Abstract
Vertebrate synapsins constitute a family of synaptic proteins that participate in the regulation of neurotransmitter release. Information on the presence of synapsin homologs in invertebrates has been inconclusive. We have now cloned a Drosophila gene coding for at least two inferred proteins that both contain a region with 50% amino acid identity to the highly conserved vesicle- and actin-binding “C” domain of vertebrate synapsins. Within the C domain coding sequence, the positions of two introns have been conserved exactly from fly to human. The positions of three additional introns within this domain are similar. The Drosophilasynapsin gene (Syn) is widely expressed in the nervous system of the fly. The gene products are detected in all or nearly all conventional synaptic terminals. A single amber (UAG) stop codon terminates the open reading frame (ORF1) of the most abundant transcript of the Syn gene 140 amino acid codons downstream of the homology domain. Unexpectedly, the stop codon is followed by another 443 in-frame amino acid codons (ORF2). Using different antibodies directed against ORF1 or ORF2, we demonstrate that in the adult fly small and large synapsin isoforms are generated. The small isoforms are only recognized by antibodies against ORF1; the large isoforms bind both kinds of antibodies. We suggest that the large synapsin isoform in Drosophila may be generated by UAG read-through. Implications of such an unconventional mechanism for the generation of protein diversity from a single gene are discussed.
Release of neurotransmitter from presynaptic nerve terminals involves complex molecular mechanisms effecting the movement of transmitter-loaded vesicles to the presynaptic membrane, the docking of the vesicles at release sites, the priming of docked vesicles for exocytotic competence, the calcium-triggered fusion of vesicular and presynaptic membrane to secrete the transmitter into the synaptic cleft, and the reuptake of the vesicular membrane by endocytosis. However, the molecular details of these mechanisms are still primarily speculative, although the components involved are under intensive investigation (Jahn and Südhof, 1994; Scheller, 1995;Südhof, 1995). One of the best-studied groups of molecules of vertebrate synaptic terminals is the synapsins, a small family of synaptic vesicle-associated phosphoproteins. The four known isoforms, synapsin-Ia,b and synapsin-IIa,b, are generated by alternative splicing of transcripts from two genes (Südhof et al., 1989; Südhof, 1990). Mainly on the basis of in vitro experiments, these proteins were generally assumed to play a major role in the short-term regulation of neurotransmitter release and in the maturation of synaptic contacts during synaptogenesis (Bähler et al., 1990;DeCamilli et al., 1990; Benfenati et al., 1991; Chin et al., 1995;Ferreira et al., 1995; Pieribone et al., 1995; Valtorta et al., 1995). In specific experimental situations, dephosphorylated synapsin-I appears to restrict the availability of transmitter-loaded synaptic vesicles for exocytotic release by interlocking the vesicle membrane with actin filaments, thereby arresting the vesicles in the cytoskeletal meshwork. Depolarization of the nerve terminal leads to phosphorylation of synapsin-I and thus may release the vesicles from the cytoskeleton, transferring them from a “reserve” to a “releasable” pool. In this way, the amount of transmitter available at the presynaptic membrane could be regulated by the synapsins (Llinas et al., 1991; Benfenati and Valtorta, 1993). However, the importance of synapsins for basic synaptic function and their involvement in the development of synaptic contacts has recently been questioned, because mouse knock-out mutants lacking synapsin-I, -II, or both genes show rather normal development and behavior. Observed phenotypes in these animals include a tendency to show seizures, altered distribution of synaptic vesicles in presynaptic terminals, decreased transmitter release, and specific defects in neuronal plasticity (Rosahl et al., 1993; 1995; Li et al., 1995).
