Prothoracic transformation and functional structure of the Ultrabithorax gene of Drosophila

The activity of the Ultrabithorax (Ubx+) gene is necessary for the characteristic development of a particular anatomical domain of the body of Drosophila. Mutant alleles at the abx, bx, bxd, and pbx loci eliminate specific functions of Ubx+ since their phenotype is part of that of Ubx mutants. We have characterized several abx and bx alleles and found that their effect extends to the same anatomical subdomain. This suggests that they inactivate the same genetic subunit within Ultrabithorax. Also, their wild-type activity is required for two distinct functions: postprothorax, acting early in the embryonic period, and bithorax, acting through embryonic and larval periods. Our results suggest that the Ultrabithorax gene contains two genetic subunits and that each subunit may include two separate functions.     

Genetic Analysis of the Enhancer of Zeste Locus and Its Role in Gene Regulation in Drosophila Melanogaster

The Enhancer of zeste [E(z)] locus of Drosophila melanogaster is implicated in multiple examples of gene regulation during development. First identified as dominant gain-of-function modifiers of the zeste1-white (z-w) interaction, mutant E(z) alleles also produce homeotic transformations. Reduction of E(z)+ activity leads to both suppression of the z-w interaction and ectopic expression of segment identity genes of the Antennapedia and bithorax gene complexes. This latter effect defines E(z) as a member of the Polycomb-group of genes. Analysis of E(z)S2, a temperature-sensitive E(z) allele, reveals that both maternally and zygotically produced E(z)+ activity is required to correctly regulate the segment identity genes during embryonic and imaginal development. As has been shown for other Polycomb-group genes, E(z)+ is required not to initiate the pattern of these genes, but rather to maintain their repressed state. We propose that the E(z) loss-of-function eye color and homeotic phenotypes may both be due to gene derepression, and that the E(z)+ product may be a general repressing factor required for both examples of negative gene regulation.     

Modifiers of bx1 alter the distribution of Ubx proteins in haltere imaginal discs of Drosophila.

The bithorax (bx) mutations in the Ultrabithorax (Ubx) gene of Drosophila melanogaster cause homeotic transformations of anterior third thoracic structures (T3a) toward anterior second thoracic structures (T2a) in the adult fly. A corresponding loss of Ubx protein expression in T3a of bx imaginal discs has been observed (White and Wilcox, 1985). We describe two genetic loci which modify the bx-induced transformation. A locus which we map very close to the pink peach (pp) gene suppresses the bx1 phenotype. In contrast, mutations in the suppressor of sable (su(s)) gene enhance the bx1 phenotype. A correlation was observed between patterns of Ubx protein expression and the phenotypic transformations observed.     

Effect of Abx, Bx and Pbx Mutations on Expression of Homeotic Genes in Drosophila Larvae

We have examined the patterns of expression of the homeotic gene Ubx in imaginal discs of Drosophila larvae carrying mutations in the abx, bx and pbx regulatory domains. In haltere discs, all five bx insertion mutations examined led to a general reduction in Ubx expression in the anterior compartment; for a given allele, the strength of the adult cuticle phenotype correlated with the degree of Ubx reduction. Deletions mapping near or overlapping the sites of bx insertions, including three abx alleles and the bx34e-prv(bx-prv) allele, showed greatly reduced Ubx expression in parts of the anterior compartment of the haltere disc; however, anterior patches of strong Ubx expression often remained, in highly variable patterns. As expected, the pbx1 mutation led to reduced Ubx expression in the posterior compartment of the haltere disc; surprisingly, pbx1 also led to altered expression of the en protein near the compartment border in the central region of the disc. In the metathoracic leg, all the bx alleles caused extreme reduction in Ubx expression in the anterior regions, with no allele-specific differences. In contrast, abx and bx-prv alleles resulted in patchy anterior reductions in third leg discs. In the larval central nervous system, abx but not bx alleles affected Ubx expression; the bx-prv deletion gave a wild-type phenotype, but it could not fully complement abx mutations. In the posterior wing disc, the bx-prv allele, and to a much lesser extent the bx34e chromosome from which it arose, led to ectopic expression of Ubx. Unlike other grain-of-function mutations in the BX-C, this phenotype appeared to be partially recessive to wild type. Finally, we asked whether the ppx transformation, which results from early lack of Ubx+ function in the mesothorax and is seen in abx animals, is due to ectopic Scr expression. Some mesothoracic leg and wing discs from abx2 larvae displayed ectopic expression of Scr, which was variable in extent but always confined to the posterior compartment.     

