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Previous Article | Next Article
Volume 17, Number 17, Issue of September 1, 1997 pp. 6745-6760
Copyright ©1997 Society for NeuroscienceSpatial and Temporal Expression of the period and timeless Genes in the Developing Nervous System of Drosophila: Newly Identified Pacemaker Candidates and Novel Features of Clock Gene Product Cycling
Maki Kaneko1, Charlotte Helfrich-Förster2, and Jeffrey C. Hall1 1 Department of Biology, Brandeis University, Waltham, Massachusetts 02254, and 2 Botanisches Institut, 72076 Tübingen, Germany
ABSTRACT
The circadian timekeeping system of Drosophila functions from the first larval instar (L1) onward but is not known to require the expression of clock genes in larvae. We show that period (per) and timeless (tim) are rhythmically expressed in several groups of neurons in the larval CNS both in light/dark cycles and in constant dark conditions. Among the clock gene-expressing cells there is a subset of the putative pacemaker neurons, the "lateral neurons" (LNs), that have been analyzed mainly in adult flies. Like the adult LNs, the larval ones are also immunoreactive to a peptide called pigment-dispersing hormone. Their putative dendritic trees were found to be in close proximity to the terminals of the larval optic nerve Bolwig's nerve, possibly receiving photic input from the larval eyes. The LNs are the only larval cells that maintain a strong cycling in PER from L1 onward, throughout metamorphosis and into adulthood. Therefore, they are the best candidates for being pacemaker neurons responsible for the larval "time memory" (inferred from previous experiments). In addition to the LNs, a subset of the larval dorsal neurons (DNLs) expresses per and tim. Intriguingly, two neurons of this DNL group cycle in PER and TIM immunoreactivity almost in antiphase to the other DNLs and to the LNs. Thus, the temporal expression of per and tim are regulated differentially in different cells. Furthermore, the light sensitivity associated with levels of the TIM protein is different from that in the heads of adult Drosophila.
Key words: larval CNS; period; timeless; pigment-dispersing hormone; pacemaker; circadian; Bolwig's nerve
INTRODUCTION
The period (per) and timeless (tim) genes specify important components of the circadian clock in Drosophila. This is supported by the isolation of arrhythmic as well as period-altered mutants at both the per and tim loci (Konopka and Benzer, 1971
; Sehgal et al., 1994
Regulation of these molecular oscillations is thought to involve transcriptional (Hardin et al., 1992
The adult head has been used as the tissue source for these studies because it controls the best-studied circadian phenotype, the fly's locomotor activity rhythm (Konopka et al., 1983
the lateral neurons (LNs) located between the central brain and the optic lobes (Siwicki et al., 1988
Whereas PER and TIM oscillations are well documented in the adult brains and per expression in the CNS (including the brain hemispheres) of mid to late embryos and pupae has been reported (Liu et al., 1988
Here we demonstrate that the products of per and tim are detectable in a limited number of neurons in the larval CNS; the expression patterns in several such cells is cyclical. Among these neurons five laterally located ones (which seem to be precursors of the aforementioned LNvs) express per from early larval stage through metamorphosis, suggesting that they may be responsible for the larval time memory implied above. In another cluster of larval cells, oscillations of PER and TIM were found to occur almost in antiphase from that in all of the other cells that express per in a cyclical manner
MATERIALS AND METHODS
Strains Flies were grown in a light/dark (LD) cycle of 12 hr L and 12 hr D at 25 or 22°C. A wild-type Canton-S strain, or a white-mutant strain previously made isogenic with Canton-S, were the sources of "clock normal" (per+ tim+) in the anti-PER, anti-TIM, and anti-PDH immunostaining and in the control for endogenous galactosidase activity (described below, used in conjunction with certain transgenic strains). per01 was used as a control for anti-PER immunohistochemistry as well as for the study of TIM cycling in this genetic background. tim01 flies (also carrying the rosy506 eye marker) were used as a control for anti-TIM immunohistochemistry [see Sehgal et al. (1994)
Larvae from transgenic strains involving two different per-lacZ fusion genes, SG and BG, were stained for -galactosidase (
upstream region (5
In addition to the SG strains, we applied another per- Staging of larvae and pupae To obtain L1 individuals of defined age, we collected freshly emerged larvae during a 10 min period in 1 hr intervals. They were allowed to grow until they reached the desired age, and then they were dissected (after 0, 1, 2, 3, 4, 5, 8, 12, 15, and 20 hr). With the use of SG strains, this could be done at any time during the light phase of the LD cycle, because the per-lacZ fusion product is present at a high level throughout the daily cycle (Stanewsky et al., 1997a
To check for chromosomal position effects, we used separate transgenic lines with different chromosomal insertion sites for the SG and BG transgenes: SG3 (chromosome 2) and SG10 (X-chromosome), BG6a (chromosome 2) and BG/TM2 (chromosome 3); the TM2 abbreviation refers to a third chromosomal balancer chromosome, applied here because this particular insert of BG transgene is homozygous lethal. With the exception of BG/TM2, all of the transformants were studied in developing animals homozygous for the transgenes.
In the first method the CNS was fixed for 30 min in 1% glutaraldehyde, subsequently rinsed in phosphate buffer (PB), pH 7.2, for 3 × 5 min, and incubated at 37°C for 5-12 hr in an X-gal staining solution (Simon et al., 1985 Scoring for staining intensities Two methods were used to score the staining intensities. For each, a Zeiss Axiophot microscope (Oberkochen, Germany) equipped with both an epifluorescent and a halogen light source was used. The initial scoring of staining intensity for X-gal histochemistry in L3 was done as follows.
In the second method the larval CNS was fixed in 0.2% glutaraldehyde and 0 or 0.3% Triton X-100 (TX-100) in 100 mM sodium cacodylate, pH 7.3, for 5 min, rinsed in PBS, pH 7.2, plus 0 or 0.1% TX-100 for 3 × 5 min, and incubated for 24 hr at 37°C in X-gal staining solution (0.2% substrate in a buffer containing 0.01 M PB, pH 7.2, 0.15 M NaCl, 1 mM MgCl2, 5 mM potassium ferrocyanide, 5 mM potassium ferrocyanide, and 0.1 or 0.3% TX-100). In this case, X-gal was dissolved in 1:10 volume of dimethyl sulfoxide before being mixed in the staining buffer. After incubation, specimens were washed in a series of concentrations of glycerol (w/v 30, 60, and 90%) in PBS and mounted.