The high conservation within the vertebrate radiation found for all known proteins associated with synaptic terminals and the fact that homologs have been detected for most of them in Drosophilaand/or Caenorhabditis suggest that synaptic transmission as a fundamental mechanism of intercellular communication has been conserved in evolution between vertebrates and invertebrates. This is an important issue, because the close morphological and electrophysiological similarity of vertebrate and invertebrate synapses has always been invoked to justify the extensive use of invertebrate model systems for the general study of synaptic function. It was therefore unsatisfying that previous attempts to isolate aDrosophila gene homologous to the vertebrate synapsin gene family have been unsuccessful, although proteins cross reacting with antibodies against vertebrate synapsins have been described both inDrosophila and Aplysia (Mitschulat, 1989;Bongiovi et al., 1992). Our present results demonstrate the existence of a synapsin homolog gene in Drosophila and the conservation of the central vesicle- and actin-binding “C” domain between flies and mammals. Immunochemical analysis of fly head homogenates and cDNA-encoded protein fragments expressed in bacteria suggests that in Drosophila, different synapsin homolog isoforms may be generated from a single gene by a mechanism of partial suppression of a UAG stop codon separating two large open reading frames.
Some of the data have been published previously as meeting abstracts (Heimbeck et al., 1990; Klagges et al., in press).
MATERIALS AND METHODS
cDNA and genomic library screening
The first Syn cDNA was isolated in a screen of 250,000 plaque-forming units (pfu) of a Drosophila head λgt11 cDNA expression library (wild-type Berlin-K) (as described byYoung and Davis, 1985) attributable to a cross reaction of a polyclonal antiserum against a synthetic neuropeptide (antiserum HHA-09 kindly provided by P. Emson). Using the 1.1 kb 5′-EcoRI fragment (Syn-1+ in Fig. 6) of this 1.6 kb cDNA clone as randomly primed probe (Feinberg and Vogelstein, 1983; Amersham protocol) for hybridization screening of 200,000 pfu of the same cDNA library, 12 additional cDNA clones were obtained. A 400 bpBamHI fragment (containing a central region of the synapsin homology) of the longest of these cDNAs (Syn-1 in Fig. 6) was used as a probe (P3 in Fig. 6) for screening 200,000 pfu of a second head cDNA library (λZap, wild-type Canton-S, Stratagene). This screen resulted in the isolation of nine additional cDNAs.
cDNA fragment Syn-1+ (see Fig. 6) was also used as a randomly primed probe for screening a λ-Fix genomic library (wild-type Berlin-K). The cloned genomic walk was extended by additional screening of a λ-Gem-11 library (wild-type Oregon-R, kindly provided by K. Kaiser), resulting in a cloned genomic region of nearly 56 kb.
Subcloning and sequencing of cDNAs and genomic fragments
Phage DNA was isolated and EcoRI fragments were inserted into pBluescript KS vectors according to Sambrock et al. (1989) or according to the Stratagene in vivo excision protocol. Templates were sequenced by the dideoxy method of Sanger et al. (1977) using modified T7 polymerase (Pharmacia) or Sequenase 2.0 (United States Biochemicals). Unidirectional deletions of cDNA clones were created by the method of Henikoff (1987) and sequenced from both strands. Genomic clones were sequenced directly with synthetic oligonucleotide primers. As a control against cloning artifacts, native genomic Drosophila DNA was amplified by PCR using one unmodified and one biotinylated oligonucleotide primer. DNA strands of amplified DNA were separated according to the Dynabeads-M280 protocol (Dynal) and sequenced using Sequenase-2.0 (United States Biochemicals). Sequence data were analyzed using the DNASIS/PROSIS (Pharmacia) and the GCG (University of Wisconsin, Madison, WI) program packages.
Preparation of fusion proteins and antisera
Fusion proteins were produced using the glutathione-S-transferase (GST) expression vector system (Pharmacia) inE. coli DH5α (sup+) and BL21 (sup−) cells. DH5α cells contain a UAG suppression tRNA gene (sup E44) and are thus able, albeit with low efficiency, to read through UAG stop codons. cDNA fragments (see Figs.1 and 6) were cloned in frame to GST by using the corresponding pGex vector version. Fusion proteins consisting of the 26 kDa GST carrier and the different SYN proteins were induced and purified as described by Smith and Johnson (1988).
