Treatment with the antiepileptic drugs phenytoin and gabapentin ameliorates seizure and paralysis of Drosophila bang-sensitive mutants

Drosophila bang-sensitive (bs) mutants exhibit a stereotypic seizure and paralysis following exposure to mechanical shock. In a physiological preparation, seizures and failures corresponding to the defective behavior are observed in response to high frequency stimulation. The amplitude of the stimulus necessary to produce bs behavior, or seizure threshold, varies with bs mutant and its gene dosage. In many respects, the bs defects are similar to those observed in mammalian seizure disorders. Antiepileptic drugs (AEDs) were administered by feeding to easily shocked(2) (eas(2)), a representative bs mutant. The mean recovery times of treated flies were examined in comparison to control cultures. Some of the drugs administered, including carbamazeprine, ethosuximide, and vigabactrin, had little or no effect on the bs behavior of eas(2). Gabapentin, however, showed a reduction in mean recovery time with chronic drug exposure. Phenytoin also had a significant effect on the bs behavior of treated flies. There was a reduction of both mean recovery time and the percentage of flies that displayed bang-sensitive behavior with both acute and chronic treatment. The adult giant fiber preparation was used to examine the effects of phenytoin physiologically. Treated eas(2) flies showed changes in their response to normal stimulation as well as alterations in seizure threshold in response to high frequency stimulation. Gabapentin was also effective against two other bs mutants, bangsenseless(1) and slamdance(iso7.8), at strain-specific concentrations, while phenytoin also reduced bang-sensitive behaviors in bangsenseless(1) in a dose dependent manner. AEDs, therefore, can be used to dissect aspects of bs behavior and this model may be useful in understanding the underlying basis of seizure disorders.     

Altered mechanoreceptor response in Drosophila bang-sensitive mutants

Bang-sensitive mutants of Drosophila melano gaster (bas ¹, bss^MW1, eas², tko^25t) display seizure followed by paralysis when subjected to mechanical shock. However, no physiological or biochemical defect has been found to be common to all of these mutants. In order to observe the effects of bang-sensitive mutations upon an identified neuron, and to study the nature of mechanically induced paralysis, we examined the response of a mechanosensory neuron in these mutants. In each single mutant and the double mutant bas ¹ bss^MW1, the frequency of action potentials in response to a bristle displacement was reduced. This is the first demonstration of a physiological defect common to several of the bang-sensitive mutations. Adaptation of spike frequency, cumulative adaptation to repeated stimulation (fatigue) and the time course of recovery from adaptation were also examined. Recovery from adaptation to a conditioning stimulus was examined in two mutants (bas ¹ and bss ^MW1), and initial recovery from adaptation was greater in both mutants. Quantification of receptor potentials was complicated by variability inherent in extracellular recording conditions, but examination of the waveform and range of amplitudes did not indicate clear mutant defects. Therefore the differences observed in the spike response may be due to an alteration of the transfer from receptor potentials to action potential production. DNA sequence analysis of tko and eas has indicated that they encode apparently unrelated biochemical products. Our results suggest that these biochemical lesions lead to a common physiological defect in mechanoreceptors. Although this defect does not provide a straightforward explanation for bang sensitivity, the altered cellular process may lead to bang sensitivity through its action in different parts of the nervous system.Abbreviations APA anterior post-alar - ANP anterior notopleural - bas bang-sensitive - bss bang-senseless - eas easily-shocked tko technical knockout     

EFFECTS OF OXYGEN CONCENTRATION AND PRESSURE ON Drosophila melanogaster: OXIDATIVE STRESS,MITOCHONDRIAL ACTIVITY,AND SURVIVORSHIP

