 |
||||
|
||||
|
||||
|
||||
|
||||
Previous Article | Next Article
The Journal of Neuroscience, May 1, 2000, 20(9):3425-3433
The Genetic Variant Voila1 Causes Gustatory Defects during Drosophila Development
Maria Balakireva1, Nanaë Gendre2, Reinhard F. Stocker2, and Jean-François Ferveur3 1 Centre des Sciences du Goût, 21 000 Dijon, France, 2 Department of Biology and Program in Neuroscience, University of Fribourg, CH-1700 Fribourg, Switzerland, and 3 Unité de Recherche 5548 Associée au Centre National de la Recherche Scientifique, Faculté des Sciences, Université de Bourgogne, 21 000 Dijon, France
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Voila1, an enhancer-trap strain in Drosophila melanogaster, expresses GAL4 in most gustatory neurons, both before and after metamorphosis. Voila1 expression starts at embryonic stage 10. In the periphery, it labels larval gustatory sensilla in the antennomaxillary complex as well as in the pharynx. GAL4 is also expressed in the CNS in a manner that prefigures expression in adult flies. Most Voila1/1 homozygotes die between second larval instar and early adulthood. Moreover, escaping Voila1/1 larvae do not show gustatory responses to NaCl and sucrose. The simultaneous rescue of normal larval gustation together with adult viability after removal of the transposable PGAL4 element suggests that both these phenotypes are caused by the same inserted element.
Key words: Drosophila; taste; gustatory nervous system; development; larval behavior; enhancer-trap PGAL4 strain
INTRODUCTION
The study of the taste sensory system requires the availability of a reliable behavioral phenotype (or phenotypes) related to the genetic alteration of a restricted number of neurons. In the fruit fly Drosophila melanogaster, the recent engineering of PGAL4 enhancer-trap strains expressed in a specific subset of neurons (Brand and Perrimon, 1993
) has made it possible to begin unraveling the function of neurons by studying behavior in parallel with genetic misexpression (Ferveur et al., 1995
The major components of the chemosensory system of Drosophila larvae are the dorsal organ (DO), the terminal organ (TO), and a number of pharyngeal sensilla (for review, see Stocker, 1994
During metamorphosis of holometabolous insects, most of the larval motor neurons and many interneurons persist and combine with new imaginal neurons to form the adult CNS (Truman et al., 1993
Similarly, we show here that the Voila1-PGAL4 strain, which was found to express GAL4 specifically in adult taste sensilla (Balakireva et al., 1998
MATERIALS AND METHODS
Fly stocks and genetics. Strains were kept at 25°C (unless otherwise noted) in a 12 hr dark/light cycle on standard cornmeal food. A description of the chromosomes and mutations used in this study can be found in Lindsley and Zimm (1992)
Complementation analysis of Voila1 was performed with a set of deficiencies uncovering the chromosomal region 86C-87C [for breakpoints and origin, see Reuter et al. (1987)
Derivative lines of Voila1 were produced according to the standard procedure (Cooley et al., 1988
2-3 chromosome (Robertson et al., 1988
male was used to establish a derivative line containing an independent Voila excision event (Voilaexc) balanced over the TM3, Sb Ser chromosome (the white eye color indicates that at least the part of the PGAL4 transposon containing the w+ minigene sequence has been excised from the genome of the Voila1 strain).
Developmental lethality. For measuring developmental lethality, eggs were collected for a period of 24 hr at 25°C (for experiments performed at 25 and 29°C) or at 20°C (for experiments at 20°C) and deposited in vials at the experimental temperature. Thirty to forty hours after the end of egg-laying, the number of dead embryos was counted. Strains carrying a balancer chromosome are expected to yield an average of 25% dead embryos (homozygous for the balancer chromosome). Adults emerging from the pupal case were counted according to their genotype (nA), and the frequency of adult survival was estimated relative to the number of surviving embryos (nA/nE). The frequency of lethality during pupal life was also directly measured (nP/nE). The occurrence of lethality during larval stages is thus the difference between the number of hatching embryos minus the number of individuals that reach (and die during) pupariation and adulthood (nL = nE
[nP + nA]).
The respective lethality of both homozygous and heterozygous Voila1 genotypes was assessed with the dominant marker Tubby (Tb) carried on the balancer chromosome TM6C, Sb Tb. The Tb marker makes it possible to distinguish both genotypes during larval and pupal stages. The lethality of the different adult genotypes was based on our estimation carried out with both Voila1/TM3 and Voila1/TM6 strains. A similar protocol was used to estimate the lethality of flies carrying derivative Voilaexc chromosomes or deficiencies.
