Reinhard F. Stocker scite author profile

This review surveys the organization of the olfactory and gustatory systems in the imago and in the larva of Drosophila melanogaster, both at the sensory and the central level. Olfactory epithelia of the adult are located primarily on the third antennal segment (funiculus) and on the maxillary palps. About 200 basiconic (BS), 150 trichoid (TS) and 60 coeloconic sensilla (CS) cover the surface of the funiculus, and an additional 60 BS are located on the maxillary palps. Males possess about 30% more TS but 20% fewer BS than females. All these sensilla are multineuronal; they may be purely olfactory or multimodal with an olfactory component. Antennal and maxillary afferents converge onto approximately 35 glomeruli within the antennal lobe. These projections obey precise rules: individual fibers are glomerulus-specific, and different types of sensilla are associated with particular subsets of glomeruli. Possible functions of antennal glomeruli are discussed. In contrast to olfactory sensilla, gustatory sensilla of the imago are located at many sites, including the labellum, the pharynx, the legs, the wing margin and the female genitalia. Each of these sensory sites has its own central target. Taste sensilla are usually composed of one mechano- and three chemosensory neurons. Individual chemosensory neurons within a sensillum respond to distinct subsets of molecules and project into different central target regions. The chemosensory system of the larva is much simpler and consists essentially of three major sensillar complexes on the cephalic lobe, the dorsal, terminal and ventral organs, and a series of pharyngeal sensilla.

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Molecular Architecture of Smell and Taste inDrosophila

Vosshall

Stocker

2007

Annu. Rev. Neurosci.

800

811

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The chemical senses-smell and taste-allow animals to evaluate and distinguish valuable food resources from dangerous substances in the environment. The central mechanisms by which the brain recognizes and discriminates attractive and repulsive odorants and tastants, and makes behavioral decisions accordingly, are not well understood in any organism. Recent molecular and neuroanatomical advances in Drosophila have produced a nearly complete picture of the peripheral neuroanatomy and function of smell and taste in this insect. Neurophysiological experiments have begun to provide insight into the mechanisms by which these animals process chemosensory cues. Given the considerable anatomical and functional homology in smell and taste pathways in all higher animals, experimental approaches in Drosophila will likely provide broad insights into the problem of sensory coding. Here we provide a critical review of the recent literature in this field and comment on likely future directions.

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Neuronal architecture of the antennal lobe in Drosophila melanogaster

et al. 1990

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Computer reconstruction of the antennal lobe of Drosophila melanogaster has revealed a total of 35 glomeruli, of which 30 are located in the periphery of the lobe and 5 in its center. Several prominent glomeruli are recognizable by their location, size, and shape; others are identifiable only by their positions relative to prominent glomeruli. No obvious sexual dimorphism of the glomerular architecture was observed. Golgi impregnations revealed: (1) Five of the glomeruli are exclusive targets for ipsilateral antennal input, whereas all others receive afferents from both antennae. Unilateral amputation of the third antennal segment led to a loss of about 1000 fibers in the antennal commissure. Hence, about 5/6 of the approximately 1200 antennal afferents per side have a process that extends into the contralateral lobe. (2) Afferents from maxillary palps (most likely from basiconic sensilla) project into both ipsi- and contralateral antennal lobes, yet their target glomeruli are apparently not the same as those of antennal basiconic sensilla. (3) Afferents in the antennal lobe may also stem from pharyngeal sensilla. (4) The most prominent types of interneurons with arborizations in the antennal lobe are: (i) local interneurons ramifying in the entire lobe, (ii) unilateral relay interneurons that extend from single glomeruli into the calyx and the lateral protocerebrum (LPR), (iii) unilateral interneurons that connect several glomeruli with the LPR only, (iv) bilateral interneurons that link a small number of glomeruli in both antennal lobes with the calyx and LPR, (v) giant bilateral interneurons characterized by extensive ramifications in both antennal lobes and the posterior brain and a cell body situated in the midline of the suboesophageal ganglion, and (vi) a unilateral interneuron with extensive arborization in one antennal lobe and the posterior brain and a process that extends into the thorax. These structural results are discussed in the context of the available functional and behavioral data.

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Target neuron prespecification in the olfactory map of Drosophila

Jefferis

Marin

Stocker³

et al. 2001

Nature

396

442

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Neuroblast ablation in Drosophila P[GAL4] lines reveals origins of olfactory interneurons

et al. 1997

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Hydroxyurea (HU) treatment of on targets in the calyx. Hence, the ablated interneuearly first instar larvae in Drosophila was previously rons were derived from the LNb, whereas the HUshown to ablate a single dividing lateral neuroblast (LNb) in the brain. Early larval HU application to resistant elements originated from neuroblasts which P[GAL4] strains that label specific neuron types enbegin to divide later in larval life. Developmental abled us to identify the origins of the two major classes GAL4 expression patterns suggested that differentiof interneurons in the olfactory system. HU treatment ated RI are present at the larval stage already and resulted in the loss of antennal lobe local interneurons may be retained through metamorphosis. ᭧ 1997 John and of a subset of relay interneurons (RI), elements Wiley & Sons, Inc. J Neurobiol 32: 443-456, 1997 usually projecting to the calyx and the lateral protoc-Keywords: olfactory interneurons; cell lineage; pererebrum (LPR). Other RI were resistant to HU and sisting larval neurons; P[GAL4] enhancer trap lines; still projected to the LPR. However, they formed no hydroxyurea ablation; Drosophila melanogaster collaterals in the calyx region (which was also ab-

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