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.     

Developmental studies of lethality associated with the antennapedia gene complex in Drosophila melanogaster

A number of dominant homoeotic mutations are localized to the proximal right arm of chromosome 3 of Drosophila melanogaster and are thought to represent members of a gene complex that controls normal determinative decisions in the head and thorax. We have designated this complex the Antennapedia gene complex (ANT-C). Developmental studies were done to investigate the nature of the lethality associated with members of two of the complementation groups within ANT-C. The first complementation group, represented by the mutant Multiple Sex Combs (Msc) is characterized by embryonic lethality when heterozygous with a deletion of the ANT-C. The second complementation group consists of Antennapedia (Antp), Antennapedia-Extra Sex Combs (Antp^Scx), and the lethals recovered as revertants of Antp^Ns. When heterozygous for a deletion of the ANT-C or in heterozygous condition with each other, the members of this group show effective lethal phases spanning from embryo-larval boundary to late larval stages. Wakimoto and Kaufman (1981) show that the Antp⁺ gene acts to establish normal determinative states in the thorax. In the present work, transplantation of eye-antennal disks from lethal individuals heterozygous for two different Antp^Ns revertant chromosomes into wild-type hosts allowed the assessment of the function of the Antp⁺ allele in the antenna. Since these transplants formed only antennal structures and showed no evidence of the antennal → leg transformation seen in Antp^Ns controls, we conclude that the wild-type function of the Antp locus is not necessary for the establishment and/or maintenance of the antennal determined state. We suggest that regulatory mechanisms associated with the Antp⁺ structural gene normally function both to allow its expression in the thorax and to repress it in the antenna.     

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.     

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.     

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.     

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.     

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.     

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.     

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.     

Dosage-Dependent Modifiers of Homoeotic Mutations in Drosophila melanogaster

The determination of segment identity in Drosophila melanogaster appears to be controlled by a small number of genes. In order to identity new components in the process, we have systematically screened the autosomal complement for loci that show a dosage-dependent interaction with mutations in previously characterized genes thought to be important in the determination of segment identity. The dominant homoeotic phenotype of mutations at four loci involved in thoracic leg determination (Pc, Pcl, Antp and Scr) were quantitated in flies bearing a series of synthetic duplications covering more than 99% of the autosomal complement. Twelve regions were identified that when present in three wild-type copies strongly enhanced or suppressed the phenotype of mutations at one or more of the four homoeotic loci examined. The effects of five of these regions appear to correspond to previously described homoeotic loci; the effects of the remaining seven appear to identify new loci involved in the determination of segment identity.     

A Second New Species of Ice Crawlers from China (Insecta: Grylloblattodea), with Thorax Evolution and the Prediction of Potential Distribution

Modern grylloblattids are one of the least diverse of the modern insect orders. The thorax changes in morphology might be associated with the changes of the function of the forelegs, wing loss, changes in behavior and adaptation to habitat. As temperature is the main barrier for migration of modern grylloblattids, the range of each species is extremely limited. The potential distribution areas of grylloblattids remain unclear. A second new species of ice crawlers (Insecta: Grylloblattodea), Grylloblattella cheni Bai, Wang et Yang sp. nov., is described from China. The distribution map and key to species of Grylloblattella are given. A comparison of the thorax of extant and extinct Grylloblattodea is presented, with an emphasis on the pronotum using geometric morphometric analysis, which may reflect thorax adaptation and the evolution of Grylloblattodea. Potential global distribution of grylloblattids is inferred. Highly diversified pronota of extinct Grylloblattodea may reflect diverse habitats and niches. The relatively homogeneous pronota of modern grylloblattids might be explained by two hypotheses: synapomorphy or convergent evolution. Most fossils of Grylloblattodea contain an obviously longer meso- and metathorax than prothorax. The length of the meso- and metathorax of modern grylloblattids is normally shorter than the prothorax. This may be associated with the wing loss, which is accompanied by muscle reduction and changes to the thoracic skeleton system. Threats to grylloblattids and several conservation comments are also provided.     

Trithorax: A new homoeotic mutation of Drosophila melanogaster causing transformations of abdominal and thoracic imaginal segments

Summary A new homoeotic mutation, trithorax ¹ (trx ¹), of Drosophila melanogaster is described which causes intersegmental transformations in both the adult thorax and abdomen. Specifically, the metathorax and ventral prothorax are partially transformed to mesothroax, whilst abdominal segments are partially transformed towards the first abdominal segment. Three variables are shown to influence the expressivity of the mutant phenotype: (1) presence of wild type copies of the gene in the female parent; (2) culture temperature during the first four hours of embryogenesis; (3) exposure of embryos to ether vapour at the blastoderm stage. In addition it is shown that phenocopies of the mutant phenotype can be induced by ether treatment of heterozygous trx ¹ embryos with a frequency higher than that of bithorax phenocopies in wild type embryos.These findings are together taken to imply that the mutated gene functions early during embryogenests, and that a common mechanism underlies the determination of all the thoracic and abdominal segments.     

