Genetic analysis of the Drosophila Gs(alpha) gene.

One of the best understood signal transduction pathways activated by receptors containing seven transmembrane domains involves activation of heterotrimeric G-protein complexes containing Gs(alpha), the subsequent stimulation of adenylyl cyclase, production of cAMP, activation of protein kinase A (PKA), and the phosphorylation of substrates that control a wide variety of cellular responses. Here, we report the identification of "loss-of-function" mutations in the Drosophila Gs(alpha) gene (dgs). Seven mutants have been identified that are either complemented by transgenes representing the wild-type dgs gene or contain nucleotide sequence changes resulting in the production of altered Gs(alpha) protein. Examination of mutant alleles representing loss-of-Gs(alpha) function indicates that the phenotypes generated do not mimic those created by mutational elimination of PKA. These results are consistent with the conclusion reached in previous studies that activation of PKA, at least in these developmental contexts, does not depend on receptor-mediated increases in intracellular cAMP, in contrast to the predictions of models developed primarily on the basis of studies in cultured cells.

Ectopic G-protein expression in dopamine and serotonin neurons blocks cocaine sensitization in Drosophila melanogaster.

Sensitization to repeated doses of psychostimulants is thought to be an important component underlying the addictive process in humans [1] [2] [3] [4]. In all vertebrate animal models, including humans [5], and even in fruit flies, sensitization is observed after repeated exposure to volatilized crack cocaine [6]. In vertebrates, sensitization is thought to be initiated by processes occurring in brain regions that contain dopamine cell bodies [2] [7]. Here, we show that modulated cell signaling in the Drosophila dopamine and serotonin neurons plays an essential role in cocaine sensitization. Targeted expression of either a stimulatory (Galpha(s)) or inhibitory (Galpha(i)) Galpha subunit, or tetanus toxin light chain (TNT) in dopamine and serotonin neurons of living flies blocked behavioral sensitization to repeated cocaine exposures. These flies showed alterations in their initial cocaine responsiveness that correlated with compensatory adaptations of postsynaptic receptor sensitivity. Finally, repeated drug stimulation of a nerve cord preparation that is postsynaptic to the brain amine cells failed to induce sensitization, further showing the importance of presynaptic modulation in sensitization.

Associative learning disrupted by impaired Gs signaling in Drosophila mushroom bodies.

Disruptions in mushroom body (MB) or central complex (CC) brain structures impair Drosophila associative olfactory learning. Perturbations in adenosine 3',5' monophosphate signaling also disrupt learning. To integrate these observations, expression of a constitutively activated stimulatory heterotrimeric guanosine triphosphate-binding protein alpha subunit (Galphas*) was targeted to these brain structures. The ability to associate odors with electroshock was abolished when Galphas* was targeted to MB, but not CC, structures, whereas sensorimotor responses to these stimuli remained normal. Expression of Galphas* did not affect gross MB morphology, and wild-type Galphas expression did not affect learning. Thus, olfactory learning depends on regulated Gs signaling in Drosophila MBs.

Activation of protein kinase A-independent pathways by Gs alpha in Drosophila.

One of the best-described transmembrane signal transduction mechanisms is based on receptor activation of the alpha subunit of the heterotrimeric G protein Gs, leading to stimulation of adenylyl cyclase and the production of cAMP. Intracellular cAMP is then thought to mediate its effects largely, if not entirely, by activation of protein kinase A and the subsequent phosphorylation of substrates which in turn control diverse cellular phenomena. In this report we demonstrate, by two different methods, that reduction or elimination of protein kinase A activity had no effect on phenotypes generated by activation of Gs alpha pathways in Drosophila wing epithelial cells. These genetic studies show that the Gs alpha pathway mediates its primary effects by a novel pathway in differentiating, wing epithelial cells. This novel pathway may in part be responsible for some of the complex, cell-specific responses observed following activation of this pathway in different cell types.

Inducible ternary control of transgene expression and cell ablation in Drosophila.

In Drosophila, P-GAL4 enhancer trap lines can target expression of a cloned gene, under control of a UASGAL element, to any cells of interest. However, additional expression of GAL4 in other cells can produce unwanted lethality or side-effects, particularly when it drives expression of a toxic gene product. To target the toxic gene product ricin A chain specifically to adult neurons, we have superimposed a second layer of regulation on the GAL4 control. We have constructed flies in which an effector gene is separated from UASGAL by a polyadenylation site flanked by two FRT sites in the same orientation. A recombination event between the two FRT sites, catalysed by yeast FLP recombinase, brings the effector gene under control of UASGAL. Consequently, expression of the effector gene is turned on in that cell and its descendants, if they also express GAL4. Recombinase is supplied by heat shock induction of a FLP transgene, allowing both timing and frequency of recombination events to be regulated. Using a lacZ effector (reporter) to test the system, we have generated labelled clones in the embryonic mesoderm and shown that most recombination events occur soon after FLP recombinase is supplied. By substituting the ricin A chain gene for lacZ, we have performed mosaic cell ablations in one GAL4 line that marks the adult giant descending neurons, and in a second which marks mushroom body neurons. In a number of cases we observed loss of one or both the adult giant descending neurons, or of subsets of mushroom body neurons. In association with the mushroom body ablations, we also observed misrouting of surviving axons.

The Drosophila segment polarity gene patched is involved in a position-signalling mechanism in imaginal discs.