Food renewal was performed by transferring first instar larvae (once) on fresh food medium. For all experiments, the number of larvae was roughly controlled (200-300) to prevent competition for food resources.
Gustatory tests. Petri dishes divided into halves (Falcon 1003) were filled with 1% agarose/water (control) and 1% agarose/test solution (test) on opposite halves (Heimbeck et al., 1999
The RI values were relatively stable between 15 and 60 min of the test period. This is the reason why we have shown the RI values that were yielded after 30 min. However, the RI values toward sucrose that were very significantly different between strains at 15 min are also described in Results. We used two-way ANOVA to compare the difference between our data that were normally distributed within most samples (for each genotype, for a given concentration, and time of observation). Statistical significance was tested with least significant difference and Newman-Keuls post hoc tests.
Reporter gene expression. Voila1/TM6 was crossed with either UAS-lacZ (Brand and Perrimon, 1993
-galactosidase, embryos were stained with X-Gal according to Ghysen and O'Kane (1989)
For visualization of GFP through the confocal microscope, larvae and pupae were dissected in Drosophila Ringer's solution and fixed in 4% paraformaldehyde [for details, see Laissue et al. (1999)
RESULTS
Preimaginal lethality
The PGAL4 enhancer trap line Voila1, which was isolated in a screen for expression in the adult chemosensory system, yielded only viable heterozygous adult flies (Voila1/+). Voila 1/1 exhibited developmental lethality at various stages (see below). Furthermore, homozygous Voila1 larvae and pupae remained much smaller than Voila1/+ or wild-type genotypes (Fig. 1). We do not know yet whether this effect is caused by starvation. We have not noted obvious abnormal movements, digging, or feeding behaviors of mutant larvae.
View larger version (86K):[in this window]
[in a new window]
Figure 1. A, B, Homozygous Voila1/1 larvae and pupae (left side in each panel) are significantly smaller than the corresponding wild-type stages (right side). A, Third instar larvae. B, Pupae after head eversion.
The lethality of Voila 1/1 homozygotes was clearly postembryonic: individuals died between the second larval instar and the late pupal stage. The developmental lethality that occurred during embryonic, larval, pupal, and early imaginal stages was measured by counting the frequency of individuals surviving at the end of each of these developmental phases. The Voila 1/1 genotype showed a highly reproducible pattern of lethality during development (Fig. 2A).
View larger version (17K):[in this window]
[in a new window]
Figure 2. A-C, Cumulative lethality during different phases of development of (A) homozygous Voila1/1 in various environmental conditions and (B, C) of various genotypes. A, Effect of temperature and food quality on the lethality rate for Voila1/1 genotype. B, Complementation analysis of Voila1 with different genetic deficiencies. Deficiencies shown above the graph are aligned with the salivary gland chromosome map (Lindsley and Zimm, 1992
Temperature and feeding conditions, but not genetic background, affect developmental lethality
At 25°C, ~83% of Voila 1/1 homozygotes died before reaching puparium formation (Fig. 2A). We tested the influence of different genetic backgrounds (each one including a different balancer for chromosome 3: TM3, Sb Ser, or TM6, Ubx, or TM6C, Sb Tb). At 25°C, the lethality profile between these three strains showed only slight quantitative variations: 5-12% of individuals died during pupal life, and the 5-12% of adult escapers (of both sexes) died during their first 2 d of adult life (data not shown). The surviving imagoes had difficulties standing up and therefore showed no visible locomotor activity.
We also tested the influence of temperature and food on developmental lethality. When the developmental temperature was either shifted down to 20°C or raised to 29°C, no Voila1/1 adult flies eclosed (Fig. 2A). In both cases, the percentage of dying larvae increased dramatically (95-98%); 25°C is thus the most favorable temperature for prolonging the survival of Voila1/1 homozygotes. Food quality also largely influenced the lethality profile (Fig. 2A). Larvae that were transferred to fresh food medium during their first instar showed an increased probability of reaching puparium formation (43%) as compared with siblings held on the same medium throughout larval development (17%). As a consequence, the larvae that were raised on renewed food more frequently yielded adult flies (38%) than larvae held on unchanged medium (12%). Nevertheless, no Voila1/1 imago survived for more than 48 hr, regardless of rearing conditions.
For the rest of our study and to standardize our measurements, these experimental conditions were kept constant. Strains were always raised at 25°C and held on the same food medium during their entire preimaginal development.