Organisms are known to be equipped with an adaptive plasticity as the phenotype of traits in response to the imposed environmental challenges as they grow and develop. In this study, the effects of extreme changes in oxygen availability and atmospheric pressure on physiological phenotypes of Drosophila melanogaster were investigated to explore adaptation mechanisms. The changes in citrate synthase activity (CSA), lifespan, and behavioral function in different atmospheric conditions were evaluated. In the CAS test, hyperoxia significantly increased CSA; both hypoxia and hyperbaric conditions caused a significant decrease in CSA. In the survivorship test, all changed atmospheric conditions caused a significant reduction in lifespan. The lifespan reduced more after hypoxia exposure than after hyperbaria exposure. In behavioral function test, when mechanical agitation was conducted, bang‐sensitive flies showed a stereotypical sequence of initial muscle spasm, paralysis, and recovery. The percentage of individuals that displayed paralysis or seizure was measured on the following day and after 2 weeks from each exposure. The majority of flies showed seizure behavior 15 days after exposure, especially after 3 h of exposure. The percentage of individuals that did not undergo paralysis or seizure and was able to move in the vial, was also tested. The number of flies that moved and raised the higher level of the vial decreased after exposure. Animal's speed decreased significantly 15 days after exposure to extreme environmental conditions. In summary, the alteration of oxygen availability and atmospheric pressure may lead to significant changes in mitochondria mass, lifespan, and behavioral function in D. melanogaster.     

Antiepileptic drugs: Impacts on human serum paraoxonase‐1

Serum paraoxonase (PON1) is a key enzyme related to high‐density lipoprotein (HDL)‐cholesterol particle. It can prevent the oxidation of low‐density lipoprotein (LDL) and HDL. The present article focuses on the in vitro inhibition role of some antiepileptic drugs (AEDs) such as valproic acid, gabapentin, primidone, phenytoin, and levetiracetam on human paraoxonase (hPON1). Therefore, PON1 was purified from human serum with a specific activity of 3976.36 EU/mg and 13.96% yield by using simple chromatographic methods. The AEDs were tested at various concentrations, which showed reduced in vitro hPON1 activity. IC₅₀ values for gabapentin, valproic acid, primidone, phenytoin, and levetiracetam were found to be 0.35, 0.67, 0.87, 6.3, and 53.3 mM, respectively. K_i constants were 0.261 ± 0.027, 0.338 ± 0.313, 0.410 ± 0.184, 10.3 ± 0.001, and 43.01 ± 0.003 mM, respectively. Gabapentin exhibited effective inhibitory activity as compared with the other drugs. The inhibition mechanisms of all compounds were noncompetitive.     

Calcium Imaging of Neuronal Activity in Drosophila Can Identify Anticonvulsive Compounds

Although there are now a number of antiepileptic drugs (AEDs) available, approximately one-third of epilepsy patients respond poorly to drug intervention. The reasons for this are complex, but are probably reflective of the increasing number of identified mutations that predispose individuals to this disease. Thus, there is a clear requirement for the development of novel treatments to address this unmet clinical need. The existence of gene mutations that mimic a seizure-like behaviour in the fruit fly, Drosophila melanogaster, offers the possibility to exploit the powerful genetics of this insect to identify novel cellular targets to facilitate design of more effective AEDs. In this study we use neuronal expression of GCaMP, a potent calcium reporter, to image neuronal activity using a non-invasive and rapid method. Expression in motoneurons in the isolated CNS of third instar larvae shows waves of calcium-activity that pass between segments of the ventral nerve cord. Time between calcium peaks, in the same neurons, between adjacent segments usually show a temporal separation of greater than 200 ms. Exposure to proconvulsants (picrotoxin or 4-aminopyridine) reduces separation to below 200 ms showing increased synchrony of activity across adjacent segments. Increased synchrony, characteristic of epilepsy, is similarly observed in genetic seizure mutants: bangsenseless¹ (bss¹) and paralytic^K1270T (para^K1270T). Exposure of bss¹ to clinically-used antiepileptic drugs (phenytoin or gabapentin) significantly reduces synchrony. In this study we use the measure of synchronicity to evaluate the effectiveness of known and novel anticonvulsive compounds (antipain, isethionate, etopiside rapamycin and dipyramidole) to reduce seizure-like CNS activity. We further show that such compounds also reduce the Drosophila voltage-gated persistent Na⁺ current (I_NaP) in an identified motoneuron (aCC). Our combined assays provide a rapid and reliable method to screen unknown compounds for potential to function as anticonvulsants.     