Mice were injected with different amounts (1 μg up to 11 μg) of 5′-fusion protein and 3′-fusion protein (see Fig. 6) and boosted after 3 weeks. Antisera were collected the next week. Fusion of spleen cells with myeloma cells and isolation of a SYN-specific hybridoma cell line were performed according to standard protocols (Peters and Baumgarten, 1990).
Immunohistochemistry
Adult flies. Immunostaining of frozen sections was performed as described previously (Buchner et al., 1986). Flies were fixed for 3 hr in 4% paraformaldehyde and washed overnight in 25% sucrose solution. Sections were cut on a cryostat microtome at 10 μm thickness and incubated at 4°C with primary antisera or the primary monoclonal antibody at dilutions of 1:1000 or 1:4, respectively. The staining procedures followed the protocol of the biotin–avidin–peroxidase system (Vector Laboratories). Specificity of antibody staining was verified by appropriate controls (e.g., omission of primary antibody).
Larvae. After immobilization at 4°C, late third instar larvae of WT Berlin-K strain were pinned to a layer of transparent silicone rubber (Sylgard) and cut open as described by Jan and Jan (1976) under a drop of HL3 solution (Stewart et al., 1994). The preparations were fixed overnight in phosphate buffered 4% paraformaldehyde and washed three times in a large volume of PBS. The staining procedure followed the biotin–avidin–peroxidase protocol (Vector Laboratories) as described previously (Buchner et al., 1986). After incubation for 2 hr in diluted normal horse serum containing 0.1% Triton X-100, the monoclonal antibody SYNORF1 (dilution 1:100) was applied for 48 hr at 4°C and visualized by using a biotinylated secondary antibody, the avidin–peroxidase complex, and DAB as chromogen.
In situ hybridization
Head sections. cDNA fragment Syn-1+ (Fig. 6) was used as template for the generation of a 35S-labeled RNA probe that was hybridized to Drosophila head sections. Preparation of frozen sections and hybridization followed the protocol of Hafen et al. (1983). Contact autoradiographs were obtained by compressing a microscope slide carrying the dried sections and an emulsion-coated slide prepared by dipping in Ilford L4 liquid emulsion and thorough drying. After exposure, the slides were separated, the films developed, and autoradiographs and sections observed simultaneously on a two-stage microscope (Leitz).
Embryo whole mounts. Digoxygenin (DIG)-labeled DNA probes were generated using cDNA Syn-1 as template according the DIG–DNA labeling protocol (Boehringer Mannheim) and hybridized to embryo whole mounts. Preparation of the embryos and hybridization was performed according to Tautz and Pfeifle (1989). Components of the DIG–DNA Detection Kit (Boehringer Mannheim) were used for the staining procedure. Embryos were incubated for 1 hr at 4°C in a 1:400 dilution of the phosphatase-conjugated antibody. After washing four times in PBS (130 mm NaCl, 7 mmNa2HPO4, 3 mmNaH2PO4, pH 7.4), whole mounts were equilibrated in 5 mmMgCl2, 100 mm NaCl, 100 mm Tris, pH 9.2, and NBT/BCIP staining reaction was performed according to the protocol.
Western blots
Frozen Drosophila heads were collected and homogenized in sample buffer on ice. After separation by standard sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) (Laemmli, 1970), proteins were transferred to nitrocellulose membranes according to Khyse-Andersson (1984). Immunostaining was performed as described in the Proto-Blot protocol (Promega) or according to the enhanced chemiluminescence Western blotting protocols (Amersham).