Genetic mapping of developmental lethality
Voila1 was originally mapped to chromosome 3, at 86E1-2 (Balakireva et al., 1998
The second genetic experiment was performed to rescue adult viability by remobilizing the PGAL4 transposon. Each remobilization event was subsequently maintained in a Voilaexc strain. We obtained 61 Voilaexc strains, each of which was characterized for the profile of developmental lethality of its homozygous Voilaexc/exc flies (M. Balakireva, unpublished data). Out of these Voilaexc strains, adult viability was completely rescued in 35 cases (viable strains = Voilaexc-Vb lines). Data are shown for the Voila23 and Voila57 strains that exhibited mortality curves that were very similar to that of the control CS strain (Fig. 2C). This rescue indicates that the PGAL4 transposon is responsible for the developmental lethality of Voila1/1 homozygotes.
Remobilization can often yield imprecise excisions of the transposon, thus producing new alleles at the same locus (Wilson et al., 1989
Gustatory defects in Voila larvae tested with sodium chloride
Voila1/1 and Voila1/TM3 larvae were compared with larvae from the control strain (CS) and with homozygous larvae from two Voilaexc-Vb (Voila23/23 and Voila57/57) strains with rescued developmental viability. Gustatory responses after 30 min were measured as RI, which indicates the relative number of larvae choosing agar mixed with the test solution versus neutral agar (see Materials and Methods).
Voila1/1 homozygotes showed RI values that were significantly different from the four other genotypes (0.00001 < p < 0.019; except for both Voilaexc-Vb strains at 0.1 M). The values shown on Figure 3A indicate that Voila1/1 larvae are unable to choose between neutral agar and agar mixed with NaCl, at the three concentrations tested here. Conversely, larvae of all other genotypes were clearly repelled by the higher concentration (0.5-0.3 M) of salt. Interestingly, both Voilaexc-Vb strains of larvae showed RI values that were similar to the RI values of the CS control genotype. Furthermore, Voila1/TM3 showed RI values that were significantly different from both Voilaexc-Vb strains (p = 0.002-0.007) at 0.5 M. If RI values were relatively stable during the entire 60 min test period for most data points, Voilaexc-Vb
but not Voila1/TM3 heterozygotes and CS
View larger version (18K):[in this window]
[in a new window]
Figure 3. A, B, Mean (and SE) of larval gustatory responses in tests involving different concentrations of NaCl (A) and sucrose (B). For each test, ~50 second instar larvae were put in the middle of a Petri dish that was divided into two halves containing either neutral agar or agar mixed with the substance to be tested. The numbers of larvae present on each side were noted after 30 min. The response index represents their relative number on each side. Larvae that did not move from the starting point were not taken into account (see Materials and Methods). The dashed line represents indifference (RI = 0); negative RI values on the y-axis represent repulsion, and positive values represent attraction. Each data point represents the mean of 5-16 replicate experiments. Two-way ANOVA revealed a significant effect of genotype and concentration for NaCl and sucrose (respectively, df = 113 and 132; Fgenotype = 21.28 and 6.29; Fconcentration = 16.25 and 14.50; 0.000001 < p < 0.0001), but not of their interaction (F = 1.68 and 1.72; p = 0.10-0.11).
These results show that Voila1/1 larvae are impaired for their response to salt because, unlike the four other genotypes, they cannot discriminate between NaCl mixed with agar and neutral agar. The PGAL4 transposon is clearly responsible for the gustatory defect of Voila1/1 larvae because homozygous larvae of both Voilaexc-Vb strains showed rescued RI values in response to NaCl. Gustatory indifference to salt appears to be recessively controlled by the mutation. However, Voila1/TM3 larvae seem to be more sensitive to 0.5 M NaCl than the larvae from the three other strains. This effect is not caused by the TM3 balancer because TM3/+ larvae did not show abnormal gustatory response (data not shown).
Gustatory behavior toward sucrose
The tests performed with 0.1-0.5 M sucrose suggest that Voila1/1 larvae are barely attracted toward this substance (Fig. 3B). In contrast to the data obtained with NaCl (see above), few significant differences were noted between Voila1/1 and larvae of other genotypes (with Voila1/TM3, at 0.5 M: p = 0.011; and with CS, at 0.1 M: p = 0.036). In contrast, heterozygous Voila1/TM3 larvae showed very contrasted responses depending on the dose of sucrose: they were repelled by 0.5 M and yielded significant difference with CS and both Voilaexc-Vb strains (0.00001 < p < 0.002). Voila1/TM3 larvae were indifferent at 0.3 M sucrose, and their RI values were still significantly lower than that obtained with both Voilaexc-Vb strains (p = 0.001-0.014).
