Inactivation of olfactory sensilla of a single morphological type differentially affects the response of Drosophila to odors

The olfactory organs on the head of Drosophila, antennae and maxillary palps, contain several hundred olfactory hairs, each with one or more olfactory receptor neurons. Olfactory hairs belong to one of three main morphological types, trichoid, basiconic, and coeloconic sensilla, and show characteristic spatial distribution patterns on the surface of the antenna and maxillary palps. Here we show that targeting expression of the cell-death gene reaper to basiconic sensilla (BS) causes the specific inactivation of most olfactory sensilla of this type with no detectable effect on other types of olfactory sensilla or the structure of the antennal lobe. Our data suggest that BS are required for a normal sensitivity to many odorants with a variety of chemical structures, through a wide range of concentrations. Interestingly, however, in contrast to other odorants tested, the behavioral response of ablated flies to intermediate concentrations of propionic and butyric acids is normal, suggesting the involvement of sensilla unaffected by ectopic reaper expression, probably coeloconic sensilla that respond strongly to these two organic acids. As inactivation of BS causes an underestimation of the concentration of both acids detectable at both the highest and lowest odorants concentrations, our results suggest that concentration coding for these two odorants relies on the integration of signals from different subsets of sensilla, most likely of different morphological types.

Novel genes expressed in subsets of chemosensory sensilla on the front legs of male Drosophila melanogaster

Detection of courtship-activating female pheromones by contact chemoreceptors on the front legs of male Drosophila melanogaster is thought to play an important role in triggering courtship behavior. However, the chemosensory organs, cells, and molecules responsible are not known. We have isolated two genes, CheA29a and CheB42a, expressed in nonneuronal auxiliary cells within two nested subsets of chemosensory sensilla on the front legs of sexually mature, adult males. The proteins encoded by the CheA29a and CheB42a genes have no sequence similarity to each other or any other known protein, but they belong to two novel families of proteins encoded by the D. melanogaster genome. Members of the two families are predicted to have a single transmembrane domain at their amino terminus, probably to serve as a signal peptide, suggesting that they are soluble and secreted. Finally, in addition to CheA29a and CheB42a, other genes within each family are expressed preferentially in appendages where chemosensory organs are concentrated, in several cases in a male-specific manner. Our data suggest that CheA29a and CheB42a and other members of these two protein families are involved in male-specific chemical senses, perhaps pheromone response.

Gustatory organs of Drosophila melanogaster: fine structure and expression of the putative odorant-binding protein PBPRP2

In Drosophila, as in most insects, gustation is mediated by sensory hairs located on the external and internal parts of the proboscis and on the legs and wings. We describe in detail the organization and ultrastructure of the gustatory sensilla on the labellum and legs and the distribution of PBPRP2, a putative odorant-binding protein, in the gustatory organs of Drosophila. The labellum carries two kinds of sensilla: taste bristles and taste pegs. The former have the typical morphology of gustatory sensilla and can be further subdivided into three morphological subtypes, each with a stereotyped distribution and innervation. Taste pegs have a unique morphology and are innervated by two receptor cells: one mechanoreceptor and the other a putative chemoreceptor cell. PBPRP2 is abundantly expressed in all adult gustatory organs on labellum, legs, and wings and in the internal taste organs on the proboscis. In contrast to olfactory organs, where PBPRP2 is expressed in the epidermis, this protein is absent from the epidermis of labial palps and legs. In the taste bristles of the labellum and legs, PBPRP2 is localized in the crescent-shaped lumen of the sensilla, and not in the lumen where the dendrites of the gustatory neurons are found, making a function in stimulus transport unlikely in these sensilla. In contrast, PBPRP2 in peg sensilla is expressed in the inner sensillum-lymph cavity and is in contact with the dendrites. Thus, PBPRP2 could be involved as a carrier for hydrophobic ligands, e.g., bitter tastants, in these sensilla.

Expression patterns of two putative odorant-binding proteins in the olfactory organs of Drosophila melanogaster have different implications for their functions

The aqueous medium bathing the dendrites of olfactory neurons contains high concentrations of odorant-binding proteins (OBPs) whose role is still unclear. OBPs may facilitate interactions between odorants and their membrane-bound receptors, perhaps by increasing the water solubility of hydrophobic molecules. Alternatively, OBPs may be involved in the inactivation of odorants and other volatile molecules, preventing desensitization and/or protecting olfactory neurons from toxic chemicals. We report here novel features of the localization of two putative OBPs, PBPRP2 and PBPRP5, that have important and different implications for their role in olfaction. Unlike several other putative OBPs of Drosophila melanogaster that are only found in adult olfactory organs, PBPRP5 is also expressed in the larval olfactory organs, suggesting that it plays a common role in olfaction at both stages. In the adult, PBPRP5 expression is restricted to the sensillum lymph that bathes the olfactory dendrites of a subset of olfactory hairs, the basiconic sensilla. Since individual basiconic sensilla differ in olfactory specificity, PBPRP5 may be able to bind to and mediate olfactory responses to a wide range of odorants. In contrast, PBPRP2 is present in the space immediately below the antennal cuticle and in the outer cavity of approximately 30% of the double-walled coeloconic sensilla on the antennal surface. In neither case is PBPRP2 in contact with the dendritic membranes of olfactory neurons, making a carrier function unlikely for this protein. Instead, PBPRP2 may act as a sink, binding to odorants and other volatile chemicals and limiting their interactions with olfactory neurons.