Genetic dissection of itpr gene function reveals a vital requirement in aminergic cells of Drosophila larvae

Signaling by the second messenger inositol 1,4,5-trisphosphate is thought to affect several developmental and physiological processes. Mutants in the inositol 1,4,5-trisphosphate receptor (itpr) gene of Drosophila exhibit delays in molting while stronger alleles are also larval lethal. In a freshly generated set of EMS alleles for the itpr locus we have sequenced and identified single point mutations in seven mutant chromosomes. The predicted allelic strength of these mutants matches the observed levels of lethality. They range from weak hypomorphs to complete nulls. Interestingly, lethality in three heteroallelic combinations has a component of cold sensitivity. The temporal focus of cold sensitivity lies in the larval stages, predominantly at second instar. Coupled with our earlier observation that an itpr homozygous null allele dies at the second instar stage, it appears that there is a critical period for itpr gene function in second instar larvae. Here we show that the focus of this critical function lies in aminergic cells by rescue with UAS-itpr and DdCGAL4. However, this function does not require synaptic activity, suggesting that InsP(3)-mediated Ca(2+) release regulates the neurohormonal action of serotonin.     

Mechanisms of Mutagenesis by a Bulky DNA Lesion at the Guanine N7 Position

The RpII215 locus encodes the large subunit of RNA polymerase II (polII). Three of 22 RpII215 alleles cause a synergistic enhancement of the mutant phenotype elicited by mutations in the Ultrabithorax (Ubx) locus. We have recovered and analyzed three new mutations that suppress this enhancement. All three mutations map to the RpII215 locus. In addition to suppressing the Ubx enhancement of other RpII215 alleles, two of the new mutations, JH1 and WJK2, themselves enhance Ubx. RpII215 alleles can be placed into three classes based on their ability to enhance Ubx. Class I alleles, including Ubl, C4, C11, JH1, and WJK2, enhance Ubx when heterozygous with class II alleles, which include wild-type RpII215. Class III alleles, which include amorphic alleles, do not enhance Ubx. The third new mutation, WJK1, is a conditional amorphic allele, which behaves like a class III allele at 29 degrees but like a class II allele at 19 degrees. Another mutant phenotype is caused by certain RpII215 alleles, including all class I alleles. This phenotype is a synergistic enhancement of a mutant phenotype elicited by mutations at the Delta (Dl) locus. Unlike the enhancement of Ubx, the enhancement of Dl is not dependent upon antagonistic interactions between different classes of RpII215 alleles.     

Haltere determination and mutations at the bithorax locus

Mutations at the bithorax locus transform anterior haltere tissue into anterior wing. These transformations could in principle be due to the mutations altering either the expression or cell heredity functions of determination. I have studied two alleles of the bithorax locus bx³ and bx^34e using disc culture techniques and found that both produce their transformations by altering the expression of the determined state. I have also found that the expression of the temperature-sensitive allele, bx^34e, can be altered by temperature shifts during the culture period. Evidence has been obtained that suggests that such changes in expression do not require growth or cell division.     

Temperature-Dependent Expression of the APTEROUS Phenotype in DROSOPHILA MELANOGASTER

Mutations at the apterous (ap) locus in Drosophila melanogaster produce a variety of developmental defects, including several classes of wing abnormalities. We describe the wing phenotype produced by homozygotes and hemizygotes of three different temperature-sensitive apterous alleles grown at 16, 18, 20, 22, 25, and 29 degrees. We also describe the phenotype produced by each of these three alleles when heteroallelic with the non-temperature-sensitive apc allele. Constant-temperature and temperature-shift experiments show that each of the heteroallelic genotypes can produce several of the previously described apterous phenotypes and that the length of the temperature-sensitive period for a given phenotype depends on the allelic combinations used to measure it. We suggest that the stage-specific requirements of the tissue for gene product, rather than the time of gene expression per se, determine the temperature-sensitive periods for apterous and other loci. The results support the hypothesis that the various wing phenotypes produced by apterous mutations are due to quantitative reductions in the activity of gene product and that failure to meet specific threshold requirements for gene product can lead to qualitatively different phenotypes.     