After 15 min of test, significant differences were noted between Voila1/1 and the four other genotypes at 0.1 M (0.00001 < p < 0.006), and with both Voilaexc-Vb strains at 0.3 M (p = 0.0001). On the other hand, Voila1/TM3 showed a slight difference with CS at 0.5 M (p = 0.041) but more substantial difference with both Voilaexc-Vb strains at 0.3 and 0.5 M (0.00001< p < 0.006). If the gustatory defect of Voila1/1 larvae on sucrose was not as strong as that observed with NaCl, the reaction of heterozygote Voila1/TM3 larvae was more spectacular (if compared with the other genotypes), especially after 30 min of test. The strong aversive response noted with 0.5 M was likely caused by a single copy of Voila1 because TM3/+ larvae were slightly attracted by that concentration of sucrose (data not shown).
Embryonic expression of Voila1
To better understand the developmental lethality and the lack of gustatory discrimination in Voila1/1 larvae, we studied the developmental expression of the PGAL4 line Voila1, using lacZ and GFP reporter products for visualization.
Embryonic lacZ expression in Voila1 was observed for the first time at stage 10, when the stomodeum invaginates (cf. Campos-Ortega and Hartenstein, 1985
View larger version (129K):[in this window]
[in a new window]
Figure 4. A-F, Embryonic expression pattern of Voila1 visualized by the lacZ reporter. A, B, At embryonic stage 10, staining appears in the entire germ band, with a strongly expressing cluster of cells in the head region (arrowheads). C, At stage 11, large neuroblast-like cells (arrowheads) are seen in each segment. D, E, At subsequent stages (D, stage 13; E, stage 14), strong label appears at three sites: in the CNS, in a segmental, dorsoventral stripe of cells (arrowheads), probably part of the PNS, and in twin spots at the anterior tip of the head (arrows), very likely the precursors of the antennomaxillary complex. F, At stage 16, staining intensity in the CNS begins to fade. Scale bar, 50 µm.
Larval expression
Reporter gene expression in second and third instar larvae of Voila1 was restricted almost exclusively to chemosensilla and CNS elements. In the periphery, label resided in the AMC and an anterior and a posterior group of pharyngeal gustatory sensilla (Fig. 5A,D). In the AMC, dendritic staining extended to the cuticular portion of the gustatory TO (Fig. 5B,E,F), suggesting that expression is neuronal. Label was particularly strong in the dorsolateral group of TO sensilla, the afferents of which reach the brain via the larval antennal nerve (Fig. 5E) (Kankel et al., 1980
View larger version (189K):[in this window]
[in a new window]
Figure 5. A-H, Larval Voila1 expression pattern shown with lacZ (A-E, H) and GFP reporters (F, G). A-C, Second larval instar. Expression is seen in the antennomaxillary complex (A, amc) and in an anterior and posterior group of pharyngeal sensilla (A, ap, pp). In the AMC, dendritic staining extends to the gustatory terminal organ (B, to) but not the olfactory dorsal organ (B, do). Intense labeling occurs in the mushroom bodies (C, arrowheads; lobes, arrow) and in additional scattered cells in the brain and ventral nerve cord. D-H, Third larval instar. Peripheral expression is similar as in second instar (D). Neurons are labeled exclusively in the terminal organ (E, F), including the so-called dorsolateral group of sensilla (E, arrowhead), but not in the dorsal organ. Massive staining occurs in the mushroom bodies (G, arrowheads;
Larval GAL4 expression was present also in the brain, subesophageal ganglion (SOG), and ventral nerve cord (Fig. 5C,G,H). In the brain, massive expression occurred in the mushroom bodies. The pattern consisted of a large cluster of cells in the dorsal hemispheres, presumably Kenyon cells, and of several distinctive tracts, such as the pedunculus and the
and
Pupal expression
Expression in the developing adult peripheral nervous system (PNS) was first observed at puparium formation in leg imaginal disks (Fig. 6A). The pattern consisted of two distal clusters of cells with axonal processes. From 2 hr after puparium formation (APF), these processes assembled in two nerves in the elongating leg (Fig. 6B,C). In the wing disk, initial expression was seen at 8 hr APF in evenly spaced cell clusters at the anterior wing margin (Fig. 6D). At 16 hr APF, the clusters were clearly revealed as wing sensilla, characterized by dendritic-like processes. The clusters coincided with the known pattern of approximately 30 chemosensilla on the dorsal triple row and approximately 12 chemosensilla on the ventral triple row (cf. Stocker, 1994
View larger version (90K):[in this window]
[in a new window]
Figure 6. A-F, Confocal images of early pupal Voila1/UAS-GFP expression pattern. A, At puparium formation, expression appears in the third leg disks in two distal clusters of cells (arrowheads) with axon-like processes (arrow). B, At 2 hr APF, two nerves are visible in the elongating leg (arrowheads). C, At 4 hr APF, leg segmentation begins (arrowheads). D, In wing disks, initial expression is seen at 8 hr APF in regularly spaced groups of cells along the anterior margin (arrowheads). E, At 16 hr APF, the clusters of cells are clearly revealed as wing sensilla. Their distribution coincides with the adult pattern of approximately 30 chemosensilla on the dorsal triple row (arrowheads) and approximately 12 chemosensilla on the ventral triple row (arrows). F, At 24 hr APF, the strong staining pattern in legs (arrowheads) and wings (arrows) is reminiscent of the pattern of chemosensilla. Scale bar, 100 µm.
