By screening Drosophila mutants that are potentially defective in synaptic transmission between photoreceptors and their target laminar neurons, L1/L2, (lack of electroretinogram on/off transients), we identified ort as a candidate gene encoding a histamine receptor subunit on L1/L2. We provide evidence that the ort gene corresponds to CG7411 (referred to as hclA), identified in the Drosophila genome data base, by P-element-mediated germ line rescue of the ort phenotype using cloned hclA cDNA and by showing that several ort mutants exhibit alterations in hclA regulatory or coding sequences and/or allele-dependent reductions in hclA transcript levels. Other workers have shown that hclA, when expressed in Xenopus oocytes, forms histamine-sensitive chloride channels. However, the connection between these chloride channels and photoreceptor synaptic transmission was not established. We show unequivocally that hclA-encoded channels are the channels required in photoreceptor synaptic transmission by 1) establishing the identity between hclA and ort and 2) showing that ort mutants are defective in photoreceptor synaptic transmission. Moreover, the present work shows that this function of the HCLA (ORT) protein is its native function in vivo.
Histamine (HA) is the photoreceptor neurotransmitter in arthropods, directly gating chloride channels on large monopolar cells (LMCs), postsynaptic to photoreceptors in the lamina. Two histamine-gated channel genes that could contribute to this channel in Drosophila are hclA (also known as ort) and hclB (also known as hisCl1), both encoding novel members of the Cys-loop receptor superfamily. Drosophila S2 cells transfected with these genes expressed both homomeric and heteromeric histamine-gated chloride channels. The electrophysiological properties of these channels were compared with those from isolated Drosophila LMCs. HCLA homomers had nearly identical HA sensitivity to the native receptors (EC 50 ϭ 25 M). Single-channel analysis revealed further close similarity in terms of single-channel kinetics and subconductance states (ϳ25, 40, and 60 pS, the latter strongly voltage dependent). In contrast, HCLB homomers and heteromeric receptors were more sensitive to HA (EC 50 ϭ 14 and 1.2 M, respectively), with much smaller single-channel conductances (ϳ4 pS). Null mutations of hclA (ort US6096 ) abolished the synaptic transients in the electroretinograms (ERGs). Surprisingly, the ERG "on" transients in hclB mutants transients were approximately twofold enhanced, whereas intracellular recordings from their LMCs revealed altered responses with slower kinetics. However, HCLB expression within the lamina, assessed by both a GFP (green fluorescent protein) reporter gene strategy and mRNA tagging, was exclusively localized to the glia cells, whereas HCLA expression was confirmed in the LMCs. Our results suggest that the native receptor at the LMC synapse is an HCLA homomer, whereas HCLB signaling via the lamina glia plays a previously unrecognized role in shaping the LMC postsynaptic response.
Abstract:We have identified and analyzed a Drosophila melanogaster gene that encodes a chloride channel subunit (DrosGluCl-␣) previously shown to function as a glutamategated chloride channel in an in vitro expression system. Sequence analysis of several cDNAs corresponding to the gene revealed sequence diversity in their open reading frames at seven specific sites. Site-specific A-to-G variations between cDNA and genomic sequences, consistent with RNA editing, were detected at five nucleotide positions. In addition, sequence variations among cDNA clones consistent with alternative splicing of mRNA were found at two different sites. In the 5Ј region, two small adjacent exons, containing similar but distinct modular sequences, are alternatively incorporated into the mature mRNA. In the 3Ј region, alternative splicing generates a variant encoding a protein with four additional amino acids just upstream of the fourth transmembrane domain. Combinations of RNA editing and alternative splicing can lead to extensive diversification of transcripts. These results give the first example of RNA editing in neurotransmitter-gated chloride channel genes or of alternative splicing in a glutamate-gated chloride channel gene of Drosophila.
The recent identification and characterization of two genes, encoding histamine-gated chloride channel subunits from Drosophila melanogaster, has confirmed that histamine is a major neurotransmitter in the fruitfly. One of the cloned genes, hclA (synonyms: HisCl-alpha1; HisCl2), corresponds to ort (ora transientless), mutationsin which affect synaptic transmission in the Drosophila visual system. We identified a mutational change (a null mutation) in the genomic and RNA copies of hclA derived from mutants carrying the ort(1) allele. This correlates with new phenotypes observed in the mutant strain. We found hypersensitivity to the avermectin neurotoxins in both the ort(1) adult flies and third instar larvae compared to Oregon R wild-type animals. On the other hand, the mutation makes both male and female adult flies more resistant to treatment with diethyl ether, and the animals show substantially prolonged recovery from paralysis after diethylether anaesthesia, as well as from paralysis after mechanical shock, as revealed by the bang sensitivity test. Altogether, our data give direct evidence that in vivo a HCLA subunit-containing receptor has a distinct role in the neurotoxic action of the avermectins. They also provide new evidence for a function in the response to diethylether anaesthesia and, moreover, that HCLA function is not limited to the visual system.
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