Preferential expression of biotransformation enzymes in the olfactory organs of Drosophila melanogaster, the antennae

Biotransformation enzymes have been found in the olfactory epithelium of vertebrates. We now show that in Drosophila melanogaster, a UDP-glycosyltransferase (UGT), as well as a short chain dehydrogenase/reductase and a cytochrome P450 are expressed specifically or preferentially in the olfactory organs, the antennae. The evolutionarily conserved expression of biotransformation enzymes in olfactory organs suggests that they play an important role in olfaction. In addition, we describe five Drosophila UGTs belonging to two families. All five UGTs contain a putative transmembrane domain at their C terminus as is the case for vertebrate UGTs where it is required for enzymatic activity. The primary sequence of the C terminus, including part of the transmembrane domain, differs between the two families but is highly conserved not only within each Drosophila family, but also between the members of one of the Drosophila families and vertebrate UGTs. The partial overlap of the conserved primary sequence with the transmembrane domain suggests that this part of the protein is involved in specific interactions occurring at the membrane surface. The presence of different C termini in the two Drosophila families suggests that they interact with different targets, one of which is conserved between Drosophila and vertebrates.

Ag, a novel protein secreted from Aplysia glia

We have isolated a cDNA (ag for Aplysia glial) corresponding to an mRNA specific to the nervous system of Aplysia californica. In this study, we characterized the ag cDNA sequence and the distribution of ag mRNA and protein in the Aplysia nervous system. The ag cDNA contains an open reading frame that encodes a novel 29 kD protein. In situ hybridizations demonstrate that ag mRNA is conspicuously absent from the cell bodies of the large neurons constituting the external layer of the ganglia. Instead, it is largely confined to a subset of small, apparently non-neuronal cells surrounding the neurons at the border of the neuropil, is sparsely scattered within the neuropil, and is widespread within the connective nerves, a pattern consistent with glial localization. Polyclonal anti-ag antiserum recognizes a protein between 27 and 29 kD that is more broadly distributed, especially within the neuropil. The distributions of ag mRNA and protein, together with the presence of a putative signal peptide, suggest that ag protein is secreted. Two findings support this hypothesis: first, ag protein is detectable by western blot in Aplysia hemolymph. Second, full length ag protein expressed in COS cells is secreted, but ag lacking the putative signal peptide is not. Secretion from glia raises the possibility that this abundant protein may affect neighboring neurons.

Members of a family of Drosophila putative odorant-binding proteins are expressed in different subsets of olfactory hairs

A polymerase chain reaction-based method was used to generate a Drosophila melanogaster antennal cDNA library from which head cDNAs were subtracted. We identified five cDNAs that code for antennal proteins containing six cysteines in a conserved pattern shared with known moth antennal proteins, including pheromone-binding proteins. Another cDNA codes for a protein related to vertebrate brain proteins that bind hydrophobic ligands. In all, we describe seven antennal proteins which contain potential signal peptides, suggesting that, like pheromone-binding proteins, they may be secreted in the lumen of olfactory hairs. The expression patterns of these putative odorant-binding proteins define at least four different subsets of olfactory hairs and suggest that the Drosophila olfactory apparatus is functionally segregated.

In vitro reconstitution of snRNPs: a reconstituted U4/U6 snRNP participates in splicing complex formation

We have reconstituted in vitro the four snRNPs known to be involved in pre-mRNA splicing: U1, U2, U5, and U4/6. Reconstitution involves adding either authentic or in vitro-synthesized snRNAs to extracts enriched in snRNP structural polypeptides. The reconstituted snRNPs have the same buoyant density and are immunoprecipitated by the same antibodies as authentic snRNPs. Thus, the polypeptide composition of reconstituted snRNPs is similar, if not identical, to that of authentic snRNPs. We show further that a reconstituted U4/U6 particle is fully functional in forming splicing complexes with pre-mRNA. As is the case for the authentic U4/U6 snRNP, the reconstituted U4 snRNP, but not the U6 snRNA, dissociates from the complex prior to formation of the mature spliceosome. The ability to reconstitute snRNPs and assay their activity in spliceosome formation should provide a powerful approach to study these particles.

