2000
DOI: 10.1016/s0022-1910(99)00109-2
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Neurophysiological and behavioural evidence for an olfactory function for the dorsal organ and a gustatory one for the terminal organ in Drosophila melanogaster larvae

Abstract: Multicellular electrophysiological responses from the dorsal organ on the cephalic lobes of third instar Drosophila melanogaster larvae (wild-type Canton S) stimulated with a cold-trapped banana volatile extract showed that this structure has an olfactory function in the fruit fly. Responses of the dorsal organ were also recorded to constituents of the banana volatile extract as they eluted from a gas chromatographic column (GC-coupled dorsal organ electrophysiology). The active chemostimulants were identified… Show more

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Cited by 76 publications
(83 citation statements)
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“…1-Hexanol caused a dose dependent increase in attraction and was the compound that induced the highest target vector response values from Lobesia larvae. This attraction indicates that 1-hexanol plays a fundamental role in the olfactory responses of these larvae, as has also been found for Drosophila melanogaster larvae (Cobb and Domain, 2000;Oppliger et al, 2000). 1-Hexanol was also tested here in 1:1 (v/v) binary mixtures with host plant compounds of other chemical classes.…”
Section: Behavioural Response To the Odour Of The Artificial Diet Andsupporting
confidence: 69%
“…1-Hexanol caused a dose dependent increase in attraction and was the compound that induced the highest target vector response values from Lobesia larvae. This attraction indicates that 1-hexanol plays a fundamental role in the olfactory responses of these larvae, as has also been found for Drosophila melanogaster larvae (Cobb and Domain, 2000;Oppliger et al, 2000). 1-Hexanol was also tested here in 1:1 (v/v) binary mixtures with host plant compounds of other chemical classes.…”
Section: Behavioural Response To the Odour Of The Artificial Diet Andsupporting
confidence: 69%
“…Gyc-88E stained one neuron in each of the two terminal ganglia while Gyc-89Db stained 2-5 neurons in each of the terminal ganglia and 4-5 neurons in each of the two dorsal ganglia. The terminal ganglion innervates the maxillary organ, which is known to serve a gustatory function and has at least six different types of sensilla (Stocker, 1994;Heimbeck et al, 1999;Oppliger et al, 2000). The dorsal ganglion innervates the dorsal or antennal organ, which consists of seven different sensilla and is the main olfactory organ in larval Drosophila (Stocker, 1994;Heinbeck et al, 1999;Oppliger et al, 2000).…”
Section: Biochemical Properties Ofmentioning
confidence: 99%
“…This method enables sensitive measurements of action potential patterns and shows whether responses are excitatory or inhibitory, but drawing final conclusions about the individual firing neuron is difficult, as each sensillum contains two to four neurons 14 . In the larva, multicellular electrophysiological measurements of the taste system have been performed, but this method is technically challenging and it is not clear how many taste neurons are housed in which sensillum 15 .…”
Section: Introductionmentioning
confidence: 99%
“…This method enables sensitive measurements of action potential patterns and shows whether responses are excitatory or inhibitory, but drawing final conclusions about the individual firing neuron is difficult, as each sensillum contains two to four neurons 14 . In the larva, multicellular electrophysiological measurements of the taste system have been performed, but this method is technically challenging and it is not clear how many taste neurons are housed in which sensillum 15 .Microfluidic devices have been used previously to image command interneurons (AVA) and sensory neurons (ASH) in the nematode Caenorhabditis elegans and for studies of axotomy in peripheral sensory neurons of Drosophila larvae [16][17][18] . To implement a similar strategy for Drosophila larval chemosensation, we developed a simple and widely applicable microfluidic chip.…”
mentioning
confidence: 99%