Metabolomic and flux‐balance analysis of age‐related decline of hypoxia tolerance in Drosophila muscle tissue

The fruitfly Drosophila melanogaster is increasingly used as a model organism for studying acute hypoxia tolerance and for studying aging, but the interactions between these two factors are not well known. Here we show that hypoxia tolerance degrades with age in post‐hypoxic recovery of whole‐body movement, heart rate and ATP content. We previously used ¹H NMR metabolomics and a constraint‐based model of ATP‐generating metabolism to discover the end products of hypoxic metabolism in flies and generate hypotheses for the biological mechanisms. We expand the reactions in the model using tissue‐ and age‐specific microarray data from the literature, and then examine metabolomic profiles of thoraxes after 4 h at 0.5% O₂ and after 5 min of recovery in 40‐ versus 3‐day‐old flies. Model simulations were constrained to fluxes calculated from these data. Simulations suggest that the decreased ATP production during reoxygenation seen in aging flies can be attributed to reduced recovery of mitochondrial respiration pathways and concomitant overdependence on the acetate production pathway as an energy source.     

Interaction between sexes and between different circadian phenotypes affects lifespan in the fruit fly Drosophila melanogaster

Circadian clocks regulate the daily temporal structure of physiological and behavioural functions. In the fruit fly Drosophila melanogaster Meigen, disruption of daily rhythms is suggested to reduce the fly's lifespan. In the present study, because pairs of mixed‐sex flies are known to show an activity pattern different from that of individual flies, this hypothesis is tested by measuring the lifespan of flies housed same‐sexually or mixed‐sexually under an LD 12 : 12 h photocycle at a constant temperature of 25 °C. The effect of housing wild‐type (Canton‐S) flies with period (per) circadian clock mutant flies is also examined because the mutant flies have different daily activity patterns. When males and females of wild‐type flies are housed together, their lifespan is substantially lengthened (males) or shortened (females) compared with same‐sex housed flies. The shortening of the lifespan in females is significantly enhanced when mated with per mutant males. The shortening effects are significantly reduced when the mixed‐sex interaction is limited for the first 5 days after emergence. A slight elongation in lifespan, rather than a reduction, occurs when wild‐type females are housed same‐sexually with per⁰ or per^L mutant flies. In male flies, the elongation of lifespan occurs not only when wild‐type males are housed with wild‐type, per⁰ or per^L females, but also when housed with per⁰ or per^S mutant males. Mixed‐sex couples always show altered daily locomotor rhythms with an enhanced night‐time activity, whereas same‐sex couples show daily behavioural profiles slightly altered but essentially similar to a sum of the respective two flies. No significant correlation is found between the lifespan and reproductive capacity. These results suggest that the alteration of daily activity rhythms and sexual interaction may have significant impact on the fly's lifespan.     

Neurocircuit Assays for Seizures in Epilepsy Mutants of Drosophila

Drosophila melanogaster is a useful tool for studying seizure like activity. A variety of mutants in which seizures can be induced through either physical shock or electrical stimulation is available for study of various aspects of seizure activity and behavior. All flies, including wild-type, will undergo seizure-like activity if stimulated at a high enough voltage. Seizure like activity is an all-or-nothing response and each genotype has a specific seizure threshold. The seizure threshold of a specific genotype of fly can be altered either by treatment with a drug or by genetic suppression or enhancement. The threshold is easily measured by electrophysiology. Seizure-like activity can be induced via high frequency electrical stimulation delivered directly to the brain and recorded through the dorsal longitudinal muscles (DLMs) in the thorax. The DLMs are innervated by part of the giant fiber system. Starting with low voltage, high frequency stimulation, and subsequently raising the voltage in small increments, the seizure threshold for a single fly can be measured.Open in a separate windowClick here to view.^{(57M, flv)}     

High sensitivity to sodium in the sugar chemoreceptor of the cherry fruit fly after emergence