Characterisation of a new tumorous-head mutant of Drosophila melanogaster

Summary A new homoeotic mutant, I127, showing abnormal growths in the head region including homoeotic transformation of eye to genitalia and antenna to leg, was isolated in a screen designed to find new alleles of the tumorous head (tuh-3), mutation. Similarities in the phenotype and genetics of the mutant, and complementation studies with tuh-1; tuh-3, suggest that I127 is indeed an allele of tuh-3. In combination with the first chromosome modifier tuh-1, the mutant is temperature-sensitive during the third larval instar, giving an increased penetrance of the tumorous head phenotype when reared at 25° C as opposed to 18° C. The isolation of further alleles at the tumorous-head locus are essential. The types of morphological defects which can result from mutations at this locus would enable us to establish if this is a complex locus, and if null mutations are lethal during development. The interactions of the tumorous-head gene with first chromosome modifiers and other homoeotic mutations will only be understood if we able to induce a number of mutations at this locus, and as a consequence begin to elucidate the role of the wild-type gene product in normal development.     

Effects of mutations at thestambh A locus ofDrosophila melanogaster

We report novel findings on the cytogenetic location, functional complexity and maternal and germline roles of thestambh A locus ofDrosophila melanogaster. stmA is localized to polytene bands 44D1.2 on 2R.stmA mutations are of two types: temperature-sensitive (ts) adult and larval paralytic or unconditional embryonic or larval lethal. Twelve alleles reported in this study fall into two intragenic complementing groups suggesting thatstmA is a complex locus with more than one functional domain. Some unconditional embryonic lethal alleles show a ‘neurogenic’ phenotype of cuticle loss accompanied by neural hypertrophy. It is shown that embryos of ts paralytic alleles also show mild neural hypertrophy at permissive temperatures while short exposure to heat induces severe cuticle loss in these embryos.stmA exerts a maternal influence over heat-induced cuticle loss. Unconditional embryonic lethal alleles ofstmA are also germline lethal.     

A Drosophila SNAP-25 null mutant reveals context-dependent redundancy with SNAP-24 in neurotransmission

The synaptic protein SNAP-25 is an important component of the neurotransmitter release machinery, although its precise function is still unknown. Genetic analysis of other synaptic proteins has yielded valuable information on their role in synaptic transmission. In this study, we performed a mutagenesis screen to identify new SNAP-25 alleles that fail to complement our previously isolated recessive temperature-sensitive allele of SNAP-25, SNAP-25(ts). In a screen of 100,000 flies, 26 F(1) progeny failed to complement SNAP-25(ts) and 21 of these were found to be null alleles of SNAP-25. These null alleles die at the pharate adult stage and electroretinogram recordings of these animals reveal that synaptic transmission is blocked. At the third instar larval stage, SNAP-25 nulls exhibit nearly normal neurotransmitter release at the neuromuscular junction. This is surprising since SNAP-25(ts) larvae exhibit a much stronger synaptic phenotype. Our evidence indicates that a related protein, SNAP-24, can substitute for SNAP-25 at the larval stage in SNAP-25 nulls. However, if a wild-type or mutant form of SNAP-25 is present, then SNAP-24 does not appear to take part in neurotransmitter release at the larval NMJ. These results suggest that the apparent redundancy between SNAP-25 and SNAP-24 is due to inappropriate genetic substitution.     

Mutational analysis of the Shab-encoded delayed rectifier K(+) channels in Drosophila.

K(+) currents in Drosophila muscles have been resolved into two voltage-activated currents (I(A) and I(K)) and two Ca(2+)-activated currents (I(CF) and I(CS)). Mutations that affect I(A) (Shaker) and I(CF) (slowpoke) have helped greatly in the analysis of these currents and their role in membrane excitability. Lack of mutations that specifically affect channels for the delayed rectifier current (I(K)) has made their genetic and functional identity difficult to elucidate. With the help of mutations in the Shab K(+) channel gene, we show that this gene encodes the delayed rectifier K(+) channels in Drosophila. Three mutant alleles with a temperature-sensitive paralytic phenotype were analyzed. Analysis of the ionic currents from mutant larval body wall muscles showed a specific effect on delayed rectifier K(+) current (I(K)). Two of the mutant alleles contain missense mutations, one in the amino-terminal region of the channel protein and the other in the pore region of the channel. The third allele contains two deletions in the amino-terminal region and is a null allele. These observations identity the channels that carry the delayed rectifier current and provide an in vivo physiological role for the Shab-encoded K(+) channels in Drosophila. The availability of mutations that affect I(K) opens up possibilities for studying I(K) and its role in larval muscle excitability.     