Brains stained at each time point were scored for staining versus nonstaining for each cell cluster in each hemisphere. The percentage of brain hemispheres stained at each cell cluster was plotted against ZT.
Because this scoring method was not done blindly, the scoring method of Stanewsky et al. (1997a)
These two methods gave essentially the same results for BG cycling in per+ and per01 genetic backgrounds. All of the plots shown in Results reflect our application of the second scoring method, as described above. Anti-PER and anti-TIM immunohistochemistry Two different polyclonal antisera against PER, one made in rabbit (Stanewsky et al., 1997a
For scoring the staining intensity in pupal brains (which were stained by the X-gal method), we used an intensity scale of 1-3, because staining method 1 (the more sensitive of the two) gave a smaller range of staining intensities. Otherwise, scoring was done blindly, as described above. Double-labeling X-gal and PDH. X-gal and PDH double-labeling was performed on the L3 CNSs from a BG transgenic line (BG6a) at ZT 0. Anti-PDH antiserum was kindly provided by Dr. Heinrich Dircksen (Rheinische Friedrich-Wilhelms-Universität, Institut für Zoophysiologie, Bonn, Germany). First, X-gal histochemistry was performed as described above (the first such method). After fixation in Zamboni's fixative, PDH immunohistochemistry was performed as described by Helfrich-Förster (1997)
After the fixation the CNS was washed in 0.1% bovine serum albumin and 0.1% TX-100 in PBS (PBT) for 3 × 5 min, permeabilized in PBS containing 1% TX-100 for 10 min, blocked in 5% normal donkey serum (NDS, Jackson ImmunoResearch West Grove, PA) in PBT for >30 min, and incubated in the primary antibody diluted in PBT plus 5% NDS for 48-72 hr. Dilutions for rabbit anti-PER, rat anti-PER, and anti-TIM antisera were 1:15000, 1:2000, and 1:800, respectively. For the PAP staining, the secondary and tertiary antibodies were anti-rat IgG (produced in donkey; Jackson ImmunoResearch), diluted at 1:100, and rat PAP at 1:300 (Jackson ImmunoResearch). For immunofluorescent staining, secondary and tertiary reagents were biotin-SP-conjugated anti-rabbit or rat IgG (produced in donkey; Jackson ImmunoResearch) and fluorescein isothiocyanate (FITC)-conjugated streptavidin, respectively (Jackson ImmunoResearch). They were diluted at 1:200. Secondary antibodies and rat PAP were incubated for 24-48 hr, and FITC-streptavidin was incubated for 12-24 hr. Subsequent to each incubation, the CNS was washed extensively in PBT. For peroxidase color reaction, CNSs were stained for 2-3 min with DAB substrate kit (Vector Laboratories, Burlingame, CA). After the color reaction, brains were dehydrated in ethanol concentration series, cleared in xylene, and mounted in Permount (Fisher Scientific, Pittsburgh, PA). A given fluorescently labeled CNS was mounted with 2% n-propyl gallate in 80% glycerol in PB, pH 7.4. To study subcellular localization, we counterstained immunofluorescently stained samples (by FITC) by propidium iodide before they were mounted (Whitfield et al., 1990
Immunofluorescent double-labeling. Three immunofluorescent double-labeling experiments were performed on the CNS of the L3 animals: anti-
RESULTS
per-Expressing cells in the final larval stage
In CNS specimens from third-instar Drosophila larvae (L3), per expression was determined by X-gal histochemistry and anti-
Fig. 1. Left. CNS expression pattern in third-instar larvae of per-lacZ transgenics (SG) revealed by X-gal histochemistry. The staining pattern for the SG3 line is shown in A and B and for SG10 in C and D. A, Dorsoanterior clusters; this dorsal cluster of labeled neurons could be divided into two subclusters corresponding to PER-immunoreactive DN2L (arrowhead marked by 2) and DN3L (arrowhead marked by 3). Scale bar, 50 µm. B, Staining in the ventral region of the brain is shown on the left hemisphere and the LNs (arrows) on the right. Cells near the midline of the ventral ganglion are stained (large arrow points to the staining in the first thoracic neuromere). Smaller stained clusters in the abdominal neuromeres are out of focus here. Scale bar, same as in A. C, Dorsal clusters; the clusters corresponding to PER-immunoreactive DN2L and DN3L are indicated with arrowheads (marked with 2 and 3, respectively). More cells are stained in this line than in SG3. Cells at the tip of the ventral ganglion are shown as well. Scale bar, 50 µm. D, Focus on the LNs (arrow); stained cells in the ventral region are slightly out of focus in this image; strong staining in the ring gland (filled triangle) and staining in the ventral ganglion (large arrow pointing to the first thoracic neuromere) also are shown. Scale bar, same as in C.
Fig. 2. Right. CNS expression pattern in third-instar larvae of per-lacZ transgenics (BG) revealed by X-gal histochemistry. The staining pattern (for strain BG6a) at ~ZT 23 (1 hr before lights on) is shown in A and B and at ~ZT 12 (the time of lights off) in C and D. A, Only the LNs (arrows) were stained strongly at ZT 23 (1 hr before lights on). B, Higher magnification of the right hemisphere in A. C, Only DN2Ls (arrowheads marked by 2) were stained strongly at ZT 12 (the time of lights off). D, Higher magnification of the left hemisphere in C. Scale bars: 50 µm in A and C; 20 µm in B and D.
[View Larger Version of this Image (94K GIF file)]
Fig. 3. PER- and TIM-immunoreactive cells in the CNS of third-instar larvae. PER-immunoreactive cells at ~ZT 0 (the time of lights on) are shown in A, B, D, and E and at ~ZT 12 in C and F; TIM-immunoreactive cells are shown at ~ZT 21 in G and at ~ZT 10 in H. A, Five PER-immunoreactive LNs are shown in both hemispheres; the right-most LN in the right hemisphere is slightly out of focus; scale bar, 50 µm. B, Weakly stained DNL clusters, DN1L (arrowhead marked by 1), DN2L (arrowheads marked by 2), and DN3L (arrowhead marked by 3); scale bar, same as in A. C, DN2Ls (arrowhead marked by 2) are shown; they are slightly out of focus in the right hemisphere and thus display weaker than in the left hemisphere; scale bar, same as in A. D, Higher magnification of LNs in the right hemisphere in A; scale bar, 20 µm. E, Higher magnification of B; two cells are stained for each of DN1L and DN2L clusters. DN3L seems to be composed of two to three subclusters. Only one of the subclusters of DN3L is in focus here; scale bar, same as in D. F, Higher magnification of the left hemisphere in C; note that DN2Ls are stained more strongly in F than in E; scale bar, same as in D. G, TIM immunoreactivity in DN1L (arrowheads marked by 1), DN2L (arrowheads marked by 2), and LNs (arrows); scale bar, 50 µm. H, DN2L (arrowheads marked by 2) is stained more strongly here than in G; scale bar, same as in G.