View larger version (109K):[in this window]
[in a new window]
Figure 7. A-D, Voila1/UAS-lacZ expression pattern 24 hr after puparium formation. In legs (A), wings (B), and labial palps (C), strong expression is seen in developing gustatory sensilla (arrowheads) and afferent nerves (arrows). In the legs, strongly and moderately stained elements can be distinguished. For example, in the metathoracic leg shown in A, approximately 10 intensely labeled cell clusters are present in the two distalmost tarsal segments (left), corresponding to known numbers of taste bristles. In addition, future mechanosensory bristles exhibit moderate expression (arrowhead). On the wing margin (B), approximately 40 bristle sensilla are intensely stained (arrowhead), reflecting the numbers of adult taste bristles. Weak expression is also present in certain wing veins (B, asterisk) and in the fat body of the palps (C, asterisks). D, The entire second and third antennal segments (open and filled circles, respectively) are strongly labeled. The transient staining of nerves between the antennal segments (arrowheads) and toward the brain (arrows) suggests that at least some olfactory neurons express GAL4 at this stage. Scale bar, 100 µm.
Massive expression occurred also in the developing labial palps and antennae. At 24 hr APF, all prospective taste bristles in the labial palps, including their afferent nerves, were stained (Fig. 7C). This pattern is identical to the expression in adult palps (Balakireva et al., 1998
DISCUSSION
Reporter gene expression
The expression pattern of Voila1 is almost identical when comparing lacZ and GFP reporter labels, suggesting that the pattern described here includes all cells that express GAL4 in significant amounts. The most striking attribute of Voila1 expression in the PNS is its almost complete restriction to gustatory sensilla (for exceptions, see below). This applies to larval and pupal life as well as to the adult stage (Balakireva et al., 1998
Invariable staining of dendritic and axonal portions in these sensilla shows that GAL4 expression is neuronal, although additional expression in sheath cells cannot be excluded. The intensity of staining in the TO as well as in leg and wing chemosensilla suggests that most, if not all, of the receptor neurons comprising these sensilla express GAL4. However, a small subset of known or suspected taste sensilla remain unlabeled, for example the ventral organ in the larva (Chu-Wang and Axtell, 1972
In addition to taste sensilla, a number of other sensilla express GAL4 in Voila1, such as the larval DO, mechanosensory bristles during leg formation, olfactory sensilla in the developing antenna, and a few wing campaniform sensilla. However, except in the latter two cases, these elements do not exhibit axonal labeling, which suggests an expression in sheath cells rather than neurons. Alternatively, low level neuronal GAL4 expression remains possible even in nongustatory sensilla. It will be interesting to combine Voila1 with mutant genes involved in the specification of the sensory system [such as poxn (Nottebohm et al., 1994
GAL4 expression in sensory neurons begins very early during differentiation. For example, in leg disks, expression in two distal clusters of neurons and in corresponding nerves extending toward the leg base is already visible at pupariation. This pattern is reminiscent of a set of premetamorphic neurons that may serve as afferent pioneers (Jan et al., 1985
In conclusion, with the exception of a few wing campaniform sensilla (see above), the only mature sensilla that show neuronal expression in Voila1 are gustatory. In mature olfactory sensilla on the antenna and maxillary palp, GAL4 expression appears to be localized in sheath cells or glial cells (or in neurons at low levels). This spatiotemporal pattern of expression suggests a bifunctional neuronal role of an underlying gene or genes, apart from possible roles in associated cells. On the one hand, such a gene may be involved in the maturation of gustatory and olfactory neurons, and on the other it may directly assist in gustation. The latter role is convincingly demonstrated by the recessive gustatory mutant effects of Voila1 and is further supported by dominant courtship effects that may be caused by defects in pheromonal detection (Balakireva et al., 1998
The CNS expression of Voila1 is widespread, and it remains unclear whether the labeled neural tissues correspond to taste function. In the larval CNS, the structures that show the strongest expression include the mushroom bodies, the SOG, and the ventral ganglia. Interestingly, adult flies show a particularly strong expression in the same three structures. It is possible that part of the larval and adult CNS staining corresponds to the primary projection of gustatory afferents, yet the widespread GAL4 expression prevented us from further analyzing Voila1 patterns at that level.
