Gene-dose titration analysis in the search of trans-regulatory genes in Drosophila.

We have searched for trans-regulatory genes in two genetic systems in Drosophila, the bithorax complex (BX-C) and the achaete-scute complex (AS-C). Previous genetic evidence suggests that the activation of both BX-C and AS-C, depends on trans-regulatory genes (Polycomb, Pc, in the former and hairy, h, in the latter) acting in a negative type of control. Mutants of these regulatory genes in heterozygous condition have dominant derepression phenotypes in flies with extra doses of the corresponding gene complexes. We have searched for new loci, with similar gene-dose relationships. We have isolated only new alleles (six) of Pc in the BX-C experiment. In the AS-C experiment four h alleles, and 13 alleles of a new locus (extramacrochaetae, emc) have been discovered. Whereas the h locus shows specific interactions upon achaete, the new locus, emc, is specific for the scute part of the AS-C. Statistical analysis suggests that these are the only loci in the genome with those dose-dependent properties in the two systems.     

asense, a member of the Drosophila achaete-scute complex, is a proneural and neural differentiation gene.

The asense (ase) gene of the achaete-scute complex (AS-C) is expressed in the precursors of all adult sensory organs (SOs), the sensory mother cells (SMCs) and in their immediate progeny. Its deletion causes the loss of some SOs and the abnormal differentiation of part of the remaining ones. These defects, which include malformations of the external part of the SOs, duplication of the innervating neuron etc, are enhanced by the haploid condition for the other AS-C genes and are corrected by an ase transgene. We conclude that ase participates, in combination with other members of the AS-C, in implementing the neural program of differentiation of the SMCs. ase also has a proneural function that participates in the singling out of the SMCs that give rise to the recurved bristles of the anterior wing margin. The proneural potential of ase is shown, in addition, by the generation of SOs induced by the generalized expression of an ase gene driven by a hsp70 promoter.     

Cell interactions in the generation of chaetae pattern inDrosophila

Summary We have already shown that theachaetae-scute complex (AS-C) ofDrosophila is regulated by two genes,hairy andextramacrochaetae. Using mutants in these genes, we have analysed how different levels of expression of AS-C affect the pattern of chaetae. The results indicate that the spatial distribution of chaetae results from cell interactions, probably by a mechanism of lateral inhibition. The results are discussed in view of the different theories of pattern formation.     

The determination of sense organs in Drosophila: interaction of scute with daughterless

Summary Several genetic loci have been implicated in the formation of the peripheral nervous system during Drosophila embryogenesis. As a first step towards understanding the functional interrelationships between these genes, we have searched for dominant interactions between deficiencies for the achaete-scute complex (AS-C), daughterless (da) and six other regions necessary for peripheral neurogenesis in the embryo. We have found that adult flies doubly heterozygous for deletions of AS-C and of da, or of AS-C and a small region on the fourth chromosome, exhibit characteristic bristle defects, suggesting that these genes cooperate to form sense organs both in the embryo and in the adult.     

Genetic analysis ofHairy-wing mutations

Summary We studied the genetic bases of threeHairy-wing (Hw ¹,Hw ^Ua ,Hw ^49c ) mutations mapping in the region of theachaete-scute complex (AS-C). Analysis of X-ray-induced revertants ofHw ¹ andHw ^49c uncoveredachaete andscute mutant phenotypes respectively. This indicates that theHw mutant phenotypes result from an excess of function of these genes of theachaete-scute complex (AS-C). The phenotypes of the differentHws show allelic specificity in the pattern of extrachaetes. In addition to these mutations, certain inversions and internal duplications of the AS-C also produce aHw-variegated phenotype, probably due to variegation or decompensation of the genes of the AS-C. The expressivity of the differentHws (mutation or variegation) is modulated by the number of doses of the AS-C present in the genome. A similar dose-dependent modulation is exerted by the transregulatory geneshairy andextramacrochaetae. We discuss these results on the basis of a regulation model of the expression of the AS-C.     

extramacrochaetae, a negative regulator of sensory organ development in Drosophila, defines a new class of helix-loop-helix proteins.

