Gap genes define the limits of antennapedia and bithorax gene expression during early development in Drosophila.

The maintenance of selective patterns of homeotic gene expression within the Drosophila CNS involves cross-regulatory interactions among the genes of the antennapedia and bithorax complexes (ANT-C and BX-C). Such a mechanism does not appear to be responsible for the establishment of these selective expression patterns during early development. Here we show that mutations in several of the gap genes strongly alter the early patterns of Antp and Abd-B expression. The altered patterns that are observed do not always correlate with simple expectations based on cuticular pattern defects observed in advanced-stage mutants. It appears that the initial patterns of Antp and Abd-B expression involve their differential regulation by a common set of gap genes. We propose that the gap genes are largely responsible for integrating the processes of segmentation and homeosis.     

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.     

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].     

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.     

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.     

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.     

Rescue and regulation of proboscipedia: a homeotic gene of the Antennapedia Complex.

The extraordinary positional conservation of the homeotic genes within the Antennapedia and the Bithorax Complexes (ANT-C and BX-C) in Drosophila melanogaster and the murine Hox and human HOX clusters of genes can be interpreted as a reflection of functional necessity. The homeotic gene proboscipedia (pb) resides within the ANT-C, and its sequence is related to that of Hox-1.5. We show that two independent pb minigene P-element insertion lines completely rescue the labial palp-to-first leg homeotic transformation caused by pb null mutations; thus, a homeotic gene of the ANT-C can properly carry out its homeotic function outside of the complex. Despite the complete rescue of the null, the minigene expresses pb protein in only a subset of pb's normal domains of expression. Therefore, the biological significance of the excluded expression pattern elements remains unclear except to note they appear unnecessary for specifying normal labial identity. Additionally, by using reporter gene constructs inserted into the Drosophila genome and by comparing pb-associated genomic sequences from two divergent species, we have located cis-acting regulatory elements required for pb expression in embryos and larvae.     

A homologous protein-coding sequence in Drosophila homeotic genes and its conservation in other metazoans

The homeotic genes of the bithorax complex (BX-C) and the Antennapedia complex (ANT-C) of Drosophila appear to specify the developmental fate of segments or parts of segments of the fly. We have previously reported weak DNA sequence homology between 3' portions of the Antennapedia and fushi tarazu genes of the ANT-C and the Ultrabithorax gene of the BX-C. Here we show that this DNA homology (the homeo box) is due to a conserved protein-coding sequence present in these three pattern-formation genes. Thus the functional homology between these developmental controlling genes is reflected in a structural homology in their gene products. The homeo box sequence is also present in a few copies in the genomes of some other invertebrates, and is even conserved in vertebrate genomes, including the human genome. Apparently at least a part of these developmental switch genes from Drosophila is highly conserved during evolution, and might perform an analogous function in many metazoans .     

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.     

Control of female pheromones in Drosophila melanogaster by homeotic genes

We have investigated the role of the Antennapedia and Bithorax complexes (ANT-C and BX-C) on the production of cuticular hydrocarbons in Drosophila melanogaster. In males, there is little, if any, influence of these complexes on the hydrocarbon pattern. In females, there are large and opposite effects of these complexes on diene production: two ANT-C mutations cause an increase in diene production and a reduction of monoenes, whereas most BX-C mutations result in a decrease in dienes and an increase in monoenes, although their sum remains constant. The effect is the highest in Mcp and iab6 females. It is suggested that a factor originating from the prothorax might activate the conversion of monoenes to dienes in females. The abdomen seems to have a crucial role in the production or control of pheromones: abdominal segments four to seven have the main effects, with a most dramatic effect for segments four and five.     

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.     

Homeotic genes influence the axonal pathway of a Drosophila embryonic sensory neuron

Each abdominal hemisegment of the Drosophila embryo has two sensory neurons intimately associated with a tracheal branch. During embryogenesis, the axons of these sensory neurons, termed the v'td2 neurons, enter the CNS and grow toward the brain with a distinctive pathway change in the third thoracic neuromere. We show that the axons use guidance cues that are under control of the bithorax gene complex (BX-C). Pathway defects in mutants suggest that a drop in Ultrabithorax expression permits the pathway change in the T3 neuromere, while combined Ultrabithorax and abdominal-A expression represses it in the abdominal neuromeres. We propose that the axons do not respond to a particular segmental identity in forming the pathway change; rather they respond to pathfinding cues that come about as a result of a drop in BX-C expression along the antero-posterior axis of the CNS.     

Molecular cloning and characterization of homeo-box-containing genes from Atlantic salmon

As the most primitive group among vertebrates, fish might serve as a model system when studying the genetic regulation of embryogenesis in higher animals. To identify genes important for early development, we have constructed a genomic library from Atlantic salmon (Salmo salar) and screened it with homeobox-containing probes from Drosophila melanogaster. Five different salmon homeoboxes were isolated. Two of these were located in the same clone, separated by only 7.5 kb. This demonstrates the presence of clustered homeobox genes in fish. The two clustered homeoboxes were sequenced and shown to be closely related to the ANT-C/BX-C class of Drosophila, being about 80% homologous to the Ultrabithorax gene (Ubx) homeobox. One of the clustered genes appears to be the salmon equivalent of the mouse Hox-2.1 gene, indicating that some of the vertebrate homeobox-containing genes are conserved in evolution. A more diverged homeobox that shares only 60% homology with Ubx, was also sequenced. In analogy to Drosophila, therefore, the salmon genome contains more than one class of homeoboxes. In addition, Northern-blot experiments demonstrated that two of the homeobox genes are expressed in salmon embryos, suggesting their importance for proper development.