Homoeosis in Drosophila. II. a Genetic Analysis of Polycomb

Three dominant mutant alleles of the Polycomb locus of Drosophila melanogaster are associated with homoeotic transformations of meso- and metathoracic to prothoracic legs, a homoeotic transformation of antennae to legs, and abnormalities of wings and some thoracic bristles. Puro and Nygrén (1975) localized Polycomb in the proximal left arm of chromosome 3 within salivary gland chromosome interval 77E,F-80. In the present study, the location and dosage relationships of this locus were examined, using translocation-generated segmental aneuploidy. The results indicate that Polycomb lies within interval 78C,D-79D, and that the locus is haplo-insufficient. Males hypoploid for this interval show meso- and metathoracic leg transformations, and both males and females show wing abnormalities. In addition, the legs of hypoploids of both sexes are shorter than those of wild-type flies, and show aberrancies of segmentation, chaetal number and distribution, and other morphological characteristics. Hypoploid flies do not express a homoeotic antennal-leg transformation, but the deficiency is associated with a Minute phenotype that is known to suppress this transformation in Polycomb flies; thus it cannot be ascertained whether the antennal-leg transformation is a haplo-insufficient phenotype. It is suggested that the expression of non-homoeotic pleiotropic effects provides a criterion for identifying homoeotic mutations that do not function directly in the establishment of determined states, but rather cause homoeosis indirectly. Polycomb is interpreted in this fashion, and it is suggested that the mutant syndrome may result from localized cell death.     

Defects in embryogenesis in mutants associated with the antennapedia gene complex of Drosophila melanogaster

Embryogenesis in individuals with mutations or deficiencies of the genes in the polytene interval 84A-84B1,2 of Drosophila melanogaster was examined using scanning electron microscopy (SEM). The developmental function of this region of chromosome 3 is of particular interest since it contains the Antennapedia Gene Complex (ANT-C), a gene cluster that includes the homoeotic proboscipedia (pb), Sex combs reduced (Scr), and Antennapedia (Antp) loci. The results of SEM studies, clonal analyses, and temperature-shift experiments show that the fushi tarazu (ftz) and zerknullt (zen) genes, which map between pb and Scr, are involved in processes initiated during embryogenesis. The activity of ftz+ appears to be required within the first 4 hr of development for the establishment of the proper number of segments in the embryonic germ band. Individuals with ftz mutations or deficiencies produce only half the normal number of segments. Each of the segments is twice the normal width and is apparently comprised of cells that would normally form two separate metameres. The zen allele is required from about 2-4 hr of embryogenesis. Mutations of this gene result in disturbances of morphogenetic movements during gastrulation. The mutant phenotype is characterized by the absence of the optic lobe, defects in involution of the head segments, and in some cases, failure of germ band elongation. A requirement during embryogenesis for the activities of other genes residing in the 84A-84B1,2 polytene interval is suggested by the phenotypes of individuals heterozygous or homozygous for chromosomal deficiencies. Using the deficiencies Df(3R)AntpNs+R17, Df(3R)Scr, and Df(3R)ScxW+RX2, we examined the effects of deleting the distal portions or all of the 84A-84B1,2 interval. The defects in deletion heterozygotes suggest that the wild-type activity of some gene(s) other than zen, within or just adjacent to the 84B1,2 doublet, is required to complete normal head involution. The deletion of all the loci in the 84A5-84B1,2 interval results in grossly abnormal morphology and morphogenesis of the gnathocephalic appendages of the embryo. From these studies we conclude that mutations and deficiencies of genes associated with the ANT-C have profound effects on embryogenesis. The mutant phenotypes suggest, in addition to ensuring proper segment identity, the wild-type alleles of the 84A-84B1,2 genes are necessary for normal segmentation and elongation of the germ band and normal head involution.     

Genetic interaction between homoeotic Sex combs reduced and Regulator of bithorax (or trithorax) genes of Drosophila melanogaster

Summary Regulator of bithorax (Rg-bx)^–, or trithorax (trx)^– lethal larvae occasionally show a homoeotic transformation of the dorsal prothorax to mesothoracic structures. This transformation suggests a reduced activity of the Sex combs reduced (Scr) gene on the basis of gene dosage studies, as well as enhanced expression of the phenotypes of the weak Scr ^– alleles in Rg-bx ^– larvae. Morphological observations of adult flies doubly heterozygous for Rg-bx and Scr mutations also suggest the enhancement of an aspect of Scr adult phenotypes. I conclude that the Rg-bx ⁺ gene function is required for the optimal expression of the Scr gene in larval and imaginai cells.     

