Analysis of larval segmentation in lethal genotypes associated with the antennapedia gene complex in Drosophila melanogaster

The segment pattern of larval cuticular structures was examined for individuals bearing lethal genotypes associated with the Antennapedia gene complex (ANT-C). The results provide new evidence for the role of this complex in body segmentation in Drosophila and demonstrate that the ANT-C, like the bithorax complex, effects both larval and imaginal tissues. Lethal genotypes involving new EMS induced lesions or dominant homoeotic mutations (Antp or Antp^Scx) of the Antennapedia complementation group show anomalies in the larval meso- and metathorax. The phenotype is interpreted as a homoeotic transformation of the meso- and metathorax to prothorax. We suggest that Antp⁺ functions in the elicitation of mesothoracic development above that of a prothoracic level in the ventral meso- and metathorax. The lethality of the Sex combs reduced complementation group, which includes the mutation Multiple sex combs (Msc), is characterized by incomplete head formation and the lack of definitive prothoracic ventral setal belts. These results indicate that Scr⁺ is necessary for normal development of the prothorax and are consistent with earlier interpretations based on adult phenotypes. Five other lethal complementation sites, assigned to polytene chromosome interval 84A-B1,2 have been analyzed. They are not associated with dominant homoeotic phenotypes in the adult. The terminal phenotype of individuals carrying lethal mutations in the W36, R11, or R14 complementation groups demonstrate that these loci are important in normal anterior development and/or body segmentation and suggest functional relationships to the homoeotic mutations previously localized to the 84A-84B1,2 polytene interval.     

Homoeosis in Drosophila: The Lethal Syndrome of the Regulator of bithorax (or trithorax) Locus and Its Interaction with Other Homoeotic Loci

Regulator of bithorax (Rg-bx)^- [or trithorax (trx)^-] lethal zygotes show anterior transformations of various cuticular features of the larval thorax and abdomen. The Rg-bx^- lethal syndrome depends on the dosage of the bithorax gene complex (BX-C), and lack of Rg-bx⁺ function is antagonistic to posterior transformations displayed by Polycomb ( Pc)^- embryos. Significantly, when the BX-C is deleted, the Rg-bx^- embryos disclose homoeosis of mesothoracic to prothoracic cuticular structures. This homoeotic transformation is due to a reduction in Antennapedia (Antp)⁺ gene activity and is consequently dependent on the dosage of the Antennapedia gene complex (ANT-C), suggesting that the Rg-bx⁺ activity is necessary for proper expression of the Antp⁺ gene. However, the functional relationship between the Rg-bx and Sex combs reduced (Scr) loci in embryogenesis is still to be established.     

Revertants of Dominant Mutations Associated with the Antennapedia Gene Complex of DROSOPHILA MELANOGASTER: Cytology and Genetics

Using X-ray mutagenesis we have induced and recovered phenotypic revertants of four dominant mutations thought to be associated with the Antennapedia complex of Drosophila melanogaster. These include seven revertants of Antennapedia-73b (Antp^73b), six of Extra Sex Combs of Wakimoto (Scx^w), three of Deformed (Dfd) and one of Humeral (Hu). Fifteen of the 17 revertants are associated with chromosomal aberrations and localize Antp^73b, Scx ^w and Hu to polytene chromosome bands 84B1,2. The Dfd lesion is apparently located in or adjacent to bands 84A4,5. Since all of the dominants are reverted by events that delete their respective chromosomal loci, we conclude that all four are the result of a gain-of-function lesions. Complementation analysis of the various revertant chromosomes has shown that Scx^w and Hu are dominant allelic variants of the Antp locus. The Dfd lesion represents a dominant mutation at a locus just proximal to Antp and previously only occupied by recessive lethal mutations. Characterization of the revertants of Scx^w and a comparison with the properties of the original mutation has revealed that the original lesion has effects on both the Antp and Sex Combs Reduced (Scr) loci and that these defects are in some cases separable by the reverting event.     

