* Leibniz Institute for Neurobiology, D-39118 Magdeburg, Germany; Institute for Cellular Biochemistry and Clinical
Neurobiology, University of Hamburg, D-20246 Hamburg, Germany; § Institute for Human Genetics, Medical Faculty, Otto von
Guericke University, D-39120 Magdeburg, Germany;
Institute for Pharmacology and Toxicology, Medical Faculty, Otto von
Guericke University, D-39120 Magdeburg, Germany; and ¶ Department of Neurobiology, University of Alabama at Birmingham,
South Birmingham, Alabama 35213-0021
![]() |
Abstract |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
The molecular architecture of the cytomatrix of presynaptic nerve terminals is poorly understood. Here we show that Bassoon, a novel protein of >400,000 Mr, is a new component of the presynaptic cytoskeleton. The murine bassoon gene maps to chromosome 9F. A comparison with the corresponding rat cDNA identified 10 exons within its protein-coding region. The Bassoon protein is predicted to contain two double-zinc fingers, several coiled-coil domains, and a stretch of polyglutamines (24 and 11 residues in rat and mouse, respectively). In some human proteins, e.g., Huntingtin, abnormal amplification of such poly-glutamine regions causes late-onset neurodegeneration. Bassoon is highly enriched in synaptic protein preparations. In cultured hippocampal neurons, Bassoon colocalizes with the synaptic vesicle protein synaptophysin and Piccolo, a presynaptic cytomatrix component. At the ultrastructural level, Bassoon is detected in axon terminals of hippocampal neurons where it is highly concentrated in the vicinity of the active zone. Immunogold labeling of synaptosomes revealed that Bassoon is associated with material interspersed between clear synaptic vesicles, and biochemical studies suggest a tight association with cytoskeletal structures. These data indicate that Bassoon is a strong candidate to be involved in cytomatrix organization at the site of neurotransmitter release.
Key words: trinucleotide repeats; mouse bassoon gene; presynaptic terminals; rat brain; synapses ![]() |
Introduction |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
CHEMICAL synapses are sites of cell-cell contact between neurons mediating interneuronal communication. Both the presynaptic terminal and the
postsynaptic compartment comprise a highly specialized cytoskeleton underlying the synaptic membranes (Burns
and Augustine, 1995). This cortical cytoskeleton, together
with cell adhesion molecules and components of the extracellular matrix, act to keep pre- and postsynaptic compartments in register (Hall and Sanes, 1993
; Burns and Augustine, 1995
; Garner and Kindler, 1996
). At the postsynaptic
side, an electron-dense meshwork of fine filaments, the
postsynaptic density (PSD)1, underlies the membrane, and
is thought to anchor and cluster neurotransmitter receptors.
Molecules involved in this function include rapsyn/43K protein at the cholinergic neuromuscular junction (Froehner,
1991
), gephyrin at glycinergic synapses, and SAP90/PSD-95, chapsyn-110/PSD-93, and SAP102 at glutamatergic central
synapses (Garner and Kindler, 1996
; Kirsch et al., 1996;
Kennedy, 1997
).
The presynaptic nerve terminal is the principal site of
regulated neurotransmitter release. The region of the presynaptic plasmalemma