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.     

Genetic Characterization of the Region between 86f1,2 and 87b15 on Chromosome 3 of DROSOPHILA MELANOGASTER

The region between 86F1,2 and 87B15 on chromosome 3 of Drosophila melanogaster, which contains about 27 polytene chromosome bands including the 87A7 heat-shock locus, has been screened for EMS-induced visible and lethal mutations. We have recovered 268 lethal mutations that fall into 25 complementation groups. Cytogenetic localization of the complementation groups by deficiency mapping is consistent with the notion that each band encodes a single genetic function. We have also screened for mutations at the 87A7 heat shock locus, using a chromosome that has only one copy of the gene encoding the 70,000 dalton heat-shock protein (hsp70). No lethal or visible mutations at 87A7 were identified from 10,719 mutagenized chromosomes, and no female-sterile mutations at 87A7 were recovered from the 1,520 chromosomes whose progeny were tested for female fertility. We found no evidence that a functional hsp70 gene is required for development under laboratory conditions.     

Shortvein, a New Component of the Decapentaplegic Gene Complex in DROSOPHILA MELANOGASTER

Our laboratory has been concerned with the structure and function of the decapentaplegic gene complex (DPP-C) in Drosophila melanogaster . To define the boundaries of the complex, we have studied the genetics of mutations allelic to a previously discovered mutation shortvein (shv ), known to reside near decapentaplegic. We found that shortvein resides distal to Hin-d and dpp within the same polytene chromosome doublet, 22F1-2. Lesions in shv can affect not only the formation of the wing veins but also can interfere with normal development of parts of the adult and/or be lethal. Like those of dpp mutants, the shv-associated adult abnormalities affect distal epidermal structures. Some shv lesions cause a larval lethal syndrome which is associated with an unusually long larval stage (ca. five to six times its normal duration). Lesions in shv exhibit an involved pattern of complementation with dpp mutations, indicating that both shv and dpp are parts of a single gene complex. A subset of the array of mutant phenotypes displayed by shv/dpp trans-heterozygotes appear to be dpp-specific phenotypes; we interpret these as reflecting an inactivation effect of certain shv alleles on dpp functions. The other abnormalities displayed by these trans-heterozygotes appear to be shv-specific defects; we view these as indicating an inactivation effect of certain dpp mutations on shv functions. Furthermore, embryonic lethal (EL) mutations within the DPP-C exhibit allelic interactions with all shv mutations. We conclude that the shortvein region represents a newly identified integrated portion of the DPP-C.     

Lethals, Steriles and Deficiencies in a Region of the X Chromosome of CAENORHABDITIS ELEGANS

Twenty-one X-linked recessive lethal and sterile mutations balanced by an unlinked X-chromosome duplication have been identified following EMS treatment of the small nematode, Caenorhabditis elegans. The mutations have been assigned by complementation analysis to 14 genes, four of which have more than one mutant allele. Four mutants, all alleles, are temperature-sensitive embryonic lethals. Twelve mutants, in ten genes, are early larval lethals. Two mutants are late larval lethals, and the expression of one of these is influenced by the number of X chromosomes in the genotype. Two mutants are maternal-effect lethals; for both, oocytes made by mutant hermaphrodites are rescuable by wild-type sperm. One of the maternal-effect lethals and two larval lethals are allelic. One mutant makes defective sperm. The lethals and steriles have been mapped by recombination and by complementation testing against 19 deficiencies identified after X-ray treatment. The deficiencies divide the region, about 15% of the X-chromosome linkage map, into at least nine segments. The deficiencies have also been used to check the phenotypes of hemizygous lethal and sterile hermaphrodites.     

Larval adipose tissue of homoeotic bithorax mutants of Drosophila.

In the homoeotic bithorax mutant combination bx³$\text{pbx}\text{Ubx}{}^{105}$ of Drosophila melanogaster, the metathoracic segment is transformed to a mesothoracic segment and the adult flies have an extra pair of wings in place of the paired halteres [Lewis, E. B. (1963). Amer. Zool.3, 33–56]. The morphology of the larval fat body, the number of cells in the fat body, and the distribution pattern of kynurenine autofluorescent materials (KAF+) in this tissue were compared in the homoeotic mutant and a wild-type strain. The mutant has an additional mass of adipose cells anterior to the posterior margin of the ventral commissure of the fat body. However, the total number of adipose cells in the two strains as well as the limits of the KAF+ cell population do not differ. Therefore, the bithorax transformation in the larval fat body involves rearrangement of the same cell population as that in the normal strain. This study suggests (1) that the bithorax mutant genes affect the pattern of cell segregation and/or migration of preblastoderm nuclei during embryogenesis and (2) that the larval fat body of Drosophila has a segmental origin.