Genetic Analysis of the Antennapedia Gene Complex (Ant-C) and Adjacent Chromosomal Regions of DROSOPHILA MELANOGASTER. II. Polytene Chromosome Segments 84A-84B1,2

The existence of a gene complex in the proximal right arm of chromosome 3 of Drosophila melanogaster involved in the development of the head and thorax was originally suggested by the phenotypes of several dominant homoeotic mutations and their revertants. A screen for mutations utilizing Df(3R) Antp^Ns+R17 (proximally broken in salivary region 84B1,2) yielded, among 102 recovered mutations, 17 localized by deficiency mapping to the putative homoeotic cluster. These fell into four complementation groups, two of which were characterized by homoeotic phenotypes. To explore the limits of the Antennapedia gene complex (ANT-C) more proximally, a second screen has been undertaken utilizing Df(3R)Scr, a deficiency of 84A1–B1,2.—Of 2832 chromosomes screened, 21 bearing alterations localized to polytene interval 84A–84B1,2 have been recovered. Sixteen are recessive lethals, and five showing reduced viability display a visible phenotype in surviving individuals. Complementation and phenotypic analyses revealed four complementation groups proximal to those identified in the previous screen, including two new alleles of the recessive homoeotic mutation, proboscipedia (pb). Ten of the new mutations correspond to complementation groups defined previously in the Df(3R)Antp^Ns+R17 screen four to the EbR11 group, two to the Scr group and four to the Antp group.—On the basis of the phenotypes of the 39 mutations localized to this region, plus their interactions with extant homoeotic mutations, we postulate that there are at least five functional sites comprising the ANT-C. Three have been demonstrated to be homoeotic in nature. The specific homoeotic transformations thus far observed suggest that these loci are critical for normal development of adult labial, maxillary and thoracic structures.     

Pattern formation and determination in the antenna of the homoeotic mutant Antennapedia of Drosophila melanogaster

The development of the antenna in the antennal-leg homoeotic mutant Antennapedia (Antp^R) was investigated using somatic crossing-over to mark clones of cells in Antp^R antennal appendages. Antp^R antennae ranged from a nearly normal antenna to a nearly normal leg. The arrangement of clones of marked bristles and cuticle in the more antennalike antennae was similar to the wild type antenna, and that of the leglike antennae was similar to the wild-type leg. The contiguity of clones argued against extensive individual cell migration. The regions occupied by homoeotic leg varied considerably between different Antp^R antennae. Observation of Antp^R antennae in these phenotypic mosaics showed that specific leg parts replaced specific antennal parts. Even small groups of leg sensilla appeared only at precise locations in the antenna. These results suggest that homoeotic leg cells and antennal cells can both respond to the same positional information or prepattern. An analysis of clone size provided estimates for cell number in the Antp^R antenna. It was found that cell numbers in the wild-type and Antp^R antennae are about the same until the third instar, when the Antp^R cells start dividing more rapidly than wild type. Previous work had shown that clonal inheritance of a commitment for homoeotic leg also did not occur prior to the early third instar. It is suggested that determination for homoeotic leg occurs in the early third instar, and that thereafter this commitment is inherited by the progeny of the determined cells. The increase in growth rate is probably due to a faster growth rate in cells with a leg commitment than in cells with an antennal commitment. The results suggest that, once initiated, determination may be of two types—a clonally inherited determination (for example, to be homoeotic leg) and an environmental determination (for example, to be a specific part of a homoeotic leg). Clonal inheritance of determination in normal embryonic development and in sex determination in intersexes is discussed.     

Homoeosis in Drosophila: a new enhancer of polycomb and related homoeotic mutations

A new recessive lethal mutation in Drosophila melanogaster , Enhancer of Polycomb [E(Pc)], and chromosomal deficiencies lacking this locus act as dominant enhancers of the Polycomb mutant syndrome in adults. Thus, although E(Pc)/+ flies are phenotypically normal, this locus is haplo-abnormal with respect to its effect on the Polycomb phenotype. Recombinational and deficiency mapping localize the E(Pc) locus on chromosome 2 proximally and very closely linked (~0.1 map unit) to the engrailed gene. E(Pc) enhances the expression of all Polycomb point mutations examined including that of a deficiency, indicating that this interaction does not depend on the presence of an altered Polycomb gene product. In several respects the mutations extra sex comb, lethal(4)29, and Polycomblike resemble those at the Polycomb locus. In the presence of E(Pc), recessive alleles of extra sex comb and lethal(4)29 are rendered slightly pseudodominant, and the homoeotic effects of Polycomblike heterozygotes are also enhanced. However, E(Pc) does not affect the expression of dominant mutations within the Bithorax gene complex (Cbx) or Antennapedia gene complex (Antp^Ns, Antp^73b, Antp^scx , Antp^EfW15, Scr^Msc) which give homoeotic transformations resembling those of the Polycomb syndrome. Available evidence from the study of adult phenotypes suggests that mutations at E(Pc) do not result in homoeotic changes directly but instead modify the expression of a specific set of functionally related homoeotic variants.     