Possible function of Voila in gustation during development
Among the Drosophila chemosensory mutants that have been described, the great majority exhibit olfactory defects. In some cases, olfactory anomalies have been shown to affect both larval and adult development (Carlson, 1996
We previously hypothesized that the hyperexcitability observed in adult heterozygous Voila1/TM3 males was caused by defective expression of Voila in a neural center (mushroom bodies), whereas the ectopic expression of the UAS-transformer transgene in the gustatory sensory neurons was responsible for altered male pheromonal perception (Balakireva et al., 1998
The fact that remobilization of PGAL4 simultaneously rescued larval gustation and adult viability suggests that both anomalies are caused by the same transposon. We are currently investigating the causal relation between both phenotypes. Two preliminary observations support a causal link: (1) the reduced size of Voila1/1 larvae and pupae (Fig. 1), which could be caused by abnormal gustation and starvation of homozygous wandering larvae, and (2) their frequency of reaching, but not of surviving, during adulthood that can be slightly increased by selecting more favorable environmental conditions (25°C, transfer to fresh food). Cloning and characterization of the gene(s) responsible will help elucidate the correct hypothesis.
The fact that the different Voilaexc-Lt strains exhibit very different patterns of developmental lethality suggests that Voila has a complex effect, rather than an all-or-none function, on survival during development. After the genetic approach presented here, we are currently performing the molecular dissection of the Voila locus with a set of Voilaexc strains. Preliminary data indicate that rescue of developmental defects does not overlap with the rescue of behavioral anomalies observed in adult male flies (Y. Grosjean, M. Balakireva, and J-F. Ferveur, unpublished observations). It will be very interesting to determine whether preimaginal and adult phenotypes are encoded and regulated by different molecular sequences. However, several Voilaexc-Lt strains that were surveyed for their GAL4 pattern of expression did not show any qualitative difference, although changes in intensity cannot be formally excluded (N. Gendre and R. Stocker, unpublished observations).
This study shows that the Voila1 strain is very useful for specifically manipulating taste sensory organs during preimaginal development because of its limited GAL4 expression in the periphery. New PGAL4 strains make it possible to manipulate different subsets of chemosensory neurons in living larvae and flies (Heimbeck et al., 1999
FOOTNOTES Received Oct. 27, 1999; revised Feb. 1, 2000; accepted Feb. 17, 2000.
This work was supported by grants from the Human Frontier Science Program (RG-93/94 B) to J.F.F. and R.S., from the Burgundy Region to M.B., and from the Swiss National Funds (31-42053.94 and 31-52639.97) to R.S. We are very grateful to Dr. Gertrud Heimbeck for help with embryonic staging, to Yaël Grosjean for unpublished data, and to Laurence Dartevelle for technical help. Christine Dambly-Chaudière, Matthew Cobb, and two anonymous reviewers are thanked for their comments on this manuscript.
M.B. and N.G. contributed equally to this work.
Correspondence should be addressed to Jean-François Ferveur, Unité de Recherche 5548 Associée au Centre National de la Recherche Scientifique, Faculté des Sciences, Université de Bourgogne, 6 Boulevard Gabriel, 21 000 Dijon, France. E-mail: jean-francois.ferveur{at}u-bourgogne.fr.
REFERENCES
- Ashburner M (1989) In: Drosophila. A laboratory manual. Cold Spring Harbor, NY: Cold Spring Harbor Laboratory.
- Ayer R, Carlson J (1991) acj6: a gene affecting olfactory physiology and behavior in Drosophila. Proc Natl Acad Sci USA 88:5467-5471
[Abstract/Free Full Text] .- Balakireva M, Stocker RF, Gendre N, Ferveur JF (1998) Voila, a new Drosophila courtship variant that affects the nervous system: behavioral, neural and genetic characterization. J Neurosci 18:4335-4343
[Abstract/Free Full Text] .- Balmer D (1994) In: Isolation von zellspezifisch exprimierenden Gal4-Insertionslinien bei Drosophila melanogaster, unter besonderer Berücksichtigung des chemosensorischen Systems. Diploma thesis University of Fribourg.
- Brand AH (1995) GFP in Drosophila. Trends Genet 11:324-325[Web of Science][Medline].
- Brand AH, Perrimon N (1993) Targeted gene expression as a means of altering cell fates and generating dominant phenotypes. Development 118:401-415[Abstract].