RESULTS
Two alternatively spliced cDNAs
In a search for novel genes expressed in the adult brain ofDrosophila, various antibodies selected for neuronal staining in immunohistochemical preparations were used to screen cDNA expression libraries (Zinsmaier et al., 1990; Reifegerste et al., 1993;Reichmuth et al., 1995). The expression patterns of the genes corresponding to the cloned cDNAs were determined by tissue in situ hybridization. One clone that was isolated because of an unspecific cross reaction of one of the antisera hybridized to most of the cellular rind of the fly’s brain. This cDNA was used as a probe to isolate 11 additional independent clones from an adult head cDNA library. Sequencing of both strands of the longest cDNA (Syn-1, 3960 bp) revealed two in-frame potential coding regions (stop to stop) of 626 and 443 amino acids separated by a single TAG stop codon (Fig.1a). By comparison with the GenEMBL database, the upstream open reading frame was found to contain a central region of 309 amino acids (bold in Fig. 1) showing 50% identity and 89% similarity to the C domain of vertebrate synapsins (Südhof et al., 1989) (Fig. 2). Outside this region, no amino acid patterns with significant similarities to synapsins or other known proteins are observed. However, common features of vertebrate andDrosophila synapsins include richness in proline residues and strings of serine residues outside the C domain. The sites where vertebrate synapsins are phosphorylated by cAMP-dependent protein kinase (PK-A) or Ca2+-calmodulin-dependent kinase I (PK-MI) (P1 in Fig. 9) and the sites for PK-MII (P2, P3) and for a proline-dependent kinase (P4) are not conserved inDrosophila. Nevertheless, at different positions, two consensus patterns for PK-A (R/K-R/K-X-S/T) and several for PK-MII (R-X-X-S) or proline-dependent kinase (X-S/T-P-X) (Hall et al., 1990) are found in the inferred SYN protein. So far no information is available on the actual phosphorylation pattern of theDrosophila synapsin homolog isoforms.
Probing a second head cDNA library (courtesy B. Schmidt, Max Planck Institut für Hirnforschung, Frankfurt, Germany) with a fragment that encodes the homology domain, another eight independent cDNAs were isolated. Restriction analysis and partial sequencing indicates that, of the 20 cDNAs isolated so far, 11 apparently derive from the same transcript as Syn-1; in particular, all of these contain the central stop codon and show an identical restriction map throughout the coding regions. Three 5′ incomplete cDNAs derive from an alternatively spliced mRNA. The longest of these (Syn-2, Fig. 1b) begins at nucleotide (nt) 652 of Syn-1 within the homology region. Assuming identical 5′ ends for Syn-1 and Syn-2 transcripts, Syn-2 contains a potential coding region (stop to stop) of 577 amino acids, 95 of which at the C terminus are different from Syn-1 because of alternative splicing at the 5′ end of intron 10 (Fig. 1b). The noncoding 3′ end of Syn-2 contains additional genomically verified 78 bp. Interestingly, all three cDNAs of this group display an extraBamHI site because of an inconsequential single-base exchange at nt 2050 of Syn-1 (see Discussion). The remaining six cDNAs have their 5′ ends downstream of the alternative splice site and thus may belong to either group. Three of these contain at their noncoding 3′ ends a 0.7 kb extension (not shown) of which only the beginning and the end have been sequenced.
The Syn gene
Exon–intron structure of the Syn gene was determined by verifying the entire Syn-1 and Syn-2 cDNA sequences (except for a few noncoding regions) in genomic clones (compare Figs. 1 and3). Four differences noted between cDNAs and genome are described in the legend to Figure 1. They may represent polymorphisms in fly stocks or artifacts of reverse transcription or cloning. The known transcribed part of the Syn gene contains 11 introns (Fig. 3). Two introns in the homologous C domain are found at identical positions in Drosophila and man (Südhof, 1990), and three additional intron positions are similar, as shown in Figure 2. Some of the exon–intron boundaries (Fig. 4), in particular those of intron 2, differ considerably from the consensus sequence (Senapathy et al., 1990; Mount et al., 1992), even at the most conserved 5′ (GT) and 3′ (AG) intron ends.
The Syn gene has been mapped by in situhybridization to a single site in region 86A on the right arm of chromosome 3 (data not shown). Low-stringency Southern blots using the homology region as a probe give no indication of a second homologous gene. We conclude that the Syn gene presumably represents the only synapsin homolog in Drosophila.
