Coat Color in Holstein Cattle Is Associated with a Missense Mutation in the Coatomer Protein Complex,Subunit Alpha (COPA) Gene

Coat color in Holstein dairy cattle is primarily controlled by the melanocortin 1 receptor (MC1R) gene, a central determinant of black (eumelanin) vs. red/brown pheomelanin synthesis across animal species. The major MC1R alleles in Holsteins are Dominant Black (MC1R^D) and Recessive Red (MC1R^e). A novel form of dominant red coat color was first observed in an animal born in 1980. The mutation underlying this phenotype was named Dominant Red and is epistatic to the constitutively activated MC1R^D. Here we show that a missense mutation in the coatomer protein complex, subunit alpha (COPA), a gene with previously no known role in pigmentation synthesis, is completely associated with Dominant Red in Holstein dairy cattle. The mutation results in an arginine to cysteine substitution at an amino acid residue completely conserved across eukaryotes. Despite this high level of conservation we show that both heterozygotes and homozygotes are healthy and viable. Analysis of hair pigment composition shows that the Dominant Red phenotype is similar to the MC1R Recessive Red phenotype, although less effective at reducing eumelanin synthesis. RNA-seq data similarly show that Dominant Red animals achieve predominantly pheomelanin synthesis by downregulating genes normally required for eumelanin synthesis. COPA is a component of the coat protein I seven subunit complex that is involved with retrograde and cis-Golgi intracellular coated vesicle transport of both protein and RNA cargo. This suggests that Dominant Red may be caused by aberrant MC1R protein or mRNA trafficking within the highly compartmentalized melanocyte, mimicking the effect of the Recessive Red loss of function MC1R allele.     

Hybrid Lethal Systems in the Drosophila Melanogaster Species Complex. II. the Zygotic Hybrid Rescue (Zhr) Gene of D. Melanogaster

Hybrid females from Drosophila simulans females X Drosophila melanogaster males die as embryos while hybrid males from the reciprocal cross die as larvae. We have recovered a mutation in melanogaster that rescues the former hybrid females. It was located on the X chromosome at a position close to the centromere, and it was a zygotically acting gene, in contrast with mhr (maternal hybrid rescue) in simulans that rescues the same hybrids maternally. We named it Zhr (Zygotic hybrid rescue). The gene also rescues hybrid females from embryonic lethals in crosses of Drosophila mauritiana females X D. melanogaster males and of Drosophila sechellia females X D. melanogaster males. Independence of the hybrid embryonic lethality and the hybrid larval lethality suggested in a companion study was confirmed by employing two rescue genes, Zhr and Hmr (Hybrid male rescue), in doubly lethal hybrids. A model is proposed to explain the genetic mechanisms of hybrid lethalities as well as the evolutionary pathways.     

Phenotypic and Molecular Characterization of Ser(d), a Dominant Allele of the Drosophila Gene Serrate

The Drosophila gene Serrate (Ser) encodes a transmembrane protein with 14 epidermal growth factor--like repeats in its extracellular domain, which is required for the control of cell proliferation and pattern formation during wing development. Flies hetero- or homozygous for the dominant mutation Ser(D) exhibit scalloping of the wing margin due to cell death during pupal stages. Ser(D) is associated with an insertion of the transposable element Tirant in the 3' untranslated region of the gene, resulting in the truncation of the Ser RNA, thereby eliminating putative RNA degradation signals located further downstream. This leads to increased stability of Ser RNA and higher levels of Serrate protein. In wing discs of wild-type third instar larvae, the Serrate protein exhibits a complex expression pattern, including a strong stripe dorsal and a weaker stripe ventral to the prospective wing margin. Wing discs of Ser(D) third instar larvae exhibit additional Serrate protein expression in the edge zone of the future wing margin, where it is normally not detectable. In these cells expression of wing margin specific genes, such as cut and wingless, is repressed. By using the yeast Gal4 system to induce locally restricted ectopic expression of Serrate in the edge zone of the prospective wing margin, we can reproduce all aspects of the Ser(D) wing phenotype, that is, repression of wing margin--specific genes, scalloping of the wing margin and enhancement of the Notch haplo-insufficiency wing phenotype. This suggests that expression of the Serrate protein in the cells of the edge zone of the wing margin, where it is normally absent, interferes with the proper development of the margin.     

