Properties of photoreceptor-specific phospholipase C encoded by the norpA gene of Drosophila melanogaster.

Mutations in the norpA gene drastically affect the phototransduction process in Drosophila. To study the biochemical characteristics of the norpA protein and its cellular and subcellular distributions, we have generated antisera against the major gene product of norpA. The antisera recognize an eye-specific protein of 130-kDa relative molecular mass that is present in wild-type head extracts but not in those of strong norpA mutants. The protein is associated with membranes and can be extracted with high salt. Immunohistochemical analysis at the light and electron microscopic levels indicates that the protein is expressed in all adult photoreceptor cells and specifically localized within the rhabdomeres, preferentially adjacent to, but not within, the rhabdomeric membranes. The results of the present study strongly support the previous suggestion that the norpA gene encodes the major phosphoinositol-specific phospholipase C in the photoreceptors. Moreover, insofar as the rhabdomeres are specialized structures for photoreception and phototransduction, specific localization of the norpA protein within these structures, in close association with the membranes, is consistent with the proposal that it has an important role in phototransduction.

A Drosophila phospholipase C gene that is expressed in the central nervous system.

A Drosophila phospholipase C (PLC) gene, designated as plc-21, was isolated by screening a genomic DNA library using a cDNA for a previously isolated Drosophila PLC gene, norpA, as probe under reduced stringency hybridization conditions. The gene maps to 21C on the left arm of the second chromosome. Two proteins of 1305 and 1312 amino acids, respectively, were deduced from two classes of cDNA which were isolated. The two putative plc-21 proteins are similar in sequence and overall structure to the beta-class of PLCs found in mammals and differ from each other only by 7 amino acid residues that are present near the C terminus of one of the proteins but not the other. Hybridization of plc-21 cDNA probes to blots of poly(A)+ RNA revealed that the gene encodes a 7.0-kilobase transcript that could be detected in the head but not in the body of adult flies and a 5.6-kilobase transcript that could be detected throughout development and in both heads and bodies of adults. In situ hybridization of cDNA sequences to tissue sections showed that the gene is expressed in the neuronal cell bodies of the optic lobe, central brain, and thoracic ganglia of adults and the brain of larvae. This tissue distribution of plc-21 transcripts is identical to the distribution of transcripts from a Drosophila Go alpha-subunit gene that we reported previously.

Molecular characterization of Drosophila gene encoding G0 alpha subunit homolog.

A Drosophila melanogaster gene (dgo) encoding a G protein alpha subunit has been isolated by screening genomic and adult head cDNA libraries using bovine transducin alpha subunit cDNA as probe. The gene, which maps to 47A on the second chromosome, encodes two proteins which are both 354 amino acids long but differ in seven amino acids in the amino-terminal region. The deduced amino acid sequences of the two proteins are 81% identical to that of a rat Go alpha subunit. Analysis of genomic clones revealed that there are eight coding exons and that the putative transcripts for the two proteins differ in the 5'-noncoding regions and the first coding exons but share the remaining six coding exons. The arrangement of two different 5'-noncoding regions on the gene suggests that two different promoters regulate the expression of the transcripts encoding the two proteins. RNA blot analysis detected three transcripts: a 3.9-kilobase (kb) transcript found at all stages of development; a 5.4-kb transcript present predominantly in adult heads; and a 3.4-kb transcript present only in adult bodies. In situ hybridizations of a cDNA probe to adult tissue sections showed that the gene is expressed abundantly in neuronal cell bodies in the brain, optic lobe, and thoracic ganglia.

Expression of two developmentally regulated brain-specific proteins is correlated with late outgrowth of the pyramidal tract.

The regulation of axon outgrowth is not well understood. In previous studies, however, axon elongation has been well correlated with expression of a small number of growth-associated proteins (GAPs). To identify other proteins whose expression could be correlated with axon outgrowth during development of CNS pathways, monoclonal antibodies were raised against growth cone particles isolated from neonatal hamster brains. Two of these antibodies recognized a brain-specific 33 kDa protein associated with intracellular membranes of axons and growth cones. Immunoblotting demonstrated a sharp developmental decline in levels of the protein in hamster brain during the first postnatal week and a more gradual decline thereafter. Immunocytochemical studies with the antibodies revealed ubiquitous staining of the neuropil during the first several days, which by the end of the first week became restricted to a few later-maturing pathways. Staining was most intense in the pyramidal tract and was well correlated with axon outgrowth, which continues until 14 d in this pathway. These results suggest that the 33 kDa protein may, like previously identified GAPs, play a role in axon elongation. Late outgrowth of the hamster pyramidal tract is also correlated with expression of another developmentally regulated protein, the high-molecular-weight neurofilament subunit (NF-H). Immunostaining with a monoclonal antibody that recognized phosphorylated NF-H demonstrated that this subunit does not begin to appear in the late-maturing pyramidal tract fibers until several weeks after birth, in striking contrast to intense immunoreactivity of other spinal cord pathways from postnatal day 1. This finding suggests that specific pathways may have a highly idiosyncratic time course for expression of neurofilament subunits.

Isolation of a putative phospholipase C gene of Drosophila, norpA, and its role in phototransduction.

Severe norpA mutations in Drosophila eliminate the photoreceptor potential and render the fly completely blind. Recent biochemical analyses have shown that norpA mutants lack phospholipase C (PLC) activity in the eye. A combination of chromosomal walking and transposon-mediated mutagenesis was used to clone the norpA gene. This gene encodes a 7.5 kb RNA that is expressed in the adult head. In situ hybridizations of norpA cDNA to adult tissue sections show that this gene is expressed abundantly in the retina. The putative norpA protein is composed of 1095 amino acid residues and has extensive sequence similarity to a PLC amino acid sequence from bovine brain. We suggest that the norpA gene encodes a PLC expressed in the eye of Drosophila and that PLC is an essential component of the Drosophila phototransduction pathway.