Expression of the Syn gene
Transcription of the Syn gene was investigated by Northern blots and tissue in situ hybridization. Using probes P1, P2, and P3 from cDNA Syn-1 (compare Fig. 6), consistent and about equally strong Northern signals near 5.5 and 1.9 kb are detected at all developmental stages after mid-embryogenesis (data not shown). Because cDNA Syn-1 is incomplete at a known length of 3960 bp and cDNA Syn-2 may differ from Syn-1 by as little as 4 bp, we assume that both cDNAs are represented in the 5.5 kb signal (compare Discussion). Tissuein situ hybridization of embryos (Fig.5a) and adult head sections (Fig.5b) demonstrates Syn expression in most or all parts of the nervous system. Hybridization to adult photoreceptors and lamina monopolar cells appears considerably weaker than to the rest of the brain cellular rind (Fig. 5b).
To determine the size and distribution of polypeptides translated from the Syn gene, we have produced two sets of mouse antisera (AS) against the bacterially expressed GST fusion proteins 5′-FP and 3′-FP (compare Fig. 6). The 5′-FP contains most of the 5′ reading frame ORF1 and is encoded by cDNA Syn-1* up to the internal stop including the homology region. The 3′-FP contains most of the 3′ open reading frames downstream of the stop codon (ORF2) and is encoded by cDNA Syn-1+. Specificity of the antisera was tested by Western blots of lysates from bacteria expressing either the fusion proteins or only the GST carrier protein. Of six mice injected with 5′-FP, five produced AS reacting with both the 5′-FP (control) and the GST carrier, and one serum was negative. Spleen cells from one of the positive mice were fused with myeloma cells, and a hybridoma cell line was established that secretes a monoclonal antibody recognizing the 5′-FP but not GST (mAb SYNORF1). At least four, probably five, synapsin isoforms are recognized by mAb SYNORF1 in Western blots of fly head homogenates (lane H of Fig. 7a): three prominent protein bands ofMr = 70, 74, and 80 kDa (SDS-PAGE) and one or two less-abundant proteins of Mr ∼ 143 kDa.
All six AS generated against the 3′-FP reacted with this FP (control) and with GST carrier. One of these sera was preabsorbed with GST to obtain a serum specific for the reading frame encoded downstream of the central TAG stop (AS SYNORF2). Antiserum SYNORF2 recognizes in fly head homogenates only the two less-abundant proteins ofMr ∼143 kDa (lane H of Fig. 7b).
These results can readily be connected to the molecular genetic data described above if we assume that, in the fly, the central UAG stop codon in the mRNA corresponding to cDNA Syn-1 is partially read through by a specific, as yet unknown mechanism (see Fig. 9 and Discussion). We therefore wanted to test how the partial suppression of this stop codon by a known mechanism, i.e., a UAG suppressor tRNA in the E. coli expression system, would affect the proteins derived from cDNA Syn-1. For direct comparison, we transformed with cDNA Syn-1* (Fig. 6) both a normal (see B+ and B− in Fig.7) and a genetically modified E. coli strain (see D+ in Fig. 7), the latter containing a UAG suppressor tRNA gene. Extensive tests were performed with all antisera on the various fusion proteins. Controls included omission of first antibody (not shown) and comparison of induced (+) and noninduced (−) bacteria. Figure 7 summarizes the results showing data of the specific antibodies, mAb SYNORF1 and the GST-preabsorbed AS SYNORF2. mAb SYNORF1 (Fig. 7a) recognizes in induced sup− (B+) and sup+ (D+) strains a 78 kDa fusion protein (plus presumed degradation products) and, in addition, in the sup+ (D+) strain a ∼150 kDa fusion protein. Lysates from noninduced bacteria show little or no signal (B−). AS SYNORF2 (Fig.7b), on the other hand, only stains the ∼150 kDa read-through fusion protein (RT-FP) (plus degradation products), which is generated only in the induced sup+ strain (D+). No specific staining is observed in lysates of the sup− strain (B+, B−). The large amount of unlabeled 5′-FP of 78 kDa can be recognized in both induced lanes (B+, D+) because of a faint cross reaction of the secondary antiserum. These tests demonstrate the specificity of mAb SYNORF1 and AS SYNORF2 as they bind only to those parts of the Syn-1-encoded fusion proteins expressed in E. coli that were used for immunization. The signals in fly homogenates (lanes H in Fig. 7a,b) demonstrate that the 70/74/80 kDa triplet binds only antibodies against the 5′ reading frame (ORF1), whereas the ∼143 kDa doublet is recognized by antibodies directed against both reading frames, upstream (ORF1) and downstream (ORF2) of the internal TAG stop.
