Teiichi Tanimura

Molecular clearance of ataxin‐3 is regulated by a mammalian E4

Insoluble aggregates of polyglutamine‐containing proteins are usually conjugated with ubiquitin in neurons of individuals with polyglutamine diseases. We now show that ataxin‐3, in which the abnormal expansion of a polyglutamine tract is responsible for spinocerebellar ataxia type 3 (SCA3), undergoes ubiquitylation and degradation by the proteasome. Mammalian E4B (UFD2a), a ubiquitin chain assembly factor (E4), copurified with the polyubiquitylation activity for ataxin‐3. E4B interacted with, and thereby mediated polyubiquitylation of, ataxin‐3. Expression of E4B promoted degradation of a pathological form of ataxin‐3. In contrast, a dominant‐negative mutant of E4B inhibited degradation of this form of ataxin‐3, resulting in the formation of intracellular aggregates. In a Drosophila model of SCA3, expression of E4B suppressed the neurodegeneration induced by an ataxin‐3 mutant. These observations suggest that E4 is a rate‐limiting factor in the degradation of pathological forms of ataxin‐3, and that targeted expression of E4B is a potential gene therapy for SCA3.

Differentiated response to sugars among labellar chemosensilla in Drosophila.

Abstract Recent findings have indicated that the Gr genes for putative gustatory receptors of Drosophila melanogaster are expressed in a spatially restricted pattern among chemosensilla on the labellum. However, evidence for a functional segregation among the chemosensilla is lacking. In this work, labellar chemosensilla were classified and numbered into three groups, L-, I- and S-type, based on their morphology. Electrophysiological responses to sugars and salt were recorded from all the accessible labellar chemosensilla by the tip-recording method. All the L-type sensilla gave good responses to sugars in terms of action potential firing rates, while the probability for successful recordings from the I-type and S-type sensilla was lower. No differences were found in the responses to sugars between chemosensilla belonging to the same type; however, dose-response curves for several different sugars varied among the sensilla types. The L-type sensilla gave the highest frequency of nerve responses to all the sugars. The I-type sensilla also responded to all the sugars but with a lower magnitude of firing rate than the L-type sensilla. The S-type sensilla gave a good response to sucrose, and lower responses to the other sugars. These results suggest that there might be variations in the expression level or pattern of multiple receptors for sugars among the three types of chemosensilla. The expression pattern of six Gr genes was examined using the Gal4/UAS-GFP system, and sensilla were identified according to the innervation pattern of each GFP-expressing taste cell. None of the spatial expression patterns of the six Gr genes corresponded to the sugar sensitivity differences we observed.

Temperature cycles drive Drosophila circadian oscillation in constant light that otherwise induces behavioural arrhythmicity

The fruit fly, Drosophila melanogaster, shows a clear circadian locomotor rhythm in light cycles and constant darkness. Although the rhythm disappears in constant light, we found that temperature cycles drive the circadian rhythm both in locomotor activity and molecular abundance of PERIOD (PER) and TIMELESS (TIM). The thermoperiodically induced locomotor rhythm entailed an anticipatory activity at the late thermophase, which required several transient cycles to establish a steady‐state entrainment, suggesting that the rhythm is endogenous and driven by a circadian clock. Western blot analysis revealed that PER and TIM increased during the cryophase, peaking at the middle to late cryophase. PER was also cyclically expressed under the temperature cycle in the known per‐expressing neurons, i.e. so‐called lateral (LNs) and dorsal neurons (DNs), and two pairs of cells (LPNs) that were located in the lateral posterior protocerebrum. It is thus suggested that the temperature cycle induces the cycling of PER and TIM either by blocking somewhere in the photic entrainment pathway during the cryophase or temporally activating their translation to sufficient protein levels to drive a circadian oscillation. In flies lacking pigment‐dispersing factor (PDF) or PDF‐expressing cells, the anticipatory activity was relatively dispersed. disco2 mutant flies lacking the lateral neurons still showed an anticipatory activity, but with dispersed activity. These behavioural results suggest that not only LNs but also DNs and LPNs can, at least, partially participate in regulating the thermoperiodically induced rhythm.

DCRY is a Drosophila photoreceptor protein implicated in light entrainment of circadian rhythm

: Light is the major environmental signal for the entrainment of circadian rhythms. In Drosophila melanogaster, the period(per) and timeless (tim) genes are required for circadian behavioural rhythms and their expression levels undergo circadian fluctuations. Light signals can entrain these rhythms by shifting their phases. However, little is known about the molecular mechanism for the perception and transduction of the light signal. The members of the photolyase/cryptochrome family contain flavin adenine dinucleotide (FAD) as chromophore and are involved in two diverse functions, DNA repair and photoreception of environmental light signals.

The period gene and allochronic reproductive isolation in Bactrocera cucurbitae

Clock genes that pleiotropically control circadian rhythm and the time of mating may cause allochronic reproductive isolation in the melon fly Bactrocera cucurbitae (Coquillett) (Diptera: Tephritidae). Flies with a shorter circadian period (ca. 22 h of locomotor activity rhythm) mated 5 h earlier in the day than those with a longer circadian period (ca. 30 h). Mate–choice tests demonstrated significant pre–mating isolation between populations with short and long circadian periods. Pre–mating isolation did not occur when the mating time was synchronized between the two populations by photoperiodic controls, indicating that reproductive isolation is due to variations in the time of mating and not any unidentified ethological difference between the two populations. We cloned the period (per) gene of B. cucurbitae that is homologous to the per gene in Drosophila. The relative level of per mRNA in the melon fly exhibited a robust daily fluctuation under light : dark conditions. The fluctuation of per expression under dark : dark conditions is closely correlated to the locomotor rhythm in B. cucurbitae. These results suggest that clock genes can cause reproductive isolation via the pleiotropic effect as a change of mating time.