[View Larger Version of this Image (122K GIF file)]
Table 1.
Type of cells and tissues SG3 strain SG10 strain % stained No. signals % stained No. signals Dorsoanterior (DNLs) 100 (118a) 3.8 ± 0.1 100 (26a) 9.9 ± 0.3 Dorsoposterior 0 (118a) - 100 (26a) 4.6 ± 0.4 Lateral (LNs) 27 (118a) 0.3 ± 0.1 100 (26a) 2.6 ± 0.2 Ventroanterior (ventral cells) 100 (118a) - 100 (26a) - Ventroposterior 83 (118a) 1.0 ± 0.1 89 (26a) 1.5 ± 0.2 Thoracic neuromeres 100 (59) - 100 (13) - Abdominal neuromeres 93 (54) - 100 (12) - Mouth parts 96 (44) - 8 (12) - Ring gland 26 (50) - 100 (11) - The second of the two staining procedures described in Materials and Methods was used. For larvae from the SG3 and the SG10 transgenic lines, percentages of stained samples are indicated in the columns headed "% stained." The numbers of valid samples are shown in parentheses. In the columns indicating "No. signals," these means are quoted ± SEM. a Number of brain hemispheres; -, not determined.
Using these methods, we identified a total of six to eight per-expressing cell clusters in the nervous system of L3. All cell clusters consisted of neurons, as shown by their immunoreactivity to ELAV, a neuron-specific nuclear antigen of Drosophila (see Fig. 4G-I; Bier et al., 1988 
Fig. 4. Top. Confocal images showing subcellular localizations of PER, TIM, and SG. A-C, Wild-type L3 brains stained by anti-PER (green) also were stained by propidium iodide (red) to reveal nuclei. A, An LN at ZT 23; B, a DN1L at ZT 23; C, two DN2Ls at ZT 12. Anti-PER signals overlap with red DNA staining except in nucleoli, where there is no PER staining (an arrow in A points to a nucleolus). This indicates that PER is predominantly nuclear in these cells at their peak time points. D-F, Anti-TIM staining (green) on wild-type L3 brains counterstained by propidium iodide (red). D, An LN at ZT 21; E, a DN1L at ZT 21; F, two DN2Ls at ZT 10. Unlike PER, TIM is localized both in nuclei and cytoplasm but is excluded from nucleoli (an arrow in D points to a nucleolus). This cytoplasmic (and nuclear as well) staining also was observed in LNs at ZT 23 and DN2Ls at ZT 13 (data not shown). G-I, L3 brains from the SG3 transformant strain were double-labeled by anti-
Fig. 5. Bottom. Spatial expression patterns of a per-promoted reporter enzyme in early larval stages revealed by X-gal histochemistry. The staining pattern in the CNS of an L2 larva (24-26 hr after hatching) from the transgenic strain SG3 is shown in A and of an L1 larva (~15 hr, ZT 0) from the BG6a strain in B. A, The arrowheads (marked by 2) point to the dorsal clusters that seem to correspond to the PER-immunoreactive DN2L neurons; the arrows point to the stained cells in the lateral region, corresponding to the PER-immunoreactive LNs; all of the unmarked cells in the brain hemispheres are in the ventral region. In the ventral ganglion stained clusters near the midline of every neuromere are shown (large arrow pointing to the first thoracic neuromere). B, As in A, dorsal and lateral clusters
[View Larger Version of this Image (71K GIF file)]
Fig. 9. X-gal and anti-PDH double-labeling in the brain of a third-instar larva carrying a per-lacZ fusion gene. The transgenic strain was BG6a. A, Cells in both brain hemispheres labeled by X-gal and by an antibody against pigment-dispersing hormone at relatively low magnification; four and five LNs are prominently stained in the left and right brain hemispheres, respectively; the arrowheads point to the DNLs that are stained in the dorsoanterior brain hemispheres; the DN1Ls (arrowheads marked by 1) are stained only faintly and are slightly out of focus; the DN2Ls (arrowheads marked by 2) are located close to the terminals (large arrowheads) of the LNs, especially in the right brain hemisphere. B-D, LNs and DN2Ls in the left brain hemisphere in A at higher magnification; this brain region was first photographed after X-gal histochemistry had been performed (B), then rephotographed after anti-PDH immunohistochemistry was performed (C), and photographed for a third time after the blue X-gal stain had been dissolved by methylbenzoate (D); all four LNs were marked by X-gal. E-G, LNs and DN2Ls in the right brain hemisphere, marked by X-gal staining only (E), by X-gal and anti-PDH (F), and by anti-PDH only (G); four of five LNs stained by X-gal also were labeled by anti-PDH; the fifth LN (arrows in E and F) and both DN2Ls (marked by 2) were not PDH-immunoreactive; scale bars, 20 µm.
[View Larger Version of this Image (74K GIF file)]
By X-gal histochemistry, some differences in staining intensity and numbers of stained cells were found between the two SG transgenic lines (Fig. 1, Table 1). These differences probably are attributable to chromosomal position effects. However, the similarities of the staining pattern suggest that SG expression is controlled mainly by the regulatory sequences of this construct. The staining patterns for the two BG per reporter lines (BG6a and BG/TM2) were identical and overall very similar to those found by anti-PER immunohistochemistry in the wild type (compare Fig. 2 with Fig. 3).
In the BG lines and in wild-type larvae, fewer cells were stained than in the SG lines. These differences mainly were quantitative (see below). The most important difference among BG, wild-type per+, and SG expression was that the SG-encoded fusion protein did not cycle, but BG and endogenous PER exhibited cyclically varying staining intensities at least in some cells. This is consistent with the results recently obtained for SG- and BG-mediated expression of Cycling cells There are three clusters that belong to cycling cells: lateral neurons (LNs) and two dorsoanteriorly located clusters, dorsal neurons-1Larval (DN1L) and dorsal neurons-2Larval (DN2L).
In the following subsections the characteristic expression patterns associated with the different per-expressing cell clusters are described. They have been divided mainly into two categories: the cycling cells, in which cycling of BG and endogenous PER was clearly detected, and the noncycling cells, in which temporal variations of reporter or anti-PER signals were not detected.
