Histochemical analysis of the ecdysterone-regulated expression of the Drosophila genes P1 and LSP-2

3H-labeled DNA probes for the ecdysterone-inducible Drosophila genes P1 and LSP-2 were hybridized in situ to RNA in sections of embryos and larvae. Intense hybridization was detected specifically in fat body cells of third-instar larvae and not in other cells of third-instar larvae nor in any cells at earlier stages. These results confirm the stringent tissue- and stage-specificity of P1 and LSP-2 expression. Hybridization of both probes occurred to virtually all the cells in the fat bodies, indicating that both genes are expressed in the same cells. Since P1 expression begins several hours later than LSP-2 expression, and appears to be induced directly by ecdysterone, this finding implies that one or more of the fat body components mediating the response to ecdysterone is gene-specific.     

Developmental Arrest and Ecdysteroid Deficiency Resulting from Mutations at the Dre4 Locus of Drosophila

Loss-of-function mutations of the dre4 gene of Drosophila melanogaster caused stage-specific developmental arrest, the stages of arrest coinciding with periods of ecdysteroid (molting hormone) regulated development. Nonconditional mutations resulted in the arrest of larval development in the first instar; embryogenesis was not impaired, and mutant larvae were behaviorally normal and long-lived. At 31 degrees the temperature-sensitive dre4e55 allele caused the arrest of larval development in the first or second instars. When upshifted to 31 degrees at various times during development, dre4e55 mutants exhibited nonpupariation of third-instar larvae, failure of pupal head eversion, failure of adult differentiation, or noneclosion of pharate adults. Under some temperature regimens second-instar larvae pupariated precociously without entering the normally intervening third-instar. Nonpupariation and defects in metamorphosis were associated with the reduction or elimination of ecdysteroid peaks normally associated with late-larval, prepupal, pupal and pharate adult development. Ecdysteroid production by larval ring glands from dre4e55 hemizygous larvae was suppressed after 2 hr of incubation in vitro at 31 degrees, indicating autonomous expression of the dre4 gene in the ring gland. We postulate that the dre4 gene is required for ecdysteroid production at multiple stages of Drosophila development and that the pathologies observed in dre4 mutants reflect developmental consequences of ecdysteroid deficiency.     

Genetic Localization and Action of Regulatory Genes and Elements for Tissue-Specific Expression of alpha-Amylase in DROSOPHILA MELANOGASTER

Regulation of tissue-specific alpha-amylase (Amy) expression in Drosophila melanogaster was investigated with a newly developed method that detects the distribution of alpha-amylase allozymes in midguts of single adults or third-instar larvae. Trans regulation was found for alpha-amylase production in the posterior midgut (PMG) of adults, whereas cis regulation was demonstrated for the larval midgut. Independent regulation of components of the duplicated Amy locus was found in larvae. Recombination between the components of the Amy locus did not result in separation of the putative, very closely linked (less than 0.1 cM) cis-acting regulatory elements for alpha-amylase expression in the anterior midgut (AMG) of larvae. The expression of one of the components of the duplicated Amy locus in the AMG of larvae was influenced by a regulatory gene that was mapped at 2-79.1. alpha-Amylase expression in the adult PMG was controlled by a trans-acting regulatory gene localized at 2-79.0, in agreement with the data of Abraham and Doane.     

Regulation of synthesis of the larval serum proteins of Drosophila melanogaster

We have determined the relative amounts of subunits of larval serum proteins (LSPs) 1 and 2 during larval development in Drosophila melanogaster. These results indicate that synthesis of polypeptide subunits of LSP-1 and LSP-2 is coordinate: the proteins are first detected at the same time; they accumulate in a coordinate fashion; their RNAs are first detected at the same time; the RNAs also accumulate in similar relative amounts. Analyses of fat body polypeptides and fat body RNA indicate that synthesis of LSP-1 declines at a time when there are still substantial quantities of LSP-1 RNA in the cytoplasm. Cessation of LSP-1 subunit synthesis occurs before cessation of LSP-2 synthesis, indicating that at late times the genes (or mRNAs) for these two proteins are subject to different "switch-off" controls.     

Quantitative analysis of the amount of larval serum protein-1 (LSP-1) synthesized by flies with different doses of the LSP-1 coding sequences

Larval serum protein-1 (LSP-1) and LSP-2 are the major proteins of Drosophila larval serum. The amount of LSP-1 synthesized is strictly proportional to the number of LSP-1 genes present within the range 1-10. The normal number in female flies is 6. Flies with extreme amounts of LSP-1 were, by our criteria, as fit as the wild type. The ratio of LSP-2:LSP-1 was analyzed in 169 different stocks and was constant in 164 of these. The significantly different ratios in five stocks were all due to the lack of one of the LSP-1 gene products.     