A developmental genetic analysis of the gene Regulator of postbithorax in Drosophila melanogaster

We report the characterization of loss-of-function alleles of the homoeotic mutation Regulator of postbithorax (Rg-pbx) in Drosophila melanogaster. Rg-pbx is a dominant gain-of-function mutation which shows a transformation of posterior haltere to wing in the adult cuticle. This mutant phenotype mimics that of the bithorax complex lesion postbithorax (pbx). Loss-of-function alleles described here are lethal in the embryonic stage and affect the pattern of segmentation of the embryo. Examination of the terminal phenotype of null and hypomorphic alleles of Rg-pbx has shown that inactivation of the Rg-pbx gene leads to loss of the thoracic segments and the adjacent labial segment of the Drosophila embryo. An effect of the mutations is also seen in the seventh and eighth abdominal segments of embryos. The loss-of-function phenotype is similar to that described for the segmentation mutant hunchback (hb). Complementation tests show that Rg-pbx and hb are allelic. Temperature shift experiments using a temperature-sensitive loss-of-function allele show that the Rg-pbx gene product is required early in embryogenesis. We further report that the dominant Rg-pbx phenotype is sensitive to the gene dosage of another segmentation-controlling gene, fushi tarazu (ftz). Flies carrying a mutant copy of the ftz gene in trans to Rg-pbx show a dramatic enhancement of the penetrance of the homoeotic mutant phenotype. We were also able to demonstrate a suppression of the Rg-pbx phenotype by the addition of a duplication for the ftz⁺ gene to an Rg-pbx stock. Examination of the phenotype of ftz⁻, Rg-pbx⁻ double-mutant embryos did not reveal a clear pattern of epistasis between the genes nor was absolute additivity of phenotype seen. A possible formal relationship between Rg-pbx, ftz, and the postbithorax (pbx) locus is proposed.     

The Effects of Chromosomal Rearrangements on the zeste-white Interaction in Drosophila melanogaster

Three gene systems have been shown to exhibit proximity-dependent phenotypes in Drosophila melanogaster: bithorax (BX-C), decapentaplegic (DPP-C) and white (w). In structurally homozygous genotypes, specific allelic combinations at these loci exhibit one phenotype, while in certain rearrangement heterozygotes the same allelic combinations exhibit dramatically different phenotypes. These observations have led to the suggestion that, through the process of somatic chromosome pairing, such loci are brought into sufficient proximity to permit effective passage of molecular information between homologues; rearrangement heterozygosity would then displace the homologues relative to one another such that this trans-communication is obviated. The genetic properties of the proximity-dependent allelic complementation (termed transvection effects) at the BX-C and DPP-C, are quite similar. Chromosomal rearrangements which disrupt transvection possess a breakpoint in a particular segment of the chromosome arm bearing the transvection-sensitive gene (arm 2L for the DDP-C and 3R for the BX-C); this segment of each arm has been termed the critical region by Lewis (1954). As determined by cytogenetic analysis of transvection-disrupting rearrangements, the critical regions for the BX-C and DDP-C transvection effects extend proximally from these loci for several hundred polytene chromosome bands (Lewis 1954; Gelbart 1982). The interaction between the zeste and white loci appears to depend upon the proximity of the two w+ alleles. By use of insertional duplications, displacement of w+ homologues has been shown to interfere with the zeste-white interaction. In contrast to transvection at bithorax and decapentaplegic, however, only breakpoints in the immediate vicinity of the white locus can disrupt the zeste-white interaction (Gans 1953; Green 1967; Gelbart 1971; this report). In this report, we investigate the basis for the difference in the size of the BX-C and DPP-C critical regions from that of white. We test and eliminate the possibility that the difference is due to the presence near the white locus of a site which mediates somatic chromosome pairing. Rather, our evidence strongly suggests that the zeste-white interaction is, at the phenotypic level, much less sensitive to displacement of the homologous genes than is transvection at either the BX-C or DPP-C. We also show that many of the breakpoints in the vicinity of the white locus do not behave as if they are disrupting a critical region for somatic chromosome pairing. Given these results, we suggest that the zeste-white interaction and transvection are two different proximity-dependent phenomena.     

Dietary fatty acid effects on morphogenesis in bithorax mutants

Three bithorax alleles of Drosophila melanogaster were tested to determine if dietary additions of fatty acids would alter their gene expression. For the bx¹ allele, myristic, oleic, and linoleic acids were all effective in reducing gene expression while fatty acid supplementation was ineffective with the bx³ and bx^34e alleles. For bx¹ the nutritionally sensitive period was found to occur in the first 48 h of larval life.     