Using mAb SYNORF1, we have determined the approximate relative amounts of the 70/74/80 kDa and the ∼143 kDa proteins in head homogenates by loading increasing amounts of homogenate. Figure 7cindicates that the strongest signal of the triplet is about four to five times as abundant as the ∼143 kDa proteins.
In immunohistochemical experiments, mAb SYNORF1 and all antisera (except the negative serum), regardless of which of the two Syn-1 reading frames they are directed against, show indistinguishable staining of most regions of the larval and adult synaptic neuropil and of synaptic boutons on larval and adult muscles (Fig.8). In adult heads, the first optic neuropil, the lamina, and a certain layer of the medulla [presumably M5, (Fischbach and Dittrich, 1989)] show only very weak staining. This indicates that most synapses of Drosophila contain possibly all five but at least two synapsin isoforms, one of the 70–80 kDa triplet and one of the ∼143 kDa doublet. Photoreceptors R1-R6, which have their synapses in the lamina and at least some of the cells with synaptic terminals in or near layer M5 of the medulla (cf. Fischbach and Dittrich, 1989), contain no or very little of the presently known synapsin homolog isoforms.
DISCUSSION
We have cloned and characterized a gene that encodes proteins with a domain of 309 amino acids that shows 50% identity to the C domain of vertebrate synapsins. To our knowledge, this represents the first invertebrate gene with homology to the synapsin phosphoprotein family. Antibody cross reactivity had suggested previously the existence of synapsin-like proteins in Drosophila (Mitschulat, 1989) andAplysia (Bongiovi et al., 1992). The fact that the homology between synapsins of vertebrates and Drosophila is restricted to the C domain indicates that this domain is crucial for conserved functions of the synapsins. The interactions of vertebrate synapsins with both the synaptic vesicle membrane and the cytoskeleton have been attributed to this domain, which is common to all known synapsin isoforms (Huttner et al., 1983; Schiebler et al., 1986;Bähler and Greengard, 1987; Südhof et al., 1989; Ceccaldi et al., 1995). Thus, our results further support the notion that basic mechanisms of synaptic transmission and its regulation have been conserved in evolution of both invertebrates and vertebrates.