Abstract Recordings from the tarsal contact chemoreceptor D-sensilla of the cherry fruit fly (Rhagoletis cerasi, Dipt., Tephritidae) revealed the presence of a cell which had a variable sensitivity spectrum. In about 60% of the sensilla of freshly emerged flies this cell was found to be very sensitive to sodium and to a lesser degree to lithium cations. Potassium and other alkali cations were non-stimulatory. The anions tested, Cl^-, F^-, Br, NO₃^-, and CO₃^-, had no effect on the response to sodium. The same Na⁺-sensitive receptor cells fired in response to stimulation with sucrose plus NaCl or sucrose plus KCI mixtures and were therefore considered to be sugar cells. This was confirmed by cross-adaptation experiments using NaCl, and sucrose dissolved in dilute NaCl or KCI. However, the two adaptive stimuli were not acting symmetrically: NaCl did inhibit the following stimulation with sucrose, whereas sucrose had no effect on the subsequent NaCl stimulation. The response to sucrose and NaCl were not additive, sucrose being apparently, in some sensilla, inhibitory to the stimulation by NaCl. This observation, the lack of symmetry in adaptation, as well as the fact that only a proportion of the sensilla were sensitive to NaCl, seems to indicate that sodium had a different stimulating mechanism than sucrose. In most sensilla of flies older than 24 h, the Na⁺ sensitivity of the sugar cell was either reduced or completely lost. Behavioural observations of cherry fruit flies during the first 3 ½ days of adult life revealed that the flies fed little or not at all in the first 12 h. Thus the pronounced sodium sensitivity of the sugar cell early in adult life seems not to be correlated with a specific need for sodium intake but may have some role in the functioning of the sugar cell.     

The Drosophila slamdance gene: a mutation in an aminopeptidase can cause seizure,paralysis and neuronal failure

We report here the characterization of slamdance (sda), a Drosophila melanogaster "bang-sensitive" (BS) paralytic mutant. This mutant exhibits hyperactive behavior and paralysis following a mechanical "bang" or electrical shock. Electrophysiological analyses have shown that this mutant is much more prone to seizure episodes than normal flies because it has a drastically lowered seizure threshold. Through genetic mapping, molecular cloning, and RNA interference, we have demonstrated that the sda phenotype can be attributed to a mutation in the Drosophila homolog of the human aminopeptidase N (APN) gene. Furthermore, using mRNA in situ hybridization and LacZ staining, we have found that the sda gene is expressed specifically in the central nervous system at particular developmental stages. Together, these results suggest that the bang sensitivity in sda mutants is caused by a defective APN gene that somehow increases seizure susceptibility. Finally, by using the sda mutation as a sensitized background, we have been able to identify a rich variety of sda enhancers and other independent BS mutations.     

A Low-cost Method for Analyzing Seizure-like Activity and Movement in Drosophila

Video tracking systems have been used widely to analyze Drosophila melanogaster movement and detect various abnormalities in locomotive behavior. While these systems can provide a wealth of behavioral information, the cost and complexity of these systems can be prohibitive for many labs. We have developed a low-cost assay for measuring locomotive behavior and seizure movement in D. melanogaster. The system uses a web-cam to capture images that can be processed using a combination of inexpensive and free software to track the distance moved, the average velocity of movement and the duration of movement during a specified time-span. To demonstrate the utility of this system, we examined a group of D. melanogaster mutants, the Bang-sensitive (BS) paralytics, which are 3-10 times more susceptible to seizure-like activity (SLA) than wild type flies. Using this novel system, we were able to detect that the BS mutant bang senseless (bss) exhibits lower levels of exploratory locomotion in a novel environment than wild type flies. In addition, the system was used to identify that the drug metformin, which is commonly used to treat type II diabetes, reduces the intensity of SLA in the BS mutants.     