The function of the extramacrochaetae (emc) gene is required to establish the normal spatial pattern of adult sensory organs in Drosophila. emc acts to suppress sensory organ development in certain regions of the body surface, apparently by antagonizing the function of the achaete and scute genes of the achaetescute complex (AS.C). We have found that emc encodes a novel member of the helix-loop-helix (HLH) family of proteins. The emc protein shares the dimerization domain of other HLH proteins but lacks their DNA binding motif. We propose a model in which the emc protein negatively regulates sensory organ determination by forming heterodimers with the HLH proteins encoded by the AS-C and/or daughterless, thereby altering or interfering with their activity.     

A study of shaggy reveals spatial domains of expression of achaete-scute alleles on the thorax of Drosophila

A study of shaggy mutant clones on the notum reveals that a greater number of cells are diverted into the bristle pathway of differentiation and fewer cells remain to produce the epidermis, shaggy clones differentiate supernumerary microchaetae and macrochaetae but these are found in the correct spatial locations, e.g. clusters of macrochaetae are formed round the position of the extant macrochaetae. The shaggy mutant phenotype requires the functioning of the genes of the achaete-scute (AS-C) complex but a dosage study shows that it is unlikely that the AS-C is overexpressed in shaggy cells. Data are presented that argue, also, for a correct spatial expression of the AS-C in shaggy mutants. A study of clones doubly mutant for shaggy and different achaete and scute alleles is consistent with the hypothesis that the clusters of macrochaetae formed by shaggy represent the restricted spatial domains of expression of the AS-C. The results can be reconciled with the known role for the AS-C, in determining which bristle types differentiate where, and a role for shaggy in the cell interactions, within domains of the AS-C expression, leading to the definition of only one bristle mother cell.     

Genetic regulation of theAchaete-scute complex ofDrosophila melanogaster

Summary Mutants in two loci,hairy (h ⁺) andextramacrochaetae (emc ⁺), produce phenotypes corresponding to an excess of function of theachaete-scute complex (AS-C), that is, they cause the appearance of extra chaetae. These mutants, although recessive in normal flies, become dominant in the presence of extra doses of AS-C. Here we study the interactions between these three genes, in an attempt to elucidate their relationships. The results show that the insufficiency produced byh oremc mutants can be titrated by altering the number of copies of AS-C. Moreover, excess of function of AS-C produced by derepression mutants within the complex (Hairy-wing) can also be titrated by altering the number of wild type copies of⁺ oremc ⁺. These specific interactions indicate that bothh ⁺ andemc ⁺ code for repressors of AS-C that interact with theachaete andscute region of the complex respectively.     

Transcriptional activation by heterodimers of the achaete-scute and daughterless gene products of Drosophila

The achaete-scute complex (AS-C) and the daughterless (da) genes encode helix-loop-helix proteins which have been shown to interact in vivo and to be required for neurogenesis. We show in vitro that heterodimers of three AS-C products with DA bind DNA strongly, whereas DA homodimers bind weakly and homo or heterocombinations of AS-C products not at all. Proteins unable to dimerize did not bind DNA. Target sequences for the heterodimers were found in the promoters of the hunchback and the achaete genes. Using sequences of the former we show that the DNA binding results obtained in vitro fully correlate with the ability of different combinations to activate the expression of a reporter gene in yeast. Embryos deficient for the lethal of scute gene fail to activate hunchback in some neural lineages in a pattern consistent with the lack of a member of a multigene family.     

Wild-type and mutant actin genes in Caenorhabditis elegans

We have sequenced the four actin genes of Caenorhabditis elegans. These four genes encode typical invertebrate actins and are highly homologous, differing from each other by, at most, three amino acid residues. As a first step toward an understanding of the developmental regulation of this gene set we have also sequenced mutant actin genes. The mutant genes were cloned from two independent revertants of a single dominant actin mutant. For both revertants, reversion was accompanied by an actin gene rearrangement. The accumulation of actin mRNA during development in these two revertants is different from that of wild-type animals. We present here a correlation between actin gene structure and expression in wild-type and mutant animals. The results, suggest that co-ordinate regulation of actin genes is not essential for wild-type muscle function. In addition, it appears that changes in the 3' region of at least one of the actin mRNA may affect its steady-state regulation during development.