The Bacterially Produced Metabolite Violacein Is Associated with Survival of Amphibians Infected with a Lethal Fungus

The disease chytridiomycosis, which is caused by the chytrid fungus Batrachochytrium dendrobatidis, is associated with recent declines in amphibian populations. Susceptibility to this disease varies among amphibian populations and species, and resistance appears to be attributable in part to the presence of antifungal microbial species associated with the skin of amphibians. The betaproteobacterium Janthinobacterium lividum has been isolated from the skins of several amphibian species and produces the antifungal metabolite violacein, which inhibits B. dendrobatidis. In this study, we added J. lividum to red-backed salamanders (Plethodon cinereus) to obtain an increased range of violacein concentrations on the skin. Adding J. lividum to the skin of the salamander increased the concentration of violacein on the skin, which was strongly associated with survival after experimental exposure to B. dendrobatidis. As expected from previous work, some individuals that did not receive J. lividum and were exposed to B. dendrobatidis survived. These individuals had concentrations of bacterially produced violacein on their skins that were predicted to kill B. dendrobatidis. Our study suggests that a threshold violacein concentration of about 18 μM on a salamander''s skin prevents mortality and morbidity caused by B. dendrobatidis. In addition, we show that over one-half of individuals in nature support antifungal bacteria that produce violacein, which suggests that there is a mutualism between violacein-producing bacteria and P. cinereus and that adding J. lividum is effective for protecting individuals that lack violacein-producing skin bacteria.The amphibian fungal pathogen Batrachochytrium dendrobatidis causes a lethal skin disease that has caused substantial declines in amphibian populations (18). However, some species, such as the bullfrog (Rana catesbeiana) and the tiger salamander (Ambystoma tigrinum), are relatively asymptomatic when they are infected with this pathogen (4, 5). Variation in survival among species has been attributed to differences in innate immune factors, such as antimicrobial peptides (20) and skin-associated microbial species (8-11), as well as behavior (16). The presence of antifungal microbes is of particular interest because it suggests that these organisms are mutualistic associates of amphibian species. In addition, augmentation of the cutaneous microbial community by adding species of bacteria that inhibit B. dendrobatidis has the potential to provide resistance to chytridiomycosis (9).We have identified a number of bacteria associated with the skin of amphibians that inhibit B. dendrobatidis in vitro via secretion of antifungal metabolites (2, 3, 10, 11). The bacterial species used in this study, Janthinobacterium lividum, produces the anti-B. dendrobatidis metabolites violacein and indole-3-carboxaldehyde (MIC, 1.82 μM and 69 μM, respectively) (3). We have shown that violacein inhibits B. dendrobatidis in laboratory assays (3) and is strongly correlated with survival in vivo of the frog species Rana muscosa (9). Violacein was also present on three of seven wild-collected red-backed salamanders (Plethodon cinereus) at concentrations that inhibit B. dendrobatidis in vitro (3), suggesting that this salamander species has a mutualistic community of violacein-producing bacteria on its skin. In this study, we added J. lividum to salamander skins to generate a wide range of violacein concentrations in order to determine what concentration is needed to prevent mortality caused by chytridiomycosis in vivo.     

Ultrastructure and Cytochemistry of the Cell-types in the Tumorous Hematopoietic Organs and the Hemolymph of the Mutant Lethal (1) Malignant Blood Neoplasm (l(1)mbn) of Drosophila Melanogaster

The fine structure and histochemistry of the neoplastic primordial blood cell-types in the larval hematopoietic organs and the mature cell-types in the hemolymph of the blood tumor mutant lethal (1) malignant blood neoplasm (l(1) mbn ) of Drosophila melanogaster were investigated. In this mutant the cell-types of the plasmatocyte-line are neoplastic while the cell-types of the crystal-cell-line are not and are much reduced in numbers (1, 2).
In contrast to the wild-type the mutant hematopoietic organs are enlarged and contain, in addition to primordial blood-cells, large numbers of mature plasmato-, podo-, and lamellocytes.
All cell-types of the plasmatocyte-line differ in their fine structure and behavior from their wild-type counterparts. The mutant blood cells show generally a numerical increase of cell organelles and acid phosphatase positive primary and secondary lysosomes. In the phenol oxidase test they showed a vigorous melanization reaction. Plasmato- and podocytes invade into the tissues of the larva and show high phagocytic activity.     

Physical and Genetic Characterization of a 75-Kilobase Deletion Associated with A(l), a Recessive Lethal Allele at the Mouse Agouti Locus

The agouti locus (A) of the mouse determines the timing and type of pigment deposition in the growing hair bulb, and several alleles at this locus are lethal when homozygous. Apparent instances of intragenic recombination and complementation between different recessive lethal alleles have suggested that the locus has a complex structure. We have begun to investigate the molecular basis of agouti gene action and recessive lethality by using a series of genetically linked DNA probes and pulsed field gel electrophoresis to detect structural alterations in radiation-induced agouti mutations. Hybridization probes from the Src and Emv-15 loci do not reveal molecular alterations in DNA corresponding to the ae, ax, and al alleles, but a probe from the parotid secretory protein gene (Psp) detects a 75-kilobase (kb) deletion in DNA containing the non-agouti lethal allele (al). The deletion is defined by a 75-kb reduction in the size of BssHII, NotI, NruI and SacII high molecular weight restriction fragments detected with the Psp probe and is located between 25 kb and 575 kb from Psp coding sequences. Because the genetic distance between A and Emv-15 is much less than A and Psp, there may be a preferred site of recombination close to Psp, or suppression of recombination between A and Emv-15. The al deletion has allowed us to determine the genotype of mice heterozygous for different recessive lethal alleles. We find that three different recessive lethal complementation groups are present at the agouti locus, two of which are contained within the al deletion.     