Lateral neurons (LNs). This cluster is located between the optic lobe primordium and the central brain of L3 larvae. SG staining was strong in SG10 but relatively weak in the SG3 transgenic type, for which many of the samples did not show any staining (Fig. 1, Table 1).
In contrast, three to five LNs (mean = 4.0 ± 0.1; n = 80) were stained strongly by X-gal histochemistry applied to the BG lines at ZT 23 (Fig. 2A,B). No such staining was observed at ZT 12, indicating that the BG fusion protein cycles in this cluster (Fig. 2C,D).
Via anti-PER immunohistochemistry on CNSs from wild-type larvae, five LNs were stained relatively strongly at ZT 0-1, but not at ZT 12 (Fig. 3A,D, Table 2). No staining was observed in larvae expressing the per01 loss-of-function mutation (data not shown). Via confocal microscopy on fluorescently stained samples, up to four additional cells near the five LNs were found to express PER very weakly (data not shown).
Table 2. Anti-PER staining of wild-type L3 larvae
Type of cells and tissues ZT 0-1 ZT 11-12 % stained No. cells % stained No. cells Dorsoanterior DN1Ls 98 (45a) 1.9 ± 0.1 0 (38a) - DN2Ls 95 (43a) 1.6 ± 0.1 100 (38a) 1.9 ± 0.0 DN3Ls 86 (44a) - 89 (37a) - Lateral LNs 100 (46a) 5.0 ± 0.0 0 (38a) - Ventroanterior ventral cells 70 (20) - 53 (19) - Thoracic neuromeres 67 (21) - 100 (19) - a Number of brain hemispheres. In the columns indicating "No. cells," these means are quoted ± SEM; -, not determined. ZT 0-1, the first hour of day light in a 12 hr light/12 hr dark (LD) cycle; ZT 11-12, the first hour of darkness in the same kind of LD cycle.
Thus the LN cluster (in one side of the larval brain) consists of at least five cells in which the BG PER-
Subcellular localization of PER in this cluster was checked near its peak time point in the LD condition by confocal microscopy on immunofluorescently stained samples. It was found to be predominantly nuclear (Fig. 4A).
Dorsal neurons-1Larval (DN1L). The DN1Ls are located at the most medial part of the dorsoanterior region of the brain and consist of one to two cells. They were not detectable by X-gal histochemistry applied to SG larvae, although signals were detectable by the more sensitive method of anti-
Via X-gal histochemistry of BG, the DN1Ls were stained weakly in ~10% (n = 80) of the brain hemispheres at ZT 23, but not at ZT 12, indicating that BG cycles in this dorsal neuronal cluster (data not shown). Using anti-PER immunohistochemistry on CNSs from wild-type larvae, we detected weak staining in almost all of the hemispheres stained at ZT 0-1 (Fig. 3B,E, Table 2), but no staining was observed in the samples stained at ZT 12.
Thus the DN1Ls are two cells in the dorsoanterior region of the brain that express PER and BG weakly, but cyclically, with a peak near the end of the night or beginning of the day.
In this cluster subcellular localization of the SG fusion protein and endogenous PER was checked by the same method as that used for LNs. SG was found to be in nuclei at least at ZT 12 (Fig. 4G). PER was predominantly nuclear at ZT 0 (Fig. 4B).
Dorsal neurons-2Larval (DN2L). The DN2Ls consist of one to two cells located in a region lateral and posterior to that of the DN1Ls in the dorsal region of the brain. In SG larvae the staining in this cluster often was difficult to distinguish from that of another dorsal cluster (DN3Ls, see below), and the number of cells in the clusters was difficult to count (Fig. 1A,C). Therefore, the signals for these clusters taken together are compiled in Table 1.
In BG larvae the DN2Ls were stained most strongly at ZT 12 (Fig. 2C,D). One to two cells (mean = 1.6 ± 0.1; n = 78) were counted by this method. Similarly, anti-PER staining was stronger at ZT 12 than at ZT 0 (Fig. 3B,C,E,F).
In summary, DN2Ls consist of one to two neurons in which PER and BG cycle with a peak near the end of the day. Noncycling cells This class of cells were categorized into three to five clusters by position. They are cells on both sides of the midline at ventral ganglion and two to four clusters in the brain hemispheres dorsoanterior (DN3L), dorsoposterior, ventroanterior, and ventroposterior (see Fig. 1, Table 1). All of them seem to consist of multiple cells and could be divided into multiple subclusters.
Subcellular localization of SG fusion protein and endogenous PER was checked by confocal microscopy. SG (Fig. 4G) and PER (Fig. 4C) were nuclear at least at ZT 12.
In all of the noncycling cells, SG is expressed most strongly (Fig. 1, Table 1), with BG and endogenous PER giving much weaker signal (data not shown). Especially in the case of BG, staining in ventral clusters and cells in the ventral ganglion were detected only after anti-
Subcellular localization of SG fusion protein in noncycling cells was checked by confocal microscopy on samples immunofluorescently stained by anti- Outside the CNS In addition to the CNS, SG staining was observed in tissues around the mouth hook and in the ring gland (Table 1). The staining in the ring gland was mainly in the corpus allatum (Fig. 1D). All of these signals are real, because no staining was observed in these regions in wild-type larval controls. Neither BG nor endogenous PER was detected in any of these structures.