Transcripts of the Syn gene
None of the cDNAs isolated so far appears to be full-length. An extensive poly-A tail preceded at the normal distance of 20–30 bp by the polyadenylation consensus signal (Proudfoot and Brownlee, 1976;Birnstiel et al., 1985) is not found in any of the isolated cDNAs. Rather, they either terminate at internal EcoRI sites, indicating that these had been incompletely methylated beforeEcoRI linker attachment during construction of the cDNA library, or their 3′ ends reside within adenin-rich stretches that may lend themselves to internal oligo-dT priming during first-strand cDNA synthesis. At the 5′ end, no clustering of cDNA terminations is observed and no canonical TATA-box is found in the genomic sequence immediately upstream of the longest cDNA (Syn-1). Thus, the data are consistent with the proposition that the 5.5 kb Northern signal represents both mRNAs corresponding to Syn-1 and Syn-2 if we assume that they differ only by the four bases between the alternative splice sites of introns 10 and 10a (Fig. 4). Several possibilities exist for the interpretation of the 1.9 kb Northern signal. It may be caused by alternate transcription initiation, termination, or splicing, leading to an mRNA that, for unknown reasons, is not represented among the 20 cDNAs isolated from two libraries so far; it may correspond to a degradation product of the 5.5 kb mRNA; or it may represent an unspecific signal from rRNA not completely removed by polyA+ RNA preparation. Considering the high-stringency wash conditions of the Northern blots, we reject the speculation that the 1.9 kb signal might represent an mRNA from a homologous gene, because such a gene would have been detected in low-stringency Southern blots (data not shown). The two splice variants described here were represented in one library (from WT Berlin) with nine and three copies, respectively; in the other library (from WT Canton-S), only the major variant was found (8 independent isolates). The extra BamHI site in all three cDNAs of the minor splice variant is conspicuous, but unless this is a mere coincidence, there seems no simple interpretation. The question whether the 95 amino acids of the shifted reading frame of exon 11 may be found in one of the stable synapsin homolog isoforms can only be answered by protein sequencing or generation of antibodies against this 95 amino acid domain. Several of the cDNAs isolated here show at their 5′ or 3′ ends short sequences not detected in any other cDNA or the genomic walk of 56 kb (either by sequencing or by hybridization). Because the transitions from verified to unique sequences exhibit no similarity to the exon–intron boundary consensus, these sequences were considered to be attributable to artefactual ligation of unrelated cDNA fragments during generation of the cDNA libraries and therefore were omitted from the cDNAs shown.
The SYN proteins
Figure 9 illustrates our working hypothesis explaining how three of the five SYN isoforms seen in Western blots might derive from the two known cDNAs Syn-1 and Syn-2. SYN1-RT is assumed to correspond to one of the 143 kDa doublet isoforms, SYN1-S to the 74 or the 80 kDa isoform, and SYN2 to the 70 kDa isoform. The remaining two isoforms might represent post-translational modifications of SYN1-RT and either SYN1-S or SYN2. Because no reliable information on the actual translation start in the fly is available, the protein sizes given in Figure 9 have been calculated by using the first ATG or the first CTG (in parentheses) after the 5′ delimiting stop (TAA). CTG has been described as an alternative translation start codon in Drosophila (Sugihara et al., 1990; Boyd and Thummel, 1993). The four bases upstream of both of these codons show high similarity to the translation initiation consensus ofDrosophila genes (Cavener, 1987).
Amber suppression in E. coli supports hypothesis of UAG read-through in the fly
The hypothesis of Figure 9 is strongly supported by the analysis of the GST fusion proteins in sup− and sup+ E. coli strains (Fig. 7). TheMr values for Western signals of fusion proteins in E. coli (5′-FP, 78 kDa; 3′-FP, 66 kDa; RT-FP, 150 kDa) primarily conform to the calculated values (75, 61, and 120 kDa, respectively), except that the largest read-through protein band is ∼30 kDa too large. This led to the intriguing observation that the difference between the TAG-terminated and the largest read-through fusion protein signals in E. coli (150 − 78 = 72 kDa) closely corresponds to the difference between the 70/74/80 kDa triplet and the ∼143 kDa doublet signals in the head homogenates. Because the antibodies demonstrate that the ∼143 kDa proteins apparently contain sequences encoded by both the 5′ and the 3′ reading frame of Syn-1 and because among 11 cDNAs containing both of these reading frames none without the internal TAG stop was found, our