Developmental Expression of the Glucose Dehydrogenase Gene in Drosophila Melanogaster

The Gld gene of Drosophila melanogaster is transiently expressed during every stage of development. The temporal pattern of Gld expression is highly correlated with that of ecdysteroids. Exogeneous treatment of third instar larvae with 20-hydroxyecdysone induces the accumulation of Gld mRNA in the hypoderm and anterior spiracular gland cells. During metamorphosis Gld is expressed in a variety of tissues derived from the ectoderm. In the developing reproductive tract, Gld mRNA accumulates in the female spermathecae and oviduct and in the male ejaculatory duct and ejaculatory bulb. These four organs are derived from closely related cell lineages in the genital imaginal disc. Since the expression of Gld is not required for the development of these reproductive structures, this spatial pattern of expression is most likely a fortuitous consequence of a shared regulatory factor in this cell lineage. At the adult stage a high level of the Gld mRNA is only observed in the male ejaculatory duct.     

Noncoordinate expression of Drosophila glue genes: Sgs-4 is expressed at many stages and in two different tissues.

The glue genes of Drosophila melanogaster comprise a family of genes expressed at high levels in the salivary glands of late third instar larvae in response to the insect hormone ecdysone. We present evidence that, in contrast to the other glue genes, Sgs-4 is turned on throughout Drosophila development and is not expressed exclusively in the larval salivary glands. Larvae transformed with an Sgs-4/Adh (alcohol dehydrogenase) hybrid gene exhibit Sgs-4-directed Adh expression in the larval proventriculus as well as in the salivary glands as early as the first instar. Sgs-4-specific RNA can be detected at very low levels during all stages of development. During late third instar, levels of Sgs-4 RNA in the salivary glands increase several-thousand-fold, thereby accounting for the large amounts of Sgs-4 protein present in the glue produced by the salivary glands. This pattern of expression is unique to the Sgs-4 gene. While expression of several of the other glue genes can be detected in embryos and early larvae, they appear to be expressed neither throughout development nor in the larval proventriculus. Appearance of the glue gene RNAs in mid third instar salivary glands is noncoordinate, even for the chromosomally clustered genes Sgs-3, Sgs-7, and Sgs-8.     

The east gene of Drosophila melanogaster is expressed in the developing embryonic nervous system and is required for normal olfactory and gustatory responses of the adult.

Drosophila melanogaster larvae and adults respond to a wide range of chemosensory stimuli. We describe the genetics and developmental expression of the east gene, mutations which result in adult-specific chemosensory defects. The original isolate of east is semidominant for the behavioral phenotype. Several mutations have been generated, some of which are recessive lethals and others that are viable alleles that show a recessive, adult-specific, chemosensory defect. No larval chemosensory defects were observed. The east gene is expressed in the neurogenic region at the time of neuroblast segregation and in cells in the peripheral and central nervous system. Our results suggest that east+ expression in the nervous system is required for a normal adult chemosensory response and both increases and decreases in levels of the gene product result in a mutant phenotype.     

Hormonal control of gene expression: interactions between two trans-acting regulators in Drosophila

The steroid hormone 20-hydroxyecdysone (20HE) and the Broad-Complex locus (BRC) are involved in regulating developmental changes in gene expression around the time of metamorphosis in Drosophila. We have investigated the regulatory interactions between 20HE, BRC, and a set of genes expressed in the fat body of third-instar Drosophila larvae. RNA levels for two hormone-inducible genes, Larval Serum Protein-2 and P1, accumulate to normal levels in BRC-mutant larvae. In contrast, RNA levels for the P6 gene were affected by mutations at BRC. On the basis of the results of experiments in which hormone concentrations were varied in BRC-mutant or wild-type larvae, we conclude that 20HE can both increase and decrease P6 RNA levels in the absence of BRC product(s). BRC appears to be a trans-acting modulator of the response of P6 to the hormone. We propose that BRC attenuates the repressive effect of the hormone, expanding the range of hormone concentrations that induce the gene, thus allowing P6 RNA to reach high levels during the third larval instar. The results are discussed in relation to other genes that are regulated by the same two trans-acting factors. A model is presented that refines the model of Ashburner et al. (1974, Cold Spring Harbor Symp. Quant. Biol. 38: 655-662) for the hormonal regulation of gene activity.