Developmental and Genetic Studies on Kynurenine Hydroxylase from DROSOPHILA MELANOGASTER

The level of kynurenine hydroxylase was measured throughout the development of wild type and the eye color mutants v, cn, st, ltd, cd, kar, w, ca, bri and p(P) of Drosophila melanogaster. In all cases except cn a bimodal distribution of enzyme activity during development was observed. Activity is initially detectable in second instar. A maximum is reached in early third instar. Activity declines prior to puparium formation. Shortly after pupation, activity rises dramatically to reach a maximum about five times the peak larval level. Maximum activity persists for a short time, and then falls sharply prior to emergence. No activity is detectable in cn, cn(3), or cn(35K). In pupae which have zero, one, two or three doses of the cn(+) allele, activity is proportional to the number of the + alleles. This provides further evidence that the cn locus contains the structural gene for kynurenine hydroxylase. Kynurenine hydroxylase is a useful gene product for studying the events of imaginal disc differentiation.     

The Developmental Genetics of the Temperature-Sensitive Lethal Allele of the Suppressor of Forked, l(1)su(f)ts67g, in DROSOPHILA MELANOGASTER

A temperature-sensitive lethal allele of suppressor of forked, l(1)su(f)(ts67g) (ts67), has been discovered and characterized as follows: Flies which are hemizygous for ts67 live at 18 degrees and 25 degrees but die at 30 degrees primarily as larvae. The temperature-sensitive period for ts67 homozygotes or hemizygotes begins in second instar and ends at pupation. ts67 is lethal at 30 degrees when heterozygous with suppressor of forked (su(f)), a deficiency for suppressor of forked (su(f)(-)), and a non-conditional lethal allele of suppressor of forked (3DES). It is viable at 30 degrees when heterozygous with the wild-type allele of suppressor of forked. At 25 degrees but not at 18 degrees forked bristles are suppressed in flies of the following genotypes: f(s)ts67/Y, f(s)ts67/f(s)ts67, f(s)ts67/f(s)su(f), f(u)ts67/f(s)3DES, f(u)ts67/f(s)su(f)(-), f(u)ts67/f(s)su(f). There is some suppression of forked bristles at 25 degrees in the heterozygote, f(s)ts67/f(s)+(su(f)). The forked bristle phenotype is not suppressed at either temperature in flies of the genotypes f(u)ts67/Y, f(u)ts67/f(u)ts67/ (f(s) and f(u) indicating suppressible and unsuppressible alleles of forked). The temperature-sensitive period for suppression of forked bristles begins at pupation and extends through the period of bristle synthesis. The deficiency phenotype (bristles reduced in size or absent, wing wrinkled or blistered, eyes rough) typical of flies of the genotype f(s)su(f)/f(s)su(f)(-) at 18 degrees and 25 degrees , is exhibited by flies of the genotypes f(s)ts67/f(s)su(f)(-) at 25 degrees and f(u)ts67/f(s)su(f) at 29 degrees . An allele of lozenge (lz(1)) which can be suppressed by su(f) is suppressed at 25 degrees but not at 18 degrees in lz(1)ts67/Y males. ts67 homozygous females are fertile at 25 degrees but sterile at 30 degrees . The hypothesis is discussed that the su(f) locus codes for a ribosomal protein and that suppression and enhancement are affected by mutations at the locus by mutant ribosome-induced misreading. The possibility is presented that ts67 may be used to determine the translation time in development of any gene.     

Developmental genetics of the gastrulation defective locus in Drosophila melanogaster

The fs(1)gastrulation defective (dg) locus is one of the dorsal-group genes of Drosophila. Maternal expression of this gene is required for gastrulation movements and the differentiation of structures along the embryonic dorso-ventral axis. Twelve alleles of gd displayed a complex pattern of complementation, suggesting a direct interaction between subunits of a multimeric protein. Essential expression of the gd locus was strictly maternal with no zygotic contribution by the paternally derived allele. Clonal analysis revealed that expression of the gd locus was required in the germ line and that extreme dorsalization represented the null gd phenotype. Temperature-sensitive (ts) alleles displayed a ts period that included the last 4-5 hr of oogenesis and the first 1.5-2 hr of embryogenesis. Eggs from one ts allelic combination displayed reduced hatching when retained in the ovary at permissive temperatures, suggesting the loss of a labile egg component. This lability may also be responsible for the variable phenotypes displayed by offspring from individual females.