In summary, SG, BG, and endogenous PER are expressed in at least six classes of cells within the CNS of third-instar larvae: LNs, DN1Ls, DN2Ls, DN3Ls, ventral cells, and cells in the ventral ganglion. The SG-encoded fusion protein does not cycle, but that stemming from BG and the endogenous per+ gene cycle, at least in LNs, DN1Ls, and DN2Ls. In the other cells SG is expressed at a high level, but BG and endogenous PER are low. Expression pattern of per throughout postembryonic development
Earliest per expression The SG and BG per-lacZ fusion gene transgenics were used for determining the first stage of per expression in the larval CNS. For the analysis of SG-mediated expression, CNSs from SG larvae were stained for each of early L1 (1-2 hr after hatching), mid L1 (12-14 hr after hatching), and early L2 (24-26 hr after hatching; Table 3). For the study of BG-reported per expression, L1 and L2 larvae carrying the BG6a transgene were dissected at ZT 0 and ZT 12
Table 3. Staining signals in per-lacZ larvae (SG): stages L1 and L2
Cell cluster: age No. staining signals L1: 1-2 hr L1: 12-14 hr L2: 24-26 hr Dorsoanterior (DNLs) - (17) - (16) 1.0 ± 0.1 (18) Lateral (LNs) - (17) 0.9 ± 0.1 (16) 2.0 ± 0.1 (18) Ventroanterior 2.7 ± 0.3 (17) 2.4 ± 0.2 (16) 2.2 ± 0.1 (18) Ventroposterior 1.6 ± 0.1 (17) 2.4 ± 0.2 (16) 3.3 ± 0.2 (18) Ventral gangliona 12.4 ± 0.2 (9) 12.3 ± 0.2 (9) 12.9 ± 0.1 (8) Larvae carrying the SG fusion gene (strain SG3) were used, as was the second of the two staining procedures indicated in Materials and Methods. L1: 1-2 hr, first larval instar, 1-2 hr after hatching from the embryo; L1 12-14 hr, 12-14 hr after hatching; L2 24-26 hr, second larval instar, 24-26 hr after hatching. The "No. staining signals" are quoted ± SEM, except in a, for which the numbers of segments showing signals ± SEM in the ventral ganglia of the CNSs are indicated. The number of histologically interpretable brain hemispheres or ventral ganglia observed (last row) is indicated in parentheses; -, no staining was observed.
Table 4. X-gal-stained neurons in per-lacZ transgenic animals (BG) at various postembryonic stages and at the beginning of the day
Stage n No. stained cells Small LNv Large LNv LNd DN1L/DN1 DN2L/DN2 DN3L/DN3 L1 0-3 hr 11 (22) - - - - - - L1 4-8 hr 7 (14) 2.1 ± 0.4 - - - - - L1 12 hr 7 (14) 3.4 ± 0.3 - - - - - L1 15 hr 6 (12) 3.5 ± 0.4 - - 0.3 ± 0.1 1.0 ± 0.3 - L2 7 (14) 3.8 ± 0.2 - - 1.4 ± 0.1 1.7 ± 0.1 - L3 22 (41) 4.0 ± 0.1 - - 1.4 ± 0.1 1.8 ± 0.1 - P20-40% 8 (16) 4.1 ± 0.1 - - - 0.1 ± 0.1 - P50% 10 (18) 4.1 ± 0.1 2.8 ± 0.2 - 2.4 ± 0.2 1.2 ± 0.2 - P60% 8 (16) 4.1 ± 0.1 3.3 ± 0.2 2.2 ± 0.4 3.7 ± 0.3 1.8 ± 0.1 - P70-90% 11 (22) 4.1 ± 0.1 4.1 ± 0.2 4.5 ± 0.2 6.8 ± 0.3 1.7 ± 0.1 16.4 ± 1.3 Adult 6 (12) 3.8 ± 0.3 4.2 ± 0.2 5.3 ± 0.4 8.4 ± 1.1 1.8 ± 0.2 27.0 ± 2.9 Developing or adult animals carrying the BG (strain BG6a) per reporter protein fusion were used, as was first X-gal staining procedure described in Materials and Methods. The animals were killed at ZT 0, the beginning of the light period in a 12 hr/12 hr LD cycle. The "No. stained cells" in each entry are quoted ± SEM. The different life cycle stages are indicated by L1 0-3 hr, first instar larvae (0-3 hr after embryonic hatching); other intra-L1 times as indicated; L2 (24-26 hr after embryonic hatching); L3 (6-7 d old); P20-40%, 20-40% of the way through pupal (P) development; other intra P times as indicated. n, Numbers of samples. Numbers of histologically interpretable brain hemispheres are shown in parentheses; -, no staining was observed.
In LNs, BG was found first in 4- to 5-hr-old L1s dissected at ZT 0 (Table 4). SG was found in mid-L1 (12-14 hr after hatching) and L2, but not in early L1. In SG transformants only three or fewer cells were stained, whereas in BG transformants up to five LNs were stained. Importantly, no BG-mediated LN signals were detected in animals dissected at ZT 12, indicating that the amount of BG fusion protein in LNs of these earlier stages cycles with a similar phase, as in L3 (data not shown).
Two DNL clusters, DN1Ls and DN2Ls, were found in L1 larvae of BG older than 15 hr after hatching (Table 4). Up to two cells were stained for each cluster. DN1Ls were detectable more readily at ZT 0 than at ZT 12 (data not shown). DN2Ls were stained more prominently at ZT 12 than at ZT 0, indicating that antiphase cycling of PER begins during this early stage of development (data not shown). BG expression patterns at different pupal stages To follow the fate of the larval LNs and DNs, we stained pupal brains of the BG6a transformant for X-gal at different developmental stages, as well as at ZT 0, ZT 6, and ZT 12. For ZT 0, 8-11 brains (16-22 hemispheres) were stained for each age category, 20-40, 50, 60, and 70-90% of pupal development (Table 4). For ZT 6 and ZT 12, 2-11 brains (4-22 hemispheres) for each of 20-40, 50, and 70-90% of pupal development were observed.
In the SG transformant only DN2Ls (but not DN1Ls) were detected by X-gal histochemistry in L2 larvae (Fig. 5, Table 3). As in L3, the ventral region of the brain lobes and the ventral ganglion were stained prominently in SG, but not in BG. In contrast to the cycling cells, they were observed already in early L1. Unlike L3, in which larvae strong SG staining was observed only in the three thoracic segments (Fig. 1B,D), signals were seen in 12-13 segments both in L1 and L2 (Fig. 5A, Table 3). The difference between L1-L2 versus L3 may be attributable to the enlargement of the thoracic nervous system and the shortening of the abdominal nervous system during development.