Molecular neurophysiology of taste in Drosophila.

The recent identification of candidate receptor genes for sweet, umami and bitter taste in mammals has opened a door to elucidate the molecular and neuronal mechanisms of taste. Drosophila provides a suitable system to study the molecular, physiological and behavioral aspects of taste, as sophisticated molecular genetic techniques can be applied. A gene family for putative gustatory receptors has been found in the Drosophila genome. We discuss here current knowledge of the gustatory physiology of Drosophila. Taste cells in insects are primary sensory neurons whereupon each receptor neuron responds to either sugar, salt or water. We found that particular tarsal gustatory sensilla respond to bitter compounds. Electrophysiological studies indicate that gustatory sensilla on the labellum and tarsi are heterogeneous in terms of their taste sensitivity. Determination of the molecular bases for this heterogeneity could lead to an understanding of how the sensory information is processed in the brain and how this in turn is linked to behavior.

timrit Lengthens Circadian Period in a Temperature-Dependent Manner through Suppression of PERIOD Protein Cycling and Nuclear Localization

ABSTRACT A fundamental feature of circadian clocks is temperature compensation of period. The free-running period of ritsu(timrit ) (a novel allele oftimeless [tim]) mutants is drastically lengthened in a temperature-dependent manner. PER and TIM protein levels become lower in timrit mutants as temperature becomes higher. This mutation reduces per mRNA but not tim mRNA abundance. PER constitutively driven by the rhodopsin1 promoter is lowered in ritmutants, indicating that timrit mainly affects the per feedback loop at a posttranscriptional level. An excess of per + gene dosage can ameliorate allrit phenotypes, including the weak nuclear localization of PER, suggesting that timrit affects circadian rhythms by reducing PER abundance and its subsequent transportation into nuclei as temperature increases.

Chronobiological analysis of a new clock mutant, Toki, in Drosophila melanogaster.

We have isolated a new semidominant clock mutant Toki on the second chromosome in Drosophila melanogaster. This mutant differs from the wild-type Canton-S in several properties as follows. Larger values are obtained in the phase angle difference (phi, the time from lights-off in a 24-hr light-dark cycle to an activity offset), the ratio of activity time to rest time (alpha/rho) and the activity level. The free-running period (tau) is 25.3 hr, one hour longer than in the wild-type. In the phase response curve (PRC), the ratio between the delay and the advance portion is larger and the cross-over point occurs later, although there is no difference in amplitude of the mutants PRC (Type I). The rhythm is more sensitive to the light intensity, becoming obscure in darker condition. Toki interacts with other clock mutations, pers, perL and And, in such a way that tau s associated with these three X-linked mutations are lengthened and phi values become smaller.

Novel tissue units of regional differentiation in the gut epithelium of Drosopbila, as revealed by P-element-mediated detection of enhancer

We analysed spatial patterns of expression of a lacZ reporter gene in the gut of Drosophila larvae that had been transformed with a P-element-lacZ vector to identify regional differences in gene expression. lacZ-positive epithelial cells formed distinct domains with discrete transverse and longitudinal boundaries along the gut tube. Boundaries were often found at sites at which morphological boundaries were not obvious. The gut epithelium was subdivided into 36 compartments by the boundaries. We refer to these novel compartments as “tissue compartments”. The lacZ-positive domain of each strain appeared as a single tissue compartment or as a combination of several tissue compartments. The tissue compartment is considered to be a unit of regional differentiation. The spatial organization of the tissue compartments may represent the “floor plan”, determined by genes that control the regional differentiation of this nonsegmental organ.

Hedonic Taste in Drosophila Revealed by Olfactory Receptors Expressed in Taste Neurons

Taste and olfaction are each tuned to a unique set of chemicals in the outside world, and their corresponding sensory spaces are mapped in different areas in the brain. This dichotomy matches categories of receptors detecting molecules either in the gaseous or in the liquid phase in terrestrial animals. However, in Drosophila olfactory and gustatory neurons express receptors which belong to the same family of 7-transmembrane domain proteins. Striking overlaps exist in their sequence structure and in their expression pattern, suggesting that there might be some functional commonalities between them. In this work, we tested the assumption that Drosophila olfactory receptor proteins are compatible with taste neurons by ectopically expressing an olfactory receptor (OR22a and OR83b) for which ligands are known. Using electrophysiological recordings, we show that the transformed taste neurons are excited by odor ligands as by their cognate tastants. The wiring of these neurons to the brain seems unchanged and no additional connections to the antennal lobe were detected. The odor ligands detected by the olfactory receptor acquire a new hedonic value, inducing appetitive or aversive behaviors depending on the categories of taste neurons in which they are expressed i.e. sugar- or bitter-sensing cells expressing either Gr5a or Gr66a receptors. Taste neurons expressing ectopic olfactory receptors can sense odors at close range either in the aerial phase or by contact, in a lipophilic phase. The responses of the transformed taste neurons to the odorant are similar to those obtained with tastants. The hedonic value attributed to tastants is directly linked to the taste neurons in which their receptors are expressed.