- Busto M, Iyengar B, Campos AR (1999) Genetic dissection of behavior: modulation of locomotion by light in the Drosophila melanogaster larva requires genetically distinct visual system functions. J Neurosci 19:3337-3344
[Abstract/Free Full Text] .- Campos-Ortega JA, Hartenstein V (1985) In: The embryonic development of Drosophila melanogaster. New York: Springer.
- Carlson JR (1996) Olfaction in Drosophila: from odor to behavior. Trends Genet 12:175-180[Web of Science][Medline].
- Chu-Wang IW, Axtell RC (1972) Fine structure of the ventral organ of the house fly larva, Musca domestica L. Z Zellforsch 130:489-495[Web of Science][Medline].
- Clyne PJ, Certel SJ, de Bruyne M, Zaslavsky L, Johnson WA, Carlson JR (1999) The odor specificities of a subset of olfactory receptor neurons are governed by acj6, a POU-domain transcription factor. Neuron 22:339-347[Web of Science][Medline].
- Connolly JB, Roberts IJH, Armstrong JD, Kaiser K, Forte M, Tully T, O'Kane CJ (1996) Associative learning disrupted by impaired GS signaling in Drosophila mushroom bodies. Science 274:2104-2107
[Abstract/Free Full Text] .- Cooley L, Kelley R, Spradling A (1988) Insertional mutagenesis of the Drosophila genome with single P elements. Science 239:1121-1128
[Abstract/Free Full Text] .- Cubitt AB, Heim R, Adams SR, Boyd AE, Gross LA, Tsien RY (1995) Understanding, improving and using green fluorescent proteins. Trends Biochem Sci 20:448-455[Web of Science][Medline].
- Deak P, Omar MM, Saunders RD, Pal M, Komonyi O, Szidonya J, Maroy P, Zhang Y, Ashburner M, Benos P, Savakis C, Siden-Kiamos I, Louis C, Bolshakov VN, Kafatos FC, Madueno E, Modolell J, Glover DM (1997) P-element insertion alleles of essential genes on the third chromosome of Drosophila melanogaster: correlation of physical and cytogenetic maps in chromosomal region 86E-87F. Genetics 147:1697-1722[Abstract].
- Falk R, Atidia J (1975) A mutation affecting taste perception in Drosophila melanogaster. Nature 254:325-326[Medline].
- Ferveur JF, Störtkuhl KF, Stocker RF, Greenspan RJ (1995) Genetic feminization of brain structures and changed sexual orientation in male Drosophila melanogaster. Science 267:902-905
[Abstract/Free Full Text] .- Ghysen A, O'Kane C (1989) Neural enhancer-like elements as specific cell markers in Drosophila. Development 105:35-52[Abstract].
- Hartenstein V (1993) In: Atlas of Drosophila development. Cold Spring Harbor, NY: Cold Spring Harbor Laboratory.
- Heimbeck G, Bugnon V, Gendre N, Häberlin C, Stocker RF (1999) Smell and taste perception in Drosophila melanogaster larva: toxin expression studies in chemosensory neurons. J Neurosci 19:6599-6609
[Abstract/Free Full Text] .- Isono K, Kikuchi T (1974) Autosomal recessive mutation in sugar response of Drosophila. Nature 24:243-244.
- Jan YN, Jan LY (1993) The peripheral nervous system. In: The development of Drosophila melanogaster (Bate M, Martinez Arias A, eds), pp 1207-1244. Cold Spring Harbor, NY: Cold Spring Harbor Laboratory.
- Jan YN, Ghysen A, Barbel CI, Jan LY (1985) Formation of neuronal pathways in the imaginal discs of Drosophila melanogaster. J Neurosci 5:2453-2464[Abstract].
- Kankel DR, Ferrus A, Garen SH, Harte PJ, Lewis PE (1980) The structure and development of the nervous system. In: The genetics and biology of Drosophila, Vol 2 (Ashburner M, Wright TRF, eds), pp 295-368. New York: Academic.
- Laissue PP, Reiter C, Hiesinger PR, Halter S, Fischbach KF, Stocker RF (1999) Three-dimensional reconstruction of the antennal lobe in Drosophila melanogaster. J Comp Neurol 405:543-552[Web of Science][Medline].
- Lindsley DL, Zimm GG (1992) In: The genome of Drosophila melanogaster. New York: Academic.
- McKenna M, Monte P, Helfand S, Woodard C, Carlson J (1989) A simple chemosensory response in Drosophila and the isolation of acj mutants in which it is affected. Proc Natl Acad Sci USA 86:8118-8122
[Abstract/Free Full Text] .- Meinertzhagen IA, Hanson TA (1993) The development of the optic lobe. In: The development of Drosophila melanogaster (Bate M, Martinez Arias A, eds), pp 1363-1492. Cold Spring Harbor, NY: Cold Spring Harbor Laboratory.