During the first 40% of pupal development, only the four to five larval LNs were revealed readily by X-gal at ZT 0, except for a single weakly labeled cell near the region of DN2Ls in 1 of 16 hemispheres, dissected out at ZT 0 (Fig. 6A, Table 4). This suggests that DNLs stop expressing PER after the stage of pupariation. The BG-expressing LNs seem to correspond to a group of smaller LNs that are located relatively ventrally in adults (small LNvs; see below; also Helfrich-Förster and Homberg, 1993 
Fig. 6. per-lacZ expression pattern in pupal brains revealed by X-gal histochemistry. The transgenic strain used was BG6a. For all of these late developmental stages the left brain hemispheres are shown from a posterior view and reveal the DNs; the right ones are anterior views and reveal the LNs. A, Brain at 50% of pupal development; the arrowhead (marked by 1) in the left brain hemisphere points to two faintly stained DN1s; one of them is slightly out of focus and thus is difficult to see in this image; in the right brain hemisphere four prominently stained small ventral LNs (small LNvs) can be seen, which correspond to the larval LNs; dorsally to them two large LNvs have begun to express the BG-encoded reporter; the boxed section of the brain is shown to the right at higher magnification; the large arrow marks the two faintly stained large LNvs, and the small arrow marks the prominently stained small LNvs. B, Brain at 70% of pupal development; the arrowheads in the left brain hemisphere point to the DN1s, DN2s, and DN3s (marked by 1, 2, and 3, respectively); the DN3s are in close vicinity to the dorsolateral neurons (LNds; double arrowhead); in the right hemisphere four small and four large LNvs are stained (small and large arrows in the magnification of the boxed section); furthermore, the more dorsally situated LNds (double arrowhead) are now prominently stained; as in the left brain hemisphere, they are in close vicinity to the DN3s (arrowhead marked by 3). C, Brain of a newly emerged adult fly; all three groups of DNs can be seen in the left brain hemisphere, and the LNds as well as the small and large LNvs can be seen in the right one (also note the higher magnification of the boxed brain section); the LNds (double arrowhead) and the DN1s (arrowhead marked by 1) are now clearly separated from each other and cannot be seen in the same plane of focus; in addition to the DNs and LNs, the photoreceptor cells of the compound eyes (data not shown) and the ocelli (filled triangle) were stained prominently; furthermore, numerous glial cells on the surface of the optic lobe and central brain are revealed by X-gal. Scale bars: 100 µm for the pictures of the whole brains; 20 µm for the higher magnifications.
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By 80% of the pupal development, five other neuronal clusters were recognized: large LNvs (relatively ventrally located and larger LNs; Helfrich-Förster and Homberg, 1993
At the approximate half-way point of the pupal stage, DN1s, DN2s, and large LNvs were recognized first (Fig. 6A, Table 4). The DN1s continuously increased in number throughout pupal development (Table 4), whereas the DN2s remained at two cells and stayed at their position near the calyces of the mushroom body (Fig. 6C). At ~60% of development LNds and DN3s were first marked by X-gal (Table 4). It should be pointed out that larval DNLs and pupal DNs could be different cells despite the similarity in their position, because DNLs stop expressing BG after the pupariation.
Except for the DN2s and DN3s, all pupal BG-expressing cells cycled in
BG cycling in pupal DN1s and large LNvs seems to be less pronounced than in the above-mentioned two clusters. Both the DN1s and the cluster of large LNvs were stained relatively strongly at ZT 0 in >90% of the hemispheres dissected at 50-90% of pupal development, whereas at ZT 6 or ZT 12 they were stained only weakly and in relatively few hemispheres (12 of 42 hemispheres in the case of DN1, and 21 of 42 for large LNvs). Pupal DN2s and DN3s were stained at comparable levels at all three time points, and therefore cycling of BG was undetectable in these clusters. A similar result was obtained in a separate set of experiments on X-gal histochemistry on pupae with shorter incubation time (8 hr instead of 12 hr). Anti-TIM staining
To see if the other clock gene cloned from Drosophila, tim, is expressed in the larval CNS and to compare the expression pattern with that of per, we immunostained CNSs from L3 larvae with an antiserum against TIM. Sixty-six larval brains from eight time points
Table 5. L3 CNS cells immunopositive to anti-TIM
ZT No. cells stained No. samples LNs DN1Ls DN2Ls 1.3 0.3 ± 0.1 - 1.7 ± 0.1 8 (16) 3.9 - - 2.0 ± 0.0 10 (20) 10.1 - - 1.7 ± 0.1 10 (20) 10.9 - - 1.6 ± 0.2 5 (10) 13 3.1 ± 0.4 - 1.3 ± 0.2 8 (15) 15.3 4.9 ± 0.3 1.3 ± 0.2 0.7 ± 0.1 9 (18) 21.4 4.9 ± 0.1 2.0 ± 0.0 0.9 ± 0.1 10 (20) 23 4.6 ± 0.2 1.8 ± 0.1 1.1 ± 0.1 6 (12) In addition to the experiment summarized here, five additional ones with two to four timepoints each were performed. Very similar results (to those tabulated above) were obtained in all experiments. The "No. cells" stained (first three data columns) are quoted ± SEM. In the final column the numbers of histologically interpretable brain hemispheres are indicated in parentheses; -, not stained. See Table 2 for definition of ZT.
In the dorsoanterior brain region only two clusters were stained prominently with anti-TIM (Fig. 3G,H). The staining in DN1Ls was weak, even at its peak time point during late night. DN2Ls were stained strongly all through the day but weakly at night. Up to two cells per hemisphere were recognized for each of these DNL clusters (Table 5). In addition, one of the DN3L subclusters was stained very weakly. This faint staining was detected only after confocal microscopy was applied (data not shown).
In the lateral brain region LNs were stained by anti-TIM (Fig. 3G). They were stained strongly at night but not during the day. Up to five cells were counted in this cluster by epifluorescent microscope (Table 5). Additional weakly stained cells (up to four cells) were detected by confocal microscopy (data not shown).
In LNs, DN1Ls, and DN2Ls, subcellular localization of TIM was found to be both nuclear and cytoplasmic at least at their peak time point by observation on confocal microscopy (Fig. 4D-F). Taking advantage of this cytoplasmic staining, we determined the sizes of the cell bodies for each cluster. Diameters were similar for all three clusters, within the range of 5-9 µm.
In the ventral region of the brain and ventral ganglion, two to four cells were stained at the tip of the ventral ganglion in both wild-type larvae and those expressing the tim01 loss-of-function mutation (data not shown; Sehgal et al., 1994
Colocalization of PER and TIM in all of the TIM-expressing clusters was confirmed by a double-labeling experiment, using anti-PER and anti-TIM antisera on nine brain hemispheres from five brains (data not shown). Cycling phases of BG and TIM in LD
Because the phase of BG cycling seems to be indistinguishable from the endogenous PER cycling (as is also the case in adults; Dembinska et al., 1997
Fig. 7. BG cycling revealed by X-gal histochemistry and TIM cycling revealed by immunofluorescent staining in LD cycles. LN signals, solid lines and diamonds; DN2Ls, dotted lines and circles; DN1Ls, broken lines and squares. Error bars represent SEM of 0.1 or larger. (SEMs smaller than 0.1 do not appear in the graphs because of the artifact in the plotting program, but these are quite small errors in any case.) All of the data points are an average of multiple samples. Open and black bars at the bottom of graphs B and D represent the 12 hr light phase and the 12 hr dark phase, respectively. The method for scoring staining intensities reported by Stanewsky et al. (1997a)
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The phases of BG cycling in LNs and DN1Ls were similar to those that have been found in the adult, with a peak at ~ZT 23 and a trough at ~ZT 6-ZT 12 (Fig. 7A). The cycling amplitude was low in DN1Ls because of the overall low expression level. In contrast, BG-encoded fusion protein was found to cycle in almost opposite phase in the DN2Ls, with a peak at ~ZT 12 and a trough at ~ZT 0. The exact peak time point in DN2Ls may be a few hours later than ZT 12, because the level of BG staining was found to be higher at ZT 17 than at ZT 12 in one of four such experiments.
