A gene that regulates the bithorax complex differentially in larval and adult cells of Drosophila

Loss-of-function mutations of a new homeotic gene, sxc, in Drosophila cause transformations of body segments, suggesting inappropriate expression of BX-C and ANT-C genes. I present evidence that sxc+ is required during embryogenesis for the selective repression of the BX-C in different larval segments and show that this requirement may be met entirely by maternally derived gene product. sxc+ is also required later in development to ensure the appropriate expression of ANT-C and BX-C genes in adult thoracic and abdominal segments. Absence of sxc+ in the mesothorax apparently results in the ectopic expression of the bx+ (or Ubx+) function in both the anterior and posterior compartments; this suggests that pbx mutations may define a regulatory rather than a structural function.     

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.     

Ectopic expression of homeotic genes caused by the elimination of the Polycomb gene in Drosophila imaginal epidermis

The morphological patterns in the adult cuticle of Drosophila are determined principally by the homeotic genes of the bithorax and Antennapedia complexes. We find that many of these genes become indiscriminately active in the adult epidermis when the Pc gene is eliminated. By using the Pc3 mutation and various BX-C mutant combinations, we have generated clones of imaginal cells possessing different combinations of active homeotic genes. We find that, in the absence of BX-C genes, Pc- clones develop prothoracic patterns; this is probably due to the activity of Sex combs reduced which overrules Antennapedia. Adding contributions of Ultrabithorax, abdominal-A and Abdominal-B results in thoracic or abdominal patterns. We have established a hierarchical order among these genes: Antp less than Scr less than Ubx less than abd-A less than Abd-B. In addition, we show that the engrailed gene is ectopically active in Pc- imaginal cells.     

The function ofbithorax genes in the abdominal central nervous system ofDrosophila

Summary We have analysed the influence of the bithorax gene complex (BX-C) on two segment-specific features of the central nervous system ofDrosophila larvae: the “presumptive leg neuromeres” (PLN), which are present only in the thoracic ganglia of the larva and develop into the leg neuromeres of the adult fly during metamorphosis; and the “lateral dots” (LD) which are found in the first abdominal as well as thoracic ganglia. We show in both cases that consecutive BX-C genes can suppress the development of these structures. We also show that each gene is expressed in several consecutive segments, leading to an apparent redundancy of the suppression in posterior segments.     

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.     

Segmental determination in Drosophila central nervous system: analysis of the abdominal-A region of the bithorax complex.

The bithorax complex (BX-C) comprises several genes required for the diversification of posterior segments in Drosophila. The BX-C genes control segment differences not only in the epidermis but in other tissues as well, especially in the central nervous system. We have examined the control of one segment-specific neural structure: the lateral dots, a paired structure present in the first abdominal segment of the larval CNS and absent in all following abdominal segments. Our results show that the suppression of lateral dots in segments A3 and A4 requires the presence of two active copies of one of the BX-C genes, abdominal-A (abd-A). We also show that the adjacent BX-C regions, iab-3 and iab-4, can act in trans on abd-A not only when the two copies of BX-C are paired but also, at least to some extent, when pairing is disturbed.     

Double and triple mutant combinations of bithorax complex of Drosophila

We have constructed double and triple mutant combinations for the Ubx, abd-A and Abd-B genes of the bithorax complex and have examined the homeotic transformations they produce in the larval and adult patterns. Embryos hemizygous for the triple combination exhibit a metameric pattern consisting of parasegments 5-12 being transformed into parasegment 4. In addition, parasegment 13 develops like a mixture of parasegment 3 and 4, and parasegment 14 is abnormal. The same phenotype is displayed by embryos homozygous for DfP9, lacking all the BX-C DNA, >300 kb. This result strongly supports the notion that the BX-C contains only three genes which account for all the developmental functions of the complex. The phenotypes of the different double combinations also support the same view; the Ubx abd-a comthoracic and several abdominal functions. The abd-A Abd-B combination exhibits the same phenotype of DpP10 DfP9, lacking all the abdominal functions except those specific for A1. Our results also indicate that each BX-C gene becomes active autonomously regardless of the presence or functional state of the other BX-C genes.     

Lethal bithorax complex mutations of Drosophila melanogaster show no germ line maternal effects

Three Ultrabithorax (Ubx) alleles and three different deficiencies of the bithorax complex (BX-C) of Drosophila melanogaster have been tested for maternal effects in the germ line. The dominant female sterile technique was used. The Ubx alleles and a deletion of the abdominal region of the BX-C are homozygous viable in germ line clones and show no maternal effects. Two deletions which lack the proximal portion of the BX-C are lethal in the female germ line indicating either that these deficiencies lack genes apart from the BX-C that are necessary for fertility or that there are BX-C genes that are essential for normal maternal germ line function. The significance of the bias in the isolation of only zygotic mutations at the BX-C are discussed with respect to these results.     

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.     