We demonstrate the role of the segment polarity gene patched (ptc) in patterning in the cuticle of the adult fly. Genetic mosaics of a lethal allele of patched show that the contribution of patched varies in a position-specific manner, defining three regions in the wing where ptc clones, respectively, behave as wild-type cells, affect vein formation, or are rarely recovered. Analysis of twin clones demonstrates that the reduced clone frequency results from a proliferation failure or cell loss. In the region where clones upset venation, they autonomously fail to form veins and also non-autonomously induce ectopic veins in adjacent wild-type cells. In heteroallelic combinations with lethal alleles, two viable alleles produce distinct phenotypes: (1) loss of structures and mirror-image duplications in the region where patched clones fail to proliferate; (2) vein abnormalities in the anterior compartment. We propose that these differences reflect independently mutable functions within the gene. We show the pattern of patched transcription in the developing imaginal wing disc in relation to the expression of certain other reporter genes using a novel double-labelling method combining non-radioactive detection of in situ hybridization with beta-galactosidase detection. The patched transcript is present throughout the anterior compartment, with a stripe of maximal intensity along the A/P compartment border extending into the posterior compartment. We propose that the patched product is a component of a cell-to-cell position-signalling mechanism, a proposal consistent with the predicted structure of the patched protein.

Radiosensitization by misonidazole, pimonidazole and azomycin and intracellular uptake in human tumour cell lines.

The radiosensitization of two human tumour in vitro cell lines, HT-1080 and LoVo, has been compared with that of the Chinese hamster cell line V79-379A. Although the two human tumour cell lines were more radiosensitive than the V79 cell line sensitizer, enhancement ratios for misonidazole, pimonidazole and azomycin were similar (relative to extracellular concentration) for all three cell lines. Average intracellular concentrations of radiosensitizer were measured by high-performance liquid chromatography. In all three cell lines the uptake of misonidazole and azomycin was extremely rapid whereas that of pimonidazole was initially much slower before reaching a plateau. The ratios of intracellular concentration of radiosensitizer to extracellular concentration (Ci to Ce) for misonidazole were 0.8 (HT-1080) and 0.7 (LoVo and V79); for azomycin 0.9 (HT-1080 and LoVo) and 0.8 (V79). In contrast Ci/Ce for pimonidazole varied with cell line, the values being 1.8 (LoVo), 2.6 (HT-1080) and 3.3 (V79). Intracellular amounts of non-protein sulphydryl (NPSH) varied between cell lines by about a factor of three. However, when the average cell volume was taken into consideration the concentrations of NPSH were very similar, being 4.2 (HT-1080), 5.6 (LoVo) and 5.7 (V79) mmol dm-3. NPSH levels expressed as nmol per mg protein were also similar.

A comparison of colorimetric and clonogenic assays for hypoxic-specific toxins with hamster and human cells.

The hypoxic cytotoxicities of misonidazole and pimonidazole (Ro 03-8799) towards the human tumor cell lines HT-1080 and LoVo have been compared with those seen with Chinese hamster V79-379A cells. Survival was assayed using two colorimetric assays, either a tetrazolium salt (MTT) or methylene blue, and by conventional colony scoring. The drugs were more cytotoxic towards HT-1080 and LoVo cells than V79 cells. The times taken for 10 mmol dm-3 misonidazole to reduce survival to 0.1 surviving fraction (SF) using colony formation as the end point were 2.6 hr for HT-1080, 2.4 hr for LoVo, and 3.5 hr for V79; using the MTT assay these times were 3.5 hr, 2.1 hr, and 2.9 hr, respectively. The times for 2 mmol dm-3 pimonidazole to reduce survival to 0.1 SF using colony formation as the end point were 2.0 hr for HT-1080, 1.7 hr for LoVo, and 3.7 hr for V79; using the MTT assay these times were 2.5 hr, 1.4 hr, and 2.5 hr, respectively.

Imaginal discs can be recovered from cultured embryos mutant for the segment-polarity genes engrailed, naked and patched but not from wingless.

Drosophila embryos homozygous for strong mutations in each of the segment-polarity genes wingless (wg), engrailed (en), naked (nkd) and patched (ptc) form a larval cuticle in which there is a deletion in every segment. The mutant embryos normally fail to hatch but by in vivo culture we were able to show which could produce adult structures. Cultured wg⁻ embryos did not produce any adult structures. Cultured en⁻ embryos produced eye-antennal derivatives and rarely produced partial thoracic structures. nkd⁻ and ptc⁻ embryos produced eye-antennal and thoracic derivatives. The nkd⁻ and ptc⁻ thoracic imaginal discs developed with an abnormal morphology and abnormal pattern of en-expression. Our findings are consistent with the idea that the thoracic imaginal discs derive from two adjacent groups of cells that express wg and en respectively in the embryo.

Rapid-mixing studies of radiosensitivity with thiol-depleted mammalian cells.

A moderate reduction in the non-protein thiol content of V79 379A Chinese hamster cells, obtained by pretreatment with buthionine sulphoximine (BSO), diethyl maleate (DEM) or N-ethyl maleimide (NEM), increase both the absolute radiosensitivity of the cells in hypoxia and the radiosensitizing effect of adding oxygen 7 ms after irradiation. Combined pretreatment of cells with BSO and NEM removes most of the non-protein thiol and some of the protein thiol; such treatment further increases the radiosensitivity of hypoxic cells but there is no further effect of adding oxygen 7 ms after irradiation. Addition of 2-mercaptoethanol to cells 7 ms after irradiation gives protection factors that increase with increasing severity of thiol depletion. Substantial radioprotection can still be observed when 2-mercaptoethanol is added 70 ms after irradiation of cells pretreated with BSO and NEM; there is no effect of adding 2-mercaptoethanol to such cells 50s after irradiation. These observations support the repair-fixation model of radiation damage and suggest that, in addition to the established role of non-protein thiol in chemical repair of radiation damage, other endogenous reducing agents such as protein thiol may be important in determining cellular radiosensitivity. A relatively long-lived thiol-modifiable component of radiation damage has been observed within hypoxic thiol-depleted cells.