Direct control of antennal identity by the spineless-aristapedia gene of Drosophila

Summary Loss-of-function mutations in the spineless-aristapedia gene of Drosophila (ss ^a mutants) cause transformations of the distal antenna to distal second leg, deletions or fusions of the tarsi from all three legs, a general reduction in bristle size, and sterility. Because ss ^a mutants are pleiotropic, it has been suggested that ss ⁺ has some rather general function and that the ss ^a antennal transformation is an indirect consequence of perturbations in the expression of other genes that more directly control antennal or second leg identity. Here we test whether the ss ^a transformation results from aberrant expression of Antennapedia (Antp), a homeotic gene thought to specify directly the identity of the second thoracic segment. We find that Antp ^– ss ^a mitotic recombination clones in the distal antenna behave identically to Antp ⁺ ss ^a clones, and are transformed to second leg. This demonstrates that the ss ^a antennal transformation is independent of Antp ⁺, and suggests that ss ⁺ may itself directly define distal antennal identity. The results also reveal that Antp ⁺ is not required for the development of distal second leg structures, as these develop apparently normally in Antp ^– ss ^a antennal clones. Because Antp ^– mutations cause deletions or transformations that are restricted to proximal structures, whereas ss ^a alleles cause similar defects that are distally restricted, we suggest that ss ⁺ and Antp ⁺ may play similar, but complementary, roles in the distal and proximal portions of appendages, respectively.     

Localization of the Antennapedia protein in Drosophila embryos and imaginal discs

Antibodies have been raised against a fusion protein containing the 3' region of the coding sequence of the Antennapedia (Antp) gene fused to β-galactosidase. The distribution of the protein on whole mount embryos and imaginal discs of third instar larvae was examined by immunofluorescence. In young embryos, expression of the Antp protein was limited to the thoracic segments in the epidermis, whereas it was found in all neuromeres of head, thorax and abdomen. At the end of embryogenesis, the Antp protein mainly accumulated in the ventral nervous system in certain parts of the thoracic neuromeres, from posterior T1 to anterior T3, with a gap in posterior T2. Comparison of Antp protein distribution in nervous systems from wild-type and Df P9 embryos, lacking the genes of the Bithorax-complex (BX-C), revealed a pattern of expression which indicated that the BX-C represses Antp in the posterior segments with the exception of the last abdominal neuromeres (A8-9) which are regulated independently. The protein pattern in nervous systems from Sex combs reduced(Scr^xF9) mutant embryos was indistinguishable from that found in wild-type embryos; thus, neurogenic expression of Antp in T1 and the more anterior segments does not appear to be under the control of Scr⁺. All imaginal discs derived from the three thoracic segments express Antp protein. The distribution was distinct in each disc; strongest expression was observed in the proximal parts of the discs. In the leg discs the protein distribution seemed to be compartmentally restricted, whereas in the wing disc this was not the case. Antp protein was not detected in the eye-antennal disc. In embryos, as well as in imaginal discs, the protein is localized in the nucleus.     

Cytogenetic Analysis of Chromosome 3 in DROSOPHILA MELANOGASTER: Isolation and Characterization of Four New Alleles of the Proboscipedia (pb) Locus

Previous studies on proximal 3R have cytologically localized the dominant homeotic loci Antennapedia (Antp), Multiple Sex Comb (Msc), Nasobemia (Ns), and Extra Sex Comb (Scx). In this study we set out to find the site of the proboscipedia (pb) locus. In order to accomplish this, four new alleles of this homeotic gene were induced with gamma rays. Genetic and cytogenetic analyses have shown that the pb locus resides in polytene chromosome bands 84A1–6, immediately adjacent to the Antp gene complex in 84B1–2. An analysis of the morphology of the proboscis and the dose relationships of the four new alleles have shown that this homeosis is unusual in at least two respects. First, the two different developmental fates realized in the proboscis at 18° (labial palps → arista) and 29° (labial palps → leg) under the influence of pb¹ grown at 18°, while the remaining three are like pb¹ at 29°. Dosage studies reveal that this difference reflects a hypomorphic vs. amorphic condition. Second, like the original, these new alleles produce a prothoracic rather than a mesothoracic leg in the proboscis. Both of these results indicate that pb is unique among the homeotics, and as such it may offer some new insights into developmental processes.     

