Chromosomal continuity in the abdominal region of the bithorax complex of Drosophila is not essential for its contribution to metameric identity

We have examined the developmental consequences for larval and imaginal segmental cuticular structure of a chromosomal translocation involving a breakpoint in the abdominal region of the bithorax complex (BX-C). This complex makes an essential contribution to the development of metameric differences in part of the thorax and in all abdominal segments. The breakpoint is proximal to the most distal (iab-7) homeobox, and results in the translocation to the Y chromosome of the Ultrabithorax (Ubx) and abdominal-A (abd-A) domains. The genotype deficient for the distal part of the complex shows normal function for Ubx and abd-A but has a phenotype typical for severe Abd-B mutations. Conversely, the distal fragment retains a segment identity function which must represent a contribution from Abd-B in parasegments 13 and 14; the latter metamere is wild type, indicating that it does not require the contribution of Ubx or abd-A. We also constructed a genotype comprising the proximal fragment of this translocation together with an overlapping distal fragment of the BX-C derived from Df(3R)Ubx109. It therefore contained all sequences of the BX-C though in the abdominal region the abd-A and Abd-B domains were not adjacent to each other in the chromosome. This genotype was phenotypically normal and demonstrates that DNA sequences in the abd-A and Abd-B regions do not require cis-arrangement for their activity.     

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.     

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.     

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 Ultrabithorax gene of Drosophila and the specification of abdominal histoblasts.

Separation of the imaginal and larval developmental pathways in Drosophila occurs early in embryogenesis, resulting in the formation of imaginal discs and abdominal histoblast nests along the larval body wall. The dorsal and ventral histoblast nests within the first abdominal (A1) segment are shown not to be segmentally homologous with the metathoracic (T3) haltere and leg discs, respectively, since they occur at distinct dorso-ventral locations during normal development and can be found together within the same segment in mutants of the Bithorax complex (BX-C) where T3 is transformed towards A2-A4 or A1 towards T3. Several patterning abnormalities are also observed in BX-C mutants. A ventral shift in the A1 ventral nest occurs in partially transformed larvae harboring weak bithoraxoid (bxd) mutations; in more fully transformed larvae (Ubx1/Df) both the anterior dorsal and ventral nests are lost and instead a dorsal and ventral disc bud are formed. Dorso-ventral inversions in the pattern of the ventral nest occur in a random fashion throughout A1-A7 in response to an increase or decrease in the gene dosage of the BX-C. In gain-of-function mutants anterior dorsal histoblast cells form in the homologous anterior as well as the nonhomologous posterior portion of T3. Based on these and other findings it appears that the Ultrabithorax (Ubx) locus (and possibly abdominal-A and Abdominal-B) is required to steer ectodermal cells toward an imaginal histoblast rather than a larval cell fate at specific regions within the first abdominal segment.     

Transvection in the Iab-5,6,7 Region of the Bithorax Complex of Drosophila: Homology Independent Interactions in Trans

The Abdominal-B (Abd-B) gene of the bithorax complex (BX-C) of Drosophila controls the identities of the fifth through seventh abdominal segments and segments in the genitalia (more precisely, parasegments 10-14). Here we focus on iab-5, iab-6 and iab-7, regulatory regions of Abd-B that control expression in the fifth, sixth and seventh abdominal segments (parasegments 10-12). By analysis of partial BX-C deficiencies, we show that these regions are able to promote fifth and sixth abdominal segment identities in the absence of an Abd-B gene in cis. We establish that this ability does not result from cis-regulation of the adjacent abd-A or Ubx genes of the BX-C but rather occurs because the iab-5,6,7 region is able to interact with Abd-B in trans. We demonstrate that this interaction is proximity dependent and is, therefore, a case of what E. B. LEWIS has called transvection. Interactions of this type are presumably facilitated by the synapsis of homologues that occurs in somatic cells of Dipterans. Although transvection has been detected in a number of Drosophila genes, transvection of the iab-5,6,7 region is exceptional in two ways. First, interaction in trans with Abd-B does not require that homologues share homologous sequences within, or for some distance to either side of, the BX-C. This is the first case of transvection shown to be independent of local synapsis. A second unusual feature of iab-5,6,7 transvection is that it is remarkably difficult to disrupt by heterozygosity for chromosome rearrangements. The lack of requirement for local synapsis and the tenacity of trans-interaction argue that the iab-5,6,7 region can locate and interact with Abd-B over considerable distance. This is consistent with the normal role of iab-5,6,7, which must act over some 20-60 kb to influence its regulatory target in cis at the Abd-B promoter. Evidence is presented that trans-action of iab-5,6,7 requires, and may be mediated by, the region between distal iab-7 and Abd-B. Also, we show that iab-5,6,7 transvection is independent of the allelic state of zeste, a gene that influences several other cases of transvection. The long-range nature of interactions in trans between iab-5,6,7 and Abd-B suggests that similar interactions could operate effectively in organisms lacking extensive somatic pairing. Transvection may, therefore, be of more general significance than previously suspected.     

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.