The peak level in the DN2Ls was lower than that in the LNs, and some staining in the DN2Ls could be detected in ~40% of the brain hemispheres even at their trough time point. Therefore, the BG-encoded fusion protein in the DN2Ls seems to cycle with lower amplitude than in the LNs.
TIM cycling in wild-type larvae was assessed by anti-TIM immunohistochemistry at eight time points (Fig. 7C). As for per-reported expression in the BG transgenics, TIM was found to cycle with different phases in different cell types. Especially in DN2Ls, where BG cycling was found to be almost antiphase of that in LNs and DN1Ls, TIM cycling was also antiphase (Fig. 7C). Furthermore, TIM was high all through the day in this cluster. In addition, there is a difference in the phase relationships of the TIM and BG curves, when the LN and DN2L clusters are considered separately (compare Fig. 7A with 7C). In DN2Ls the rising phase of BG curve in large part lagged behind that of TIM curve, yet in LNs the rising phases of BG and TIM curves were different by only a few hours.
In adults, BG protein level cycles in LD cycle conditions even in a per01 genetic background, yet with lower amplitude than in per+ (Dembinska et al., 1997
Furthermore, the cycling phases of TIM and BG are slightly different from those in per+. For example, TIM did not decrease as quickly in response to light in per01 as in per+. This could be explained by a higher level of tim mRNA available in per01, as compared with per+, at the dark/light transition Cycling of PER and TIM in constant dark
The above results indicate that PER and TIM cycle at least in the three neuronal clusters in the larval CNS under LD cycle conditions. If these rhythms are true circadian ones and not driven by the external LD cycle, they should persist under free-running conditions. To test this, we performed PER and TIM immunohistochemistry on L3 brains of wild-type larvae under constant dark (DD) conditions for 2 d, starting at the fifth day after egg laying. Fluctuations of PER and TIM in a preceding LD cycle also were assessed.
Cycling of PER and TIM immunoreactivity was detectable in LNs, DN1Ls, and DN2Ls for 2 d in DD (Fig. 8). In LNs and DN1Ls, the peak times in DD were in phase with those in LD, indicating free-running periods of ~24 hr. In DN2Ls, the cycling phases for both PER and TIM seem to be advanced by a few hours on the second day in DD. For instance, the trough time point of PER was at ~circadian time 18 in DD but at ~ZT 23 in LD. Similarly, the peak time point for TIM was at ~circadian time 23 in DD, but at ~ZT 6 in LD. The cycling amplitudes of both PER and TIM seemed to decrease in both DNL clusters. In DN1Ls, this was attributable mainly to the decrease in the peak levels, whereas in DN2Ls the amplitude decrement occurred because of the increase in the trough levels. It should be pointed out that this amplitude-dampening effect could be attributable to the age difference as well as to the environmental condition (DD), because 2 d elapsed between the first day (LD) and the last day (the second one in DD) in this experiment. The amplitude dampening was not apparent in LNs. In all three of the clusters, TIM rose a few hours earlier than PER did in both LD and DD conditions (cf. Marrus et al., 1996 
Fig. 8. PER and TIM cycling revealed by immunohistochemistry in an LD cycle, followed by 2 d of DD. Fluctuation of PER immunoreactivity is shown in A, and TIM immunoreactivity is shown in B. LN signals, blue lines and diamonds; DN2Ls, pink lines and circles; DN1Ls, green lines and squares. Error bars represent SEM of 0.09 or larger. The light regime is shown at the bottom of B, where the white bar indicates the last period when lights were on, the black bars indicate when the lights were off, and the hatched bars indicate when the lights would have been on had the LD cycle been continued. For all of the data points, 5-10 (mean = 7.8) samples (10-20 brain hemispheres) were scored. Larvae were raised in LD cycles for 4 d after 24 hr of egg laying. Starting on the fourth day, 10-20 larvae were dissected at ~ZT 23, 6, 12, 18, and 23 in an LD cycle (first day in the graphs, as indicated by the black and open bars at the bottom). Therefore, 0 hr on the abscissa corresponds to ZT 0 on the fourth day. Then the remaining larvae were maintained in constant darkness (DD) for 2 further days (in particular, 42 hr of DD subsequent to the end of the "D" portion of the LD cycle), and 10-20 larvae were dissected every ~6 hr. By the seventh day many of the larvae had completed pupariation. One-half of the brains dissected at each time point were stained for PER immunoreactivity, and the other half were stained for TIM immunoreactivity. After brains from all of the time points were stained, PER and TIM immunoreactivities were blindly scored simultaneously by the second such method (see Materials and Methods). The resulting mean and SEM values for each time point were plotted: in A, PER immunoreactivity; in B, TIM immunoreactivity.
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Anti-PDH signals and coexpression of per
In adults, most of the ventral group of LNs (LNvs) are immunoreactive to the peptide hormone PDH (Helfrich-Förster, 1995
The numbers of LNs labeled by either BG expression or PDH presence, or both, are shown in Table 6. In ~80% of the valid brain hemispheres, four or five LNs were revealed for either BG or PDH, or both. In most of the samples in which five LNs were revealed, all of the LNs were stained for BG, but the number of PDH-stained LNs never exceeded four. These PDH-stained LNs also were stained for BG in all 12 such cases. In most of the specimens for which four LNs were revealed, all four of the neurons were indeed double-labeled for PDH and BG.