Polycomblike: A Gene That Appears to Be Required for the Normal Expression of the Bithorax and Antennapedia Gene Complexes of DROSOPHILA MELANOGASTER

A newly identified gene is described that is required for the maintenance of normal identities in many of the body segments of the fly. The effects of mutants in this gene, which is called Polycomblike (Pcl), suggest that its wild-type allele functions in the regulation of the bithorax gene complex (BX-C) and the Antennapedia gene complex (ANT-C). Evidence in favor of this idea derives from (1) the close correspondence between segmental transformations caused by Pcl mutants and those caused by dominant gain-of-function mutants in the BX-C and ANT-C, (2) the interactions observed between Pcl mutants and mutants in these complexes, and (3) the dependence upon BX-C and ANT-C dosage of the severity of at least one of the transformations caused by Pcl mutants. Arguments are presented that the control of the BX-C and ANT-C by Pcl⁺ is negative in nature. The results of clonal analysis experiments indicate that, at least for the BX-C, Pcl⁺ exerts this control until late in development. Since the wild-type allele of another gene, called Polycomb (Pc), has previously been shown to have many of the same properties as Pcl⁺, it appears that the BX-C and perhaps also the ANT-C are continuously regulated during development by at least two and probably several other genes.     

Cytogenetic Analysis of Chromosome 3 in DROSOPHILA MELANOGASTER: The Homoeotic Gene Complex in Polytene Chromosome Interval 84a-B

Cytogenetic evidence is presented demonstrating that the 84A-B interval in the proximal portion of the right arm of chromosome 3 is the residence of a homoeotic gene complex similar to the bithorax locus. This complex, originally defined by the Antennapedia (Antp) mutation, controls segmentation in the anterior portion of the organism. Different lesions within this complex homoeotically transform portions of the prothorax, proboscis, antenna and eye and present clear analogies to similar lesions within the bithorax locus.     

Genetic interactions between the Polycomb locus and the Antennapedia and Bithorax complexes of Drosophila

Summary We have studied the embryonic and adult phenotypes of genetic combinations between Polycomb (Pc), Regulator of bithorax (Rg-bx) and the genes of the Bithorax complex (BX-C) and the Antennapedia complex (ANT-C). The products of Pc and Rg-bx genes act antagonistically, their mutant combinations leading to the ectopic expression of genes of the BX-C and ANT-C. The genetic analysis of the Pc locus suggests it is a complex gene. Pc⁺ products behave as members of a regulatory set that negatively control the expression of BX-C and ANT-C genes. Genetic combinations between different doses of Pc, Rg-bx and the genes of the BX-C and ANT-C have phenotypes which may be interpreted as resulting from ectopic derepression of posterior selector genes repressing selector genes of anterior segments. The transformation phenotypes of certain genetic combinations differ in embryos and adults. A model of regulation of the BX-C and the ANT-C genes during the imaginal cell proliferation is presented, in which the specification state is maintained by self-activation of a given selector gene and down modulation of other selector genes in the same cell.     

Control of the spineless antennal enhancer: Direct repression of antennal target genes by Antennapedia

It is currently thought that antennal target genes are activated in Drosophila by the combined action of Distal-less, homothorax, and extradenticle, and that the Hox gene Antennapedia prevents activation of antennal genes in the leg by repressing homothorax. To test these ideas, we analyze a 62 bp enhancer from the antennal gene spineless that is specific for the third antennal segment. This enhancer is activated by a tripartite complex of Distal-less, Homothorax, and Extradenticle. Surprisingly, Antennapedia represses the enhancer directly, at least in part by competing with Distal-less for binding. We show that Antennapedia is required in the leg only within a proximal ring that coexpresses Distal-less, Homothorax and Extradenticle. We conclude that the function of Antennapedia in the leg is not to repress homothorax, as has been suggested, but to directly repress spineless and other antennal genes that would otherwise be activated within this ring.     

Head and tail development of the Drosophila embryo involves spalt, a novel homeotic gene

Mutations in spalt (sal), a novel homeotic gene on the second chromosome of Drosophila, cause opposite transformations in two subterminal regions of the embryo: posterior head segments are transformed into anterior thoracic structures and anterior tail segments are transformed into posterior abdominal structures. The embryonic phenotypes of double mutants for sal and various Antennapedia (ANT-C) or bithorax (BX-C) genes indicate that sal acts independently of the hierarchical order of the latter gene complexes. Trans-regulatory gene mutations causing ectopic expression of ANT-C and BX-C genes do not change the realms of sal action. It is proposed that the region-specific action of the sal gene primarily promotes head as opposed to trunk development, while the BX-C gene AbdB distinguishes tail from head.     