Sterilizing Effect of the Mutant Allele sbr 10 (l(1)ts403) in Compound with Null Allele in Drosophila melanogaster Females

In females of Df(1)v-L4/+(0/+) genotype, the presence of the wild-type allele ofsmall bristles (sbr) gene in a single dose has no significant effect on their fecundity, whereas a reduced dose of the temperature-sensitive allele sbr ¹⁰ (l(1)ts403) causes a strong sterilizing effect in females Df(1)v-L4/sbr ¹⁰ (0/sbr ¹⁰) at permissive temperature. We studied the contribution to this effects of the following factors: resorption of egg chambers, decreased oviposition, offspring death at the embryonic and larval stages, and reduced fecundity in females 0/sbr ¹⁰. Sterilizing effect of the mutant sbr ¹⁰ allele proved to be primarily caused by offspring lethality at the embryonic and first-instar larval stages. In 0/+ females, the majority of undeveloped eggs contained embryos that perished at the late developmental stages, whereas in females 0/sbr ¹⁰, at least 50% of undeveloped egg showed no visible signs of development or the embryo development was arrested at early stages of embryogenesis. The results obtained suggest insufficiency of the temperature-sensitive allele sbr ¹⁰ in haploid state to ensure the reproductive functions of Drosophila melanogaster females.     

The Abnormal Oocyte Phenotype Is Correlated with the Presence of Blood Transposon in Drosophila Melanogaster

The abnormal oocyte mutation (2;44) originates in the wild: it confers no visible phenotype on homozygous abo males or females, but homozygous abo females produce defective eggs and the probability of their developing into adults is much lower than that of heterozygous sister females. We isolated by chromosome walking 200 kb of DNA from region 32. This paper reports that a restriction enzyme site polymorphism analysis in wild type and mutant stocks allowed us to identify a DNA rearrangement present only in stocks carrying the abo mutation. The rearrangement is caused by a DNA insert on the abo chromosome in region 32E which, by restriction map and sequence analysis, was identified as copia-like blood transposon. The transposon, in strains that had remained in abo homozygous conditions for several generations and had lost the abo maternal-effect, was no longer present in region 32E. Certain features of the abo mutation, discussed in the light of this finding, may be ascribed to the nature of the particular allele studied.     

Comparison of in Vitro and in Vivo Activities Associated with the G6pd Allozyme Polymorphism in Drosophila Melanogaster

Earlier studies of the A and B allozymes at the G6pd locus show a differential ability of the genotypes to suppress the loss of viability associated with a low activity 6-phosphogluconate dehydrogenase mutation, 6Pgdlo1. This observation indicates a relatively lower activity for the A allozyme genotype, but it is not known if this level of suppression required a large difference in in vivo activity. To clarify this difference an analysis of the biochemical properties of the purified allozymes was carried out, as well as an analysis of the activity level associated with an original low activity P element-derived allele which had partially reverted and lost its suppression ability. G6PD activity and protein level were studied in 47 X chromosome lines from North America. The A genotype averages a 9% lower Vmax. From analysis of the correlation between G6PD activity and protein level it remains unclear whether the allozyme Vmax difference results from dissimilarity in protein level or kcat. At 25 degrees and physiological pH, comparative studies of the steady-state kinetics show the two purified allozyme variants differ significantly in their KM values for glucose-6-phosphate and NADP, and the K1 for NADPH. In aggregate these parameters predict the A genotype possesses a 20% lower in vitro catalytic efficiency. A partial revertant of a P element-derived low activity B variant, was shown to lose the ability to suppress 6Pgdlo1 low viability after acquiring only 60% of normal B activity. This last comparison shows the A genotype activity must be reduced in vivo by at least 40%.     

A Novel DFNA36 Mutation in TMC1 Orthologous to the Beethoven (Bth) Mouse Associated with Autosomal Dominant Hearing Loss in a Chinese Family

Mutations in the transmembrane channel-like gene 1 (TMC1) can cause both DFNA36 and DFNB7/11 hearing loss. More than thirty DFNB7/11 mutations have been reported, but only three DFNA36 mutations were reported previously. In this study, we found a large Chinese family with 222 family members showing post-lingual, progressive sensorineural hearing loss which were consistent with DFNA36 hearing loss. Auditory brainstem response (ABR) test of the youngest patient showed a special result with nearly normal threshold but prolonged latency, decreased amplitude, and the abnormal waveform morphology. Exome sequencing of the proband found four candidate variants in known hearing loss genes. Sanger sequencing in all family members found a novel variant c.1253T>A (p.M418K) in TMC1 at DFNA36 that co-segregated with the phenotype. This mutation in TMC1 is orthologous to the mutation found in the hearing loss mouse model named Bth ten years ago. In another 51 Chinese autosomal dominant hearing loss families, we screened the segments containing the dominant mutations of TMC1 and no functional variants were found. TMC1 is expressed in the hair cells in inner ear. Given the already known roles of TMC1 in the mechanotransduction in the cochlea and its expression in inner ear, our results may provide an interesting perspective into its function in inner ear.