Drosophila neural pathways

Summary TheDrosophila giant axon pathways cervical connective — thoracic indirect flight muscles were studied by a combined electrophysiological and genetic analysis. A functional coupling of the left and right giant axon pathways was revealed by intracellular recordings of electrical responses of the thoracic indirect flight muscles, when evoked by electrical stimulation of cervical connective (Fig. 2). This functional coupling was demonstrated in wild-type flies and in flies of the single gene, temperature-sensitive paralytic mutation,para ^ts . The functional coupling was evident also in selected bilateral gynandromorph flies, mosaics for thepara ^ts mutation (Fig. 1), even at restricted elevated ambient temperature (Tables 1–3). Analysis of neurally evoked electrogenic muscle responses of wild-type flies, following injection of picrotoxin, verifies the notion that both the dorsoventral and the dorsolongitudinal flight muscles share a common activating pathway (Fig. 3). Picrotoxin application to gynandromorph flies demonstrated the existence of neuronal elements additional to the giant axon pathways, that evoke the indirect flight muscles in response to cervical stimulation (Figs. 4, 5). An unexpected finding was the poor correlation between the mosaic external phenotype of the gynandromorph flies ofpara ^ts mutation and the genotype of neural pathways activating their thoracic flight muscles, as evidenced by the intracellular recordings.Abbreviations GA giant axon - DVM dorsoventral muscle - DLM dorsolongitudinal muscle - PSI peripherally synapsing interneuron - ts temperature sensitive     

Specific detection of the Old World screwworm fly,Chrysomya bezziana,in bulk fly trap catches using real‐time PCR

The Old World screwworm fly (OWS), Chrysomya bezziana Villeneuve (Diptera: Calliphoridae), is a myiasis‐causing blowfly of major concern for both animals and humans. Surveillance traps are used in several countries for early detection of incursions and to monitor control strategies. Examination of surveillance trap catches is time‐consuming and is complicated by the presence of morphologically similar flies that are difficult to differentiate from Ch. bezziana, especially when the condition of specimens is poor. A molecular‐based method to confirm or refute the presence of Ch. bezziana in trap catches would greatly simplify monitoring programmes. A species‐specific real‐time polymerase chain reaction (PCR) assay was designed to target the ribosomal DNA internal transcribed spacer 1 (rDNA ITS1) of Ch. bezziana. The assay uses both species‐specific primers and an OWS‐specific Taqman^® MGB probe. Specificity was confirmed against morphologically similar and related Chrysomya and Cochliomyia species. An optimal extraction protocol was developed to process trap catches of up to 1000 flies and the assay is sensitive enough to detect one Ch. bezziana in a sample of 1000 non‐target species. Blind testing of 29 trap catches from Australia and Malaysia detected Ch. bezziana with 100% accuracy. The probability of detecting OWS in a trap catch of 50 000 flies when the OWS population prevalence is low (one in 1000 flies) is 63.6% for one extraction. For three extractions (3000 flies), the probability of detection increases to 95.5%. The real‐time PCR assay, used in conjunction with morphology, will greatly increase screening capabilities in surveillance areas where OWS prevalence is low.     

Temporal Variation in the Relative Abundance of Fruit Bats (Megachiroptera: Pteropodidae) in Relation to the Availability of Food in a Lowland Malaysian Rain Forest

The aims of this study were to investigate the diet and relative abundance of fruit bats in a lowland Malaysian rain forest and to test the hypothesis that the local assemblage structure of fruit bats varies significantly over time in relation to the availability of food. In total, 352 fruit bats of eight species were captured during 72,306 m² mist‐net hours of sampling between February 1996 and September 1999. Three species of fruit bats (Balionycteris maculita, Chironax melanocephalus, and Cynopterus brachyotis) that fed on a wide range of “steady state” and “big bang” food resources were captured continuously throughout the study period, with no significant variation in capture rates over time. In contrast, five species that fed exclusively or almost exclusively on “big bang” food resources were sampled intermittently, with significant temporal variation in the capture rates of two species (Cynopterus horsfieldi and Megaerops ecaudatus). Significant variation in the capture rates of the remaining three species (Dyacopterus spadiceus, Eonycteris spelaea, and Rousettus amplexicaudatus) could not be detected due to small sample sizes. Since ephemeral “big bang” food resources were only sporadically available within the study area and were associated with large canopy trees and strangler figs, these results suggest that food abundance, or the availability of specific food items, may be important factors limiting local fruit bat species diversity in old‐growth Paleotropical rain forest. Thus, only three fruit bat species were locally resident within the forest throughout the study period. Therefore, further studies on the ranging behavior and habitat requirements of Malaysian fruit bats are required to assess the adequacy of existing reserves and protected areas.     