Electrophoresis of ribonucleoproteins reveals an ordered assembly pathway of yeast splicing complexes

Three splicing complexes formed with a yeast pre-messenger RNA during in vitro splicing can be resolved by non-denaturing gel electrophoresis after incubation in the presence of non-specific competitor RNA. The time course of the appearance of these complexes and their composition suggest that they represent an ordered pathway of splicing complex assembly.

Specific small nuclear RNAs are associated with yeast spliceosomes

Two different methods have been devised for the analysis and purification of spliceosomes formed in a yeast in vitro splicing system. The first method relies on the electrophoretic separation of ribonucleoprotein particles in composite acrylamide-agarose gels. A large fraction of added substrate is located in spliceosomes, the formation of which can be shown to be dependent on the presence of both a yeast 5' splice junction and a TACTAAC box on the RNA substrate. The second method relies on oligo(dT)-cellulose chromatography of spliceosomes formed with a polyadenylated substrate. Purification of spliceosomes by either method indicates that at least three small nuclear RNAs, approximately 160, 185, and 215 nucleotides in length, are specifically associated with yeast spliceosomes.

Alternative branch points are selected during splicing of a yeast pre-mRNA in mammalian and yeast extracts

Pre-mRNA splicing in yeast and higher eukaryotes proceeds by similar pathways, in which a probable splicing intermediate and the excised intron are in a lariat configuration. To compare the pre-mRNA splicing mechanisms in yeast and higher eukaryotes, we have analyzed the RNA products resulting from in vitro processing of a yeast intron-containing pre-mRNA in HeLa cell and yeast extracts. In yeast, the RNA branch (2'-5' phosphodiester bond) of the RNA lariat forms at the third adenosine of the TACTAAC box in vivo and in vitro. In contrast, in the HeLa cell extract, the yeast pre-mRNA is accurately spliced, but the RNA lariats contain RNA branches located significantly closer to the 3' splice site than the TACTAAC box. In yeast, mutant pre-mRNAs that lack the TACTAAC box are not spliced in vivo or in vitro. However, these same mutant pre-mRNAs are accurately spliced in the HeLa cell extract. Therefore, although pre-mRNA splicing in yeast and higher eukaryotes proceeds by the same basic pathway, there are substantial differences in the specificity of the biochemical components that mediate the formation of the RNA processing products.

mRNA splicing efficiency in yeast and the contribution of nonconserved sequences

A simple kinetic model for mRNA splicing predicts the way in which in vivo steady state precursor RNA levels (P) and messenger RNA levels (M) vary as a function of the rate constant of the splicing reaction (ksp). The model points to M/P as the best measure of ksp. The analysis of a set of intron mutations in a yeast gene supports the general features of the model and shows that the splicing efficiency of transcripts containing the wild-type intron is well in excess of what is necessary to generate normal mRNA levels. The data also suggest that regions of the intron, in addition to the well-conserved consensus sequences, contribute to efficient splicing.

In vivo characterization of yeast mRNA processing intermediates

Yeast mRNA introns contain a conserved sequence, TACTAAC, required for splicing. We previously identified a putative splicing intermediate characterized by a stop to reverse transcriptase at the TACTAAC box of the wild-type rp51A (ribosomal protein 51A gene) intron. We now show that this stop is due to a branch and occurs at the identical nucleotide in the actin intron TACTAAC box. We show further that the putative intermediate contains a complete intron and the 3' exon, but is missing the 5' exon. This RNA is largely in the form of a lariat. The lariat and the other putative splicing intermediates detected (two forms, of different molecular weights, of the excised intron and the free 5' exon) are compatible with the view that the cut at the 5' junction and lariat formation are early steps in yeast mRNA splicing and that substantial similarities exist between yeast and mammalian mRNA splicing.

Evidence for the biochemical role of an internal sequence in yeast nuclear mRNA introns: implications for U1 RNA and metazoan mRNA splicing

Sequence comparison of the introns of two yeast genes (rp51A and rp51B) coding for the same ribosomal protein shows homology only in the last 50 bases of the intron. This region of the intron contains an internal conserved sequence (ICS) present near the 3' end of all sequenced yeast nuclear mRNA introns. Removal of a 29 bp sequence containing the ICS prevents splicing of an intron-containing hybrid gene. In cells containing the wild-type gene, we have detected RNA molecules that we suggest are normal splicing intermediates, generated by an endonucleolytic cut in the primary transcript at the ICS. The homology of the ICS with a sequence near the 5' end of U1 snRNA suggests a model in which an interaction in cis between the ICS and the 5' splice junction in yeast is the counterpart of the interaction in trans between U1 and 5' splice junctions in higher eucaryotes.