working hypothesis incorporates the assumption that, in Drosophila, the UAG stop codon of the mRNA corresponding to cDNA Syn-1 is read through by a tRNA-directed mechanism with an efficiency of ∼20–25% (compare Fig.7c). Trivial alternative explanations for the TAG stop, such as cloning or sequencing artifacts, can be excluded because the stop codon was verified in 11 independent cDNAs, in genomic clones of different fly strains, and directly in PCR-amplified native DNA. A stretch of 443 contiguous amino acid codons downstream of a stop codon is highly likely to accumulate nonsense mutations unless it is translated into a polypeptide that serves some fitness-relevant function. tRNA-directed read-through represents a hypothesis that is compatible with all present data. The possibility of natural nonsense suppression in higher eukaryotes, in particular in the kelchgene of Drosophila, has been observed previously (Geller and Rich, 1980; Hatfield, 1985; Xue and Cooley, 1993). In addition, it has been demonstrated that a tRNAGtyr isolated from wild-typeDrosophila is capable of directing substantial TAG read-through of tobacco mosaic virus RNA in a heterologous test system, whereas tRNAQtyr is not (Bienz and Kubli, 1981), indicating that cellular tRNA base modification may regulate read-through translation (Beier et al., 1984). Germ line transformation of Drosophila with in vitromutagenized rhodopsin genes demonstrated differential UAG suppression, albeit at very low efficiency, depending on the nucleotide sequence surrounding the stop codon (Washburn and O’Tousa, 1992). Recently it has been suggested that two nonsense mutations in the elavlocus are read through at relatively high efficiency by an as yet unknown mechanism (Samson et al., 1995). The perfect or near-perfect match of the four nucleotides upstream of the read-through stop codon in the kelch gene, the elav mutant, and theSyn gene may be more than coincidental. Alternative hypotheses to read-through, such as the existence of an edited (Cattaneo, 1991; Sommer et al., 1993; Ruano et al., 1995) or differently spliced mRNA that is not represented among the 20 cDNAs isolated so far, seem less likely but can at present not be excluded. If verified by direct protein sequencing, the molecular mechanism of the proposed TAG read-through in Drosophila and the features of its regulation can be investigated by site-directed mutagenesis, germ line transformation, and expression analysis of the Syngene. It should be clear, however, that the current interpretation of the Western signals in fly head homogenates (Fig. 9) must remain tentative as long as direct protein sequence data, information on post-translational modifications, and selective mutants or transformants are unavailable.
Tissue distributions of SYN isoforms
The fact that nearly all synapses show the same relative staining intensity, whether the antibody used recognizes ORF1 or ORF2, indicates that small and large Drosophila synapsin homolog isoforms are expressed at abundance ratios similar to those shown in the Western blots, that is, approximately 4 to 1. The low or absent expression in photoreceptors and some synapses in the medulla intriguingly corresponds to similar findings in the vertebrate retina, where lack of synapsins has been reported for “ribbon” synapses of photoreceptors and bipolar cells (DeCamilli et al., 1990; Mandell et al., 1990). In view of the many different aspects for which there is similarity or analogy in the structure and distribution of synapsins in vertebrates and of the Drosophila synapsin homolog, it seems quite likely that there also is a functional correspondence. The targeted deletion of the Syn gene therefore is presently attempted.
Footnotes
This work was funded by Deutsche Forschungsgemeinschaft Grants Bu 566/6 to E.B. We thank Drs. P. C. Emson for the kind gift of neuropeptide antisera, B. Schmidt for one of the cDNA libraries, S. Albert for RNA blots, D. Dudaczek for excellent technical help, C.-F. Wu and T. Südhof for valuable comments on this manuscript, and M. Heisenberg for his permanent support throughout this project. Some of the fly strains used in this work were kindly provided by theDrosophila Stock Centers at Umea, Sweden, and Bloomington, IN.
B.R.E.K. and G.H. have contributed equally to this publication.
Correspondence should be addressed to Dr. Erich Buchner, Theodor-Boveri Institut für Biowissenschaften, Lehrstuhl für Genetik, Am Hubland, D-97074 Würzburg, Germany.
Dr. Heimbeck’s present address: Institut de Zoologie, Universitéde Fribourg, Pérolles, CH-1700 Fribourg, Switzerland.
Dr. Hofbauer’s present address: Institut für Zoologie, Universität Regensburg, Universitätsstrasse 31, D-93047 Regensburg, Germany.
Dr. Reifegerste’s present address: Department of Biological Sciences, University of Southern California, Los Angeles, CA 90089-1340.