Table 6. Lateral neurons of BG transgenic larvae stained for
No. LNs revealed 5 LNs 4 LNs 3 LNs 2 LNs No. total hemispheres 13 19 8 1 No. hemispheres with 4 LNs double-labeled 12a 17 - - No. hemispheres with 3 LNs double-labeled - 2c 7 - No. hemispheres with 2 LNs double-labeled 1b - 1a - No. hemispheres with 1 LN double-labeled - - - 1c a The number of
These results indicate that there are five larval LNs, of which four contain PER and PDH, suggesting that these four doubly expressing neurons correspond to the precursor of small LNvs in adults, whereas one LN contains only PER and had not been identified in adults previously (Helfrich-Förster, 1995
One further feature of the PDH-related results was that the immunohistochemical signals revealed the projections of the four small LNvs in the double-labeled preparations. Interestingly, their terminals were always located in close proximity to the cell bodies of DN2Ls (Fig. 9A,C,F). Larval photoreceptors terminate close to LNs
In larvae, LNs are located near the larval optic neuropile, where larval photoreceptor axons called Bolwig's nerve terminate (for review, see Meinertzhagen and Hanson, 1993
Fig. 10. Spatial relationship between LNs and Bolwig's nerve. A, Anti-PDH immunohistochemistry on an L3 CNS of a wild-type larva revealed four LNs sending fine dendritic processes (arrowhead) as well as axons. B, Confocal image of an L3 CNS of a BG transgenic larva, double-labeled with anti-
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In all, 36 brain hemispheres from larvae of the BG6a strain were observed. In 21 of these hemispheres, five LNs were stained with anti-
DISCUSSION
We have shown that the Drosophila clock genes per and tim are expressed in the CNS. Previous studies on per failed to detect appreciable levels of its expression at this developmental stage, except that a low level of per expression was found in whole-larval extracts by Northern blotting (Bargiello et al., 1987Relevance of larval expression to later events
Among the per-expressing cells in such developing animals, larval LNs
A contribution of other per-expressing neurons to the actual "gating" of a developmental event such as eclosion rhythm nevertheless is possible. Such non-LNs, however, would seem not to be suited to transfer larval time memory into pupae and adults, because those other cells (such as the DNLs) either develop too late or do not express per during early metamorphosis. per-Expressing cells and tim-expressing cells
Among the more intriguing of our developmentally related findings is that spatial expressions of PER and TIM (and temporal ones as well; see below) were not as one might expect from the adult patterns. In larvae, cycling of the clock gene products was detected only in LNs, DN1Ls, and DN2Ls. In the other groups of per neurons, SG fusion protein was expressed strongly in cytoplasm, but BG and endogenous PER were expressed weakly, and TIM was undetectable (at least in terms of epifluorescence microscopy). Our findings suggest that PER and BG (but not SG) stay low in the cells in which TIM is low. This is consistent with biochemical results obtained in adults, which have shown that both TIM and PER are necessary for nuclear translocation and normal molecular cycling of both gene products and that the level of PER is low in a genetic background possessing no tim+ function (Price et al., 1995Cycling phases of PER and TIM in dorsal neurons of larvae
The most unexpected result in this study was the presence of antiphase cycling of clock gene products in certain dorsally located neurons: the DN2Ls of larvae. In particular, high level of TIM in the DN2Ls during the day was intriguing, considering one of the most salient findings from studying the tim gene product: TIM in the adult head decreases sharply in the face of chronic or pulsatile exposure of the flies to light (for review, see Sehgal et al., 1996
Previous biochemical studies of adults have revealed similar cycling phases for per in eyes and brains (Zeng et al., 1994
The mechanisms responsible for these phase differences are unknown. One possibility is that DN2Ls may not be entrained directly by light or the photoreceptors but, rather, are entrained
Furthermore, the relatively high and constant level of the BG fusion protein, as well as that of native TIM, within the DN2Ls of larvae suffering the effects of a loss of per function could be explained by this hypothesis. A per null genotype, in particular within the larval LNs, would leave such cells always at the trough level time point of PER (despite the presence of BG protein, which is not functional in adults; Stanewsky et al., 1997a
However, these findings and interpretations are not in accord with the results of monitoring PER and TIM cycling in DD. Amplitudes for both proteins seem to dampen faster in DN2Ls than in LNs, suggesting that DN2Ls may be influenced more strongly by LD cycles than LNs are. Because TIM is relatively high during most of the daytime, light may induce the production of TIM, stabilize it in DN2Ls, or both. This hypothesis would require a different molecular mechanism related to the effects of light on, as well as the basic oscillations of PER and TIM in the DN2Ls. Light entrainment pathway from larval photoreceptors to the clock neurons
Eclosion rhythmicity (Brett, 1955Correspondence of larval clock neurons with adult clock neurons
Four PER-expressing small LNvs are immunoreactive with respect to the PDH neuropeptide and are most likely the precursors of the PDH-immunoreactive small LNvs in adults. However, the fifth LN present in larvae expressed only the clock gene. In principle, this fifth LN could correspond to part of either the LNd or the LNv cluster in pupae and adults. However, BG expression in five LNs was revealed during the early pupal stage before the LNd clusters were first recognized at ~60% of the way through metamorphosis. Therefore, it seems more likely that the fifth, small PDH-negative LN belongs to the group of small LNvs.
The larval DN1Ls, DN2Ls, and DN3Ls could be the same cells as DN1s, DN2s, and DN3s, respectively, in pupae and adults Application of the larval brain to in vitro studies of the circadian clock
In the adult head, per and tim are expressed in photoreceptors, glia, and neurons (Siwicki et al., 1988
In this regard, individual neurons from the larval CNS of Drosophila are relatively easy to dissociate from other cells (Wu et al., 1983
FOOTNOTES
Received Feb. 13, 1997; revised June 6, 1997; accepted June 11, 1997.
This work was supported by National Institutes of Health Grant GM-33205 and Deutsche Forschungsgemeinschaft Fo 207/3. We are grateful for antisera from Michael W. Young (anti-TIM), Michael Rosbash (anti-PER), Ralf Stanewsky (anti-PER), and Heinrich Dircksen (anti-PDH). We thank Kalpana White, Michael Rosbash, Stephen F. Goodwin, and Ralf Stanewsky for comments on this manuscript. The mAb 5D was kindly supplied by Kalpana White and the mAb 22C10 by Seymour Benzer. We appreciate the slide-coding efforts of Alexandre A. Peixoto and Ralf Stanewsky and the excellent photographic assistance provided by Ed Dougherty.
Correspondence should be addressed to Dr. Jeffrey C. Hall, Department of Biology, 235 Bassine Building, Brandeis University, 415 South Street, Waltham, MA02254-9110.
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