Cytogenetic Analysis of Chromosome 3 in DROSOPHILA MELANOGASTER: Mapping of the Proximal Portion of the Right Arm

In order to define more precisely the most proximal portion of chromosome 3R in Drosophila melanogaster, several new chromosome aberrations involving this region have been recovered and analyzed. These new arrangements were recovered as induced reversions of two dominant mutations, Antp^Ns and dsx^D, located in the region of interest. The results of the analysis have allowed the localization of several existing mutations, have further elucidated the complex homoeotic locus which resides in this region, and have confirmed the efficacy of this type of screen in the analysis of specific chromosome regions.     

Maternal-Zygotic Gene Interactions during Formation of the Dorsoventral Pattern in Drosophila Embryos

Maternal-zygotic interactions involving the three genes dorsal (dl), twist (twi) and snail (sna) are described. The results suggest that all three are involved in the process by which the dorsoventral pattern of the Drosophila embryo is established. First, the lethal embryonic mutant phenotypes are rather similar. In homozygous twi or sna embryos invagination of the ventral presumptive mesodermal cells fails to occur, and the resulting embryos are devoid of internal organs. This is very similar to the dominant phenotype described for dl; in the case of dl, however, the effect is a maternal one dependent on the mutant genotype of the female. Second, a synergistic interaction has been found whereby dominant lethality of twi- or sna-bearing zygotes is observed in embryos derived from heterozygous dl females at high temperature. The temperature sensitivity of this interaction permitted definition of a temperature-sensitive period which is probably that of dl. This was found to extend from approximately 12 hr prior to oviposition to 2–3 hr of embryogenesis. A zygotic action for the dl gene in addition to the maternal effect was revealed by the finding that extra doses of dl⁺ in the zygotes can partially rescue the dominant lethality of heterozygous twi embryos derived from heterozygous dl females. Two possible interpretations of the synergism are considered: (1) twi and sna are activated in the embryos as a result of positional signals placed in the egg as a consequence of the functioning of the dl gene during oogenesis and, thus, play a role in embryonic determination. (2) The gene products of dl⁺ and twi ⁺ (or sna⁺) combine to produce a functional molecule that is involved in the specification of dorsoventral pattern in the early embryo.     

Polyhomeotic: A gene of Drosophila melanogaster required for correct expression of segmental identity

Summary A new locus in Drosophila melanogaster that is required for the correct expression of segmental identity has been discovered. The new locus, termed polyhomeotic (ph), is X-linked and maps cytologically to bands 2D2-3. Homozygous ph flies have homeotic transformations similar to those of known dominant gain of function mutants in the Antennapedia and bithorax complexes (ANT-C, BX-C), and in addition show loss of the humerus. ph interacts with three other similar mutations: Polycomb (Pc), Polycomblike (Pcl), and extra sex comb (esc), and acts as a dominant enhancer of Pc. The expression of ph depends on the ANT-C and BX-C dosage. ph has no embryonic phenotype, but temperature shift studies on ph ² show that the ph ⁺ product is required during embryogenesis and larval development. We propose that ph mutants in some way disrupt the normal expression of the ANT-C and BX-C, and, therefore, that ph ⁺ is needed for maintenance of segmental identity.     

Isolation of synthetic lethal mutations in combination with spnab2 of fission yeast

spNab2 is a fission yeast, Schizosaccharomyces pombe, homologue of the budding yeast Nab2 protein that is an essential poly(A)⁺ RNA-binding protein required for both nuclear export of mRNA to cytoplasm and poly(A)⁺ tail length control. Here we performed a synthetic lethal genetic screen in the fission yeast to isolate mutants that are genetically linked to spnab2. We isolated three mutants that showed synthetic lethality under the repressed condition of the spnab2 expression. These mutants defined in different complementation groups. All the mutants exhibited the accumulation of poly(A)⁺ RNA in the nucleus under the restricted condition. In addition, the growth defects of one mutant (SLnab2) were complemented partially by some genes (mlo3 and rae1) required for mRNA export, while those of the rest (SLnab1 and SLnab3) were not complemented by any S. pombe genes we tested, which were known to be involved in mRNA export. These results suggest that the isolated mutants might harbor mutations in novel genes functionally linked to the spnab2 gene.