A subset of Drosophila neurons that expresses crustacean cardioactive peptide (CCAP) has been shown previously to make the hormone bursicon, which is required for cuticle tanning and wing expansion after eclosion. Here we present evidence that CCAP-expressing neurons (N CCAP ) consist of two functionally distinct groups, one of which releases bursicon into the hemolymph and the other of which regulates its release. The first group, which we call N CCAP -c929, includes 14 bursicon-expressing neurons of the abdominal ganglion that lie within the expression pattern of the enhancer-trap line c929-Gal4. We show that suppression of activity within this group blocks bursicon release into the hemolymph together with tanning and wing expansion. The second group, which we call N CCAP -R, consists of N CCAP neurons outside the c929-Gal4 pattern. Because suppression of synaptic transmission and protein kinase A (PKA) activity throughout N CCAP , but not in N CCAP -c929, also blocks tanning and wing expansion, we conclude that neurotransmission and PKA are required in N CCAP -R to regulate bursicon secretion from N CCAP -c929. Enhancement of electrical activity in N CCAP -R by expression of the bacterial sodium channel NaChBac also blocks tanning and wing expansion and leads to depletion of bursicon from central processes. NaChBac expression in N CCAP -c929 is without effect, suggesting that the abdominal bursicon-secreting neurons are likely to be silent until stimulated to release the hormone. Our results suggest that N CCAP form an interacting neuronal network responsible for the regulation and release of bursicon and suggest a model in which PKA-mediated stimulation of inputs to normally quiescent bursicon-expressing neurons activates release of the hormone.
After emergence, adult flies and other insects select a suitable perch and expand their wings. Wing expansion is governed by the hormone bursicon and can be delayed under adverse environmental conditions. How environmental factors delay bursicon release and alter perch selection and expansion behaviors has not been investigated in detail. Here we provide evidence that in Drosophila the motor programs underlying perch selection and wing expansion have different environmental dependencies. Using physical manipulations, we demonstrate that the decision to perch is based primarily on environmental valuations and is incrementally delayed under conditions of increasing perturbation and confinement. In contrast, the all-or-none motor patterns underlying wing expansion are relatively invariant in length regardless of environmental conditions. Using a novel technique for targeted activation of neurons, we show that the highly stereotyped wing expansion motor patterns can be initiated by stimulation of N CCAP , a small network of central neurons that regulates the release of bursicon. Activation of this network using the cold-sensitive rat TRPM8 channel is sufficient to trigger all essential behavioral and somatic processes required for wing expansion. The delay of wing expansion under adverse circumstances thus couples an environmentally sensitive decision network to a command-like network that initiates a fixed action pattern. Because N CCAP mediates environmentally insensitive ecdysis-related behaviors in Drosophila developmentbeforeadultemergence,thestudyofwingexpansionpromisesinsightsnotonlyintohownetworksmediatebehavioralchoices,but also into how decision networks develop.
Disturbance of neural activity by sedative drugs has been proposed to trigger a homeostatic response that resists unfavorable changes in net cellular excitability, leading to tolerance and dependence. The Drosophila slo gene encodes a BK-type Ca 2+ -activated K + channel implicated in functional tolerance to alcohol and volatile anesthetics. We hypothesized that increased expression of BK channels induced by these drugs constitutes the homeostatic adaptation conferring resistance to sedative drugs. In contrast to the dogmatic view that BK channels act as neural depressants, we show that drug-induced slo expression enhances excitability by reducing the neuronal refractory period. Although this neuroadaptation directly counters some effects of anesthetics, it also causes long-lasting enhancement of seizure susceptibility, a common symptom of drug withdrawal. These data provide a possible mechanism for the long-standing counter-adaptive theory for drug tolerance in which homeostatic adaptations triggered by drug exposure to produce drug tolerance become counter-adaptive after drug clearance and result in symptoms of dependence.addiction | anesthesia | drug abuse | seizure | epilepsy
Background Perhaps the most difficult thing to ascertain concerning the behavior of another animal is its motivation. The motivation underlying the preference of Drosophila melanogaster for ethanol-rich food has long been ascribed to its value as a food. A recently introduced idea is that, as in humans, the pharmacological effects of ethanol also motivate the fly to choose ethanol-rich food over non-alcoholic food. Methods Flies are given a choice between pipets that contain liquid food and liquid food supplemented with ethanol. In some experiments, carbohydrates are added to the non-ethanol-containing food to balance the calories for ethanol. Results We confirm that Drosophila melanogaster indeed prefer food that is supplemented with ethanol. However, if the alternative food choice is isocaloric, Drosophila melanogaster usually do not show any preference for a 10% ethanol solution. Even after ethanol preference has been established, it can be completely reversed if the alternative food is calorically supplemented. This occurs even when the carbohydrate solution used to balance calories is not gustatorily attractive. Furthermore, if the alternative food contains more calories than the ethanol food, the flies will prefer the non-ethanol food. We go on to show that during the preference assay that ethanol in the fly does not exceed 4 mM, which in mammals is a non-intoxicating dose. Conclusions We conclude that preference for ethanol in this assay arises not from the pharmacological effects of ethanol but rather because of its nutritive value.
Background There is a strong relationship between circadian rhythms and ethanol responses. Ethanol consumption has been shown to disrupt physiological and behavioral circadian rhythms in mammals (Spanagel et al., 2005b). The Drosophila central circadian pacemaker is composed of proteins encoded by the per, tim, cyc, and Clk genes. Using Drosophila mutant analysis we asked whether these central components of the circadian clock make the equivalent contribution towards ethanol tolerance and whether rhythmicity itself is necessary for tolerance. Methods We tested flies carrying mutations in core clock genes for the capacity to acquire ethanol tolerance. Tolerance was assayed by comparing the sedation curves of populations during their first and second sedation. Animals that had acquired tolerance sedated more slowly. Movement was also monitored as the flies breathe the ethanol vapor to determine if other facets of the ethanol response were affected by the mutations. Gas chromatography was used to measure internal ethanol concentration. Constant light was used to non-genetically destabilize the PER and TIM proteins. Results A group of circadian mutations, all of which eliminate circadian rhythms, do not disrupt tolerance identically. Mutations in per, tim, and cyc completely block tolerance. However, a mutation in Clk does not interfere with tolerance. Constant light also disrupts the capacity to acquire tolerance. These lines did not differ in ethanol absorption. Conclusions Mutations affecting different parts of the intracellular circadian clock can block the capacity to acquire rapid ethanol tolerance. However, the role of circadian genes in ethanol tolerance is independent of their role in producing circadian rhythmicity. The interference in the capacity to acquire ethanol tolerance by some circadian mutations is not merely a downstream effect of a nonfunctional circadian clock, instead these circadian genes play an independent role in ethanol tolerance.
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