Duplicated neural structure in bithorax mutant Drosophila

The bithorax complex (BX-C) of genes in Drosophila control the segmental identity of the thoracic and abdominal cuticle. In flies containing BX-C mutations causing meta- to mesothoracic transformation, the mesothoracic branching pattern of a well-studied identified neuron is faithfully duplicated in the metathoracic ganglion. Thus these mutations also cause the duplication of mesothoracic cues involved in this neuron's branching.     

hunchback, a gene required for segmentation of an anterior and posterior region of the Drosophila embryo

The locus hunchback (hb) is a member of the gap class of segmentation genes of Drosophila. A number of X-ray-induced deletions locate the hb locus at the chromosomal site 85A3-B1, to the right of the pink locus, which maps in the same interval. A total of 14 EMS and 3 X-ray-induced hb alleles have been studied. Homozygous mutant embryos show deletions of segments in two separate regions. In the six strong alleles, the labium and all three thoracic segments are deleted anteriorly while posteriorly the 8th abdominal segment and adjacent parts of the 7th abdominal segment are lacking. The eight weak alleles show smaller deletions both in the thoracic and posterior abdominal region. In the weakest allele only part of the mesothorax is deleted. Three hb alleles produce a homoeotic transformation: superimposed on a strong or weak deletion phenotype, head or thoracic segments are transformed into abdominal segments, respectively. This suggests that hb might also be involved in the regulation of genes in the Bithorax complex (BX-C). Fate mapping of the normal-appearing segments in strong mutant embryos using the UV-laser beam ablation technique (Lohs-Schardin et al., 1979) shows that these segments arise from the normal blastoderm regions. The mutant phenotype can be recognized soon after the onset of gastrulation in a failure to fully extend the germ band. In 6-hr-old mutant embryos, two clusters of dead cells are observed in the thoracic and posterior abdominal region. These observations indicate region specific requirement of hb gene function. The analysis of germ line chimeras by transplantation of homozygous mutant pole cells shows that hb is already expressed during oogenesis. Homozygous mutant embryos derived from a homozygous mutant germ line have a novel phenotype. The anterior affected region is enlarged, including all three gnathal segments and the anterior three abdominal segments. In addition three abdominal segments with reversed polarity are formed between the remaining head structures and the posterior abdomen. Heterozygous mutant embryos derived from a homozygous mutant germ line develop normally, indicating that maternal gene expression is not required for normal development.     

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.     

Regulatory elements of the bithorax complex that control expression along the anterior-posterior axis

The Drosophila bithorax complex (BX-C) controls segmental development by selectively deploying three protein products, Ubx, abd-A and Abd-B, within specific segments along the body axis. Expression of these products within any one segment (or, more accurately, parasegment) is affected by mutations clustered in a particular region of the BX-C. The regulatory regions defined by this genetic analysis span 20-50 kb and there is one region for each segmental unit. Here we describe regulatory elements from several of these regions, identified by fusion to a Ubx-lacZ gene and analysis in germline transformants. A small DNA fragment from the abx region programs expression with an anterior boundary in the second thoracic segment (parasegment 5). This anterior limit is appropriate, since the abx region normally controls Ubx in parasegment 5. Other regulatory regions of the BX-C that control development of parasegments 6, 7 or 8 contain similar regulatory elements that program expression with anterior limits in parasegments 6, 7 or 8, respectively. These experiments define a class of BX-C regulatory elements that control expression along the anterior-posterior axis. The early appearance of the lacZ patterns in embryos suggests a role for these elements in the initial activation of expression from the BX-C.     

Establishment of imaginal discs and histoblast nests in Drosophila

In Drosophila the homeotic genes of the bithorax-complex (BX-C) and Antennapedia-complex (ANT-C) specify the identity of segments. Adult segment primordia are established in the embryo as the histoblast nests of the abdomen and the imaginal discs of the head, thorax and terminalia. We have used a molecular probe for the limb primordia and in vivo culture to describe the nature of the adult primordia in mutants in which the pattern of homeotic gene expression was altered. The results suggest that the histoblast or disc 'mode' of development is initiated by the extended germ band stage through activity of the BX-C and ANT-C and is relatively inflexible thereafter [corrected].     

Ectopic expression of UBX and ABD-B proteins during Drosophila embryogenesis: competition, not a functional hierarchy, explains phenotypic suppression.

The Abdominal-B (Abd-B) gene, a member of the bithorax complex (BX-C), specifies the identities of parasegments (PS) 10-14 in Drosophila. Abd-B codes for two structurally related homeodomain proteins, ABD-B m and ABD-B r, that are expressed in PS10-13 and PS14-15, respectively. Although ABD-B m and r proteins have distinct developmental functions, ectopic expression of either protein during embryogenesis induces the development of filzk?rper and associated spiracular hairs, structures normally located in PS13, at ectopic sites in the larval thorax and abdomen. These results suggest that other parasegmental differences contribute to the phenotype specified by ABD-B r activity in PS14. Both ABD-B m and r repress the expression of other homeotic genes, such as Ubx and abd-A, in PS10-14. However, the importance of these and other cross-regulatory interactions among homeotic genes has been questioned. Since ectopic UBX protein apparently failed to transform abdominal segments, González-Reyes et al. (González-Reyes, A., Urquía, N., Gehring, W.J., Struhl, G. and Morata, G. (1990). Nature 344, 78-80) proposed a functional hierarchy in which ABD-A and ABD-B activities override UBX activity. We tested this model by expressing UBX and ABD-B m proteins ectopically in wild-type and BX-C-deficient embryos. Ectopic ABD-B m does not prevent transformations induced by ectopic UBX. Instead, ectopic UBX and ABD-B m proteins compete for the specification of segmental identities in a dose-dependent fashion. Our results support a quantitative competition among the homeotic proteins rather than the existence of a strict functional hierarchy. Therefore, we suggest that cross-regulatory interactions are not irrelevant but are important for repressing the expression of competing homeotic proteins. To explain the apparent failure of ectopic UBX to transform the abdominal segments, we expressed UBX at different times during embryonic development. Our results show that ectopic UBX affects abdominal cuticular identities if expressed during early stages of embryogenesis. In later embryonic stages, abdominal segments become resistant to transformation by ectopic UBX while thoracic segments remain susceptible. Head segments also show a similar stage-dependent susceptibility to transformation by ectopic UBX in early embryogenesis but become resistant in later stages. These results suggest that abdominal and head identities are determined earlier than are thoracic identities.