Neural correlates of flight activation and escape behavior in houseflies recovering from pyrethroid poisoning

Recovery from pyrethroid poisoning was studied in groups of adult female houseflies treated with LD50 doses of trans-permethrin or deltamethrin. The first overt sign of recovery was the appearance of normal posture, which was followed by jumping behavior and finally, coordinated flight when the flies had fully recovered. Prior to full recovery, treated houseflies were able to maintain normal posture and usually jump, but they could not fly. When tethered, these flightless houseflies responded to loss of tarsal contact by initiating normal patterned activity in the dorsolongitudinal flight muscles, yet the wings did not move. In flightless flies displaying jumping behavior, electrical stimulation of the brain evoked responses in the pleurosternal muscle, which controls thoracic tension during flight. Thus, many of the motor systems responsible for flight behavior seemed to be functional in flightless flies. Carbofuran, a carbamate anticholinesterase known to initiate spontaneous flight behavior from within the central nervous system, failed to elicit this response in flightless flies. These results suggested that the flightless condition was due to a disruption in central nervous pathways, and not to peripheral neuromuscular block. The pattern of recovery of different behaviors analyzed in this study was found to be consistent with the Jacksonian Hierarchy Principle, and the utility of this principle in guiding the design of new behavior-modifying compounds is discussed.     

Investigating dietary preferences in two competing dipterans, Coelopa frigida and Coelopa pilipes, using stable isotope ratios of carbon and nitrogen

Two species of seaweed fly, Coelopa frigida (Fabricius) and Coelopa pilipes (Halliday) (both Diptera: Coelopidae: Coelopini), compete for resources within deposits of marine algae washed ashore on British beaches. Previous studies report that adult flies exhibit algal‐specific behaviour that may influence interspecific interactions. It is predicted that coelopid larvae may also demonstrate algal‐specific dietary preferences. Larval dietary preferences are investigated by comparing the ratios of ¹³C/¹²C and ¹⁵N/¹⁴N in both wild flies and macroalgae to those of laboratory‐reared flies. Results showed only a small difference between the stable isotope ratios of the most abundant algae, Laminaria spp. (Laminariaceae) and Fucus spp. (Fucaceae), although there were significant differences between wild adult coelopids. This result illustrates different metabolic processes in two closely related species. The stable isotope ratios of wild‐caught coelopids were found to differ significantly from laboratory‐reared coelopids. This is either the result of red algae in the diet of natural populations or a difference in bacterial communities. We suggest that experiments with laboratory‐reared flies/specimens can greatly increase the utility of stable isotope analysis in the investigation of animal food webs, even where potential diets are isotopically similar. However, this approach is dependent on re‐creations that accurately mimic natural conditions.     

Effect of sodium channel abundance on Drosophila development,reproductive capacity and aging

The voltage-gated Na⁺ channels (VGSC) are complex membrane proteins responsible for generation and propagation of the electrical signals through the brain, the skeletal muscle and the heart. The levels of sodium channels affect behavior and physical activity. This is illustrated by the maleless mutant allele (mle^napts) in Drosophila, where the decreased levels of voltage-gated Na⁺ channels cause temperature-sensitive paralysis.

Here, we report that mle^napts mutant flies exhibit developmental lethality, decreased fecundity and increased neurodegeneration. The negative effect of decreased levels of Na⁺ channels on development and ts-paralysis was more pronounced at 18 and 29°C than at 25°C, suggesting particular sensitivity of the mle^napts flies to temperatures above and below normal environmental conditions. Similarly, longevity of mle^napts flies was unexpectedly short at 18 and 29°C compared with flies heterozygous for the mle^napts mutation. Developmental lethality and neurodegeneration of mle^napts flies was partially rescued by increasing the dosage of para, confirming a vital role of Na⁺ channels in development, longevity and neurodegeneration of flies and their adaptation to temperatures.     