- Murray MA, Schubiger M, Palka J (1984) Neuron differentiation and axon growth in the developing wing of Drosophila melanogaster. Dev Biol 104:259-273[Web of Science][Medline].
- Nayak SV, Singh RN (1983) Sensilla on the tarsal segments and mouth parts of adult Drosophila melanogaster Meigen (Diptera: Drosophilidae). Int J Insect Morphol Embryol 12:273-291.
- Nottebohm E, Usui A, Therianos S, Kimura KI, Dambly-Chaudière C, Ghysen A (1994) The gene poxn controls different steps of the formation of chemosensory organs in Drosophila. Neuron 12:25-34[Web of Science][Medline].
- Oppliger FY, Guerin PM, Vlimant M (2000) Neurophysiological and behavioural evidence for an olfactory function for the dorsal organ and a gustatory one for the terminal organ in Drosophila melanogaster larvae. J Insect Physiol 46:135-144[Web of Science][Medline].
- Reuter G, Gausz J, Gyurkovics H, Friede B, Bang R, Spierer A, Hall LMC, Spierer P (1987) Modifiers of position-effect variegation in the region from 86C to 88B of the Drosophila melanogaster third chromosome. Mol Gen Genet 210:429-436[Medline].
- Riesgo-Escovar J, Woodard C, Gaines P, Carlson J (1992) Development and organization of the Drosophila olfactory system: an analysis using enhancer traps. J Neurobiol 23:947-964[Web of Science][Medline].
- Robertson HM, Preston CR, Phillis RW, Johnson-Schiltz DM, Benz WK, Engels WR (1988) A stable source of P-element transposase in Drosophila melanogaster. Genetics 118:461-470
[Abstract/Free Full Text] .- Rodrigues V, Cheah PY, Ray K, Chia W (1995) malvolio, the Drosophila homologue of mouse NRAMP-1 (Bcg), is expressed in macrophages and in the nervous system and is required for normal taste behavior. EMBO J 14:3007-3020[Web of Science][Medline].
- Singh RN, Singh K (1984) Fine structure of the sensory organs of Drosophila melanogaster Meigen larva (Diptera: Drosophilidae). Int J Insect Morphol Embryol 13:255-273.
- Stocker RF (1994) The organization of the chemosensory system in Drosophila melanogaster: a review. Cell Tissue Res 275:3-26[Web of Science][Medline].
- Sweeney ST, Broadie K, Keane J, Niemann H, O'Kane CJ (1995) Targeted expression of tetanus toxin light chain in Drosophila specifically eliminates synaptic transmission and causes behavioral defects. Neuron 14:341-351[Web of Science][Medline].
- Tix S, Bate M, Technau GM (1989) Pre-existing neuronal pathways in the leg imaginal discs of Drosophila. Development 107:855-862
[Abstract/Free Full Text] .- Tompkins L, Cardosa M, White FV, Sanders TG (1979) Isolation and analysis of chemosensory behavior mutant in Drosophila melanogaster. Proc Natl Acad Sci USA 76:884-887
[Abstract/Free Full Text] .- Truman JW, Taylor BJ, Awad TA (1993) Formation of the adult nervous system. In: The development of Drosophila melanogaster (Bate M, Martinez Arias A, eds), pp 1245-1276. Cold Spring Harbor, NY: Cold Spring Harbor Laboratory.
- Williams DW, Shepherd D (1999) Persistent larval sensory neurons in adult Drosophila melanogaster. J Neurobiol 39:275-286[Medline].
- Wilson C, Pearson RK, Bellen HJ, O'Kane CJ, Grossniklaus U, Gehring WJ (1989) P-element-mediated enhancer detection: an efficient method for isolation and characterizing developmentally regulated genes in Drosophila. Genes Dev 3:1301-1313
[Abstract/Free Full Text] .- Yeh E, Gustafson K, Boulianne GL (1995) Green fluorescent protein as a vital marker and reporter of gene expression in Drosophila. Proc Natl Acad Sci USA 92:7036-7040
[Abstract/Free Full Text] .
Copyright © 2000 Society for Neuroscience 0270-6474/00/2093425-09$05.00/0
This Article Abstract 
Full Text (PDF) Submit an eLetter Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager 
Citing Articles Citing Articles via Web of Science (7) Citing Articles via Google Scholar Google Scholar Articles by Balakireva, M. Articles by Ferveur, J.-F. Search for Related Content PubMed PubMed Citation Articles by Balakireva, M. Articles by Ferveur, J.-F.
|
|
|
|
 |
|