Conditional modification of behavior in Drosophila by targeted expression of a temperature‐sensitive shibire allele in defined neurons

Behavior is a manifestation of temporally and spatially defined neuronal activities. To understand how behavior is controlled by the nervous system, it is important to identify the neuronal substrates responsible for these activities, and to elucidate how they are integrated into a functional circuit. I introduce a novel and general method to conditionally perturb anatomically defined neurons in intact Drosophila. In this method, a temperature‐sensitive allele of shibire (shi^ts1) is overexpressed in neuronal subsets using the GAL4/UAS system. Because the shi gene product is essential for synaptic vesicle recycling, and shi^ts1 is semidominant, a simple temperature shift should lead to fast and reversible effects on synaptic transmission of shi^ts1 expressing neurons. When shi^ts1 expression was directed to cholinergic neurons, adult flies showed a dramatic response to the restrictive temperature, becoming motionless within 2 min at 30°C. This temperature‐induced paralysis was reversible. After being shifted back to the permissive temperature, they readily regained their activity and started to walk in 1 min. When shi^ts1 was expressed in photoreceptor cells, adults and larvae exhibited temperature‐dependent blindness. These observations show that the GAL4/UAS system can be used to express shi^ts1 in a specific subset of neurons to cause temperature‐dependent changes in behavior. Because this method allows perturbation of the neuronal activities rapidly and reversibly in a spatially and temporally restricted manner, it will be useful to study the functional significance of particular neuronal subsets in the behavior of intact animals. © 2001 John Wiley & Sons, Inc. J Neurobiol 47: 81–92, 2001     

Electrophysiological analysis of the temperature-sensitive paralyticDrosophila mutant,para ts

Summary Paralysis of flight in the temperature-sensitiveDrosophila mutantpara ^ts was found to be dependent on the rate of heating (Fig. 2). The gradual nature of the onset of paralysis during the temperature elevation was revealed by recording the electrical responses of the thoracic flight muscle fibers, evoked by cervical stimulation (Figs. 3,4). A neural focus of the mutation was indicated by intracellular current injections into identified flight muscle fibers during paralysis (Fig. 5) and by electrical activity recorded from gynandromorph flies, mosaic forpara ^ts (Table 1). Recording from picrotoxin-treated flies excluded a previous explanation of paralysis by a temperature-induced augmentation of GABAergic inhibition (Fig. 6). Under the same treatment, evidence was presented for a heterogeneous increase of excitation threshold for spike generation in certain neurons.Abbreviations DLM dorsolongitudinal muscle - DVM dorsoventral muscle - ts temperature sensitive - GABA Gamma aminobutyric acid We wish to thank Dr. E. Lifschytz for providing the facilities for culturing flies in his laboratory. This research was supported by Grant No. 625 from the U.S.-Israel Binational Science Foundation to D.D.     

Phospholipid homeostasis and lipotoxic cardiomyopathy

Obesity has reached pandemic proportions globally and is often associated with lipotoxic heart diseases. In the obese state, caloric surplus is accommodated in the adipocytes as triglycerides. As the storage capacity of adipocytes is exceeded or malfunctioning, lipids begin to infiltrate and accumulate in non-adipose tissues, including the myocardium of the heart, leading to organ dysfunction. While the disruption of caloric homeostasis has been widely viewed as a principal mechanism in contributing to peripheral tissue steatosis and lipotoxicity, our recent studies in Drosophila have led to the novel finding that deregulation of phospholipid homeostasis may also significantly contribute to the pathogenesis of lipotoxic cardiomyopathy. Fly mutants that bear perturbations in phosphatidylethanolamine (PE) biosynthesis, such as the easily-shocked (eas) mutants defective in ethanolamine kinase, incurred aberrant activation of the sterol regulatory element binding protein (SREBP) pathway, thereby causing chronic lipogenesis and cardiac steatosis that culminates in the development of lipotoxic cardiomyopathy ¹. Here, we describe the potential relationship between SREBP and other eas-associated phenotypes, such as neuronal excitability defects. We will further discuss the additional implications presented by our work toward the effects of altered lipid metabolism on cellular growth and/or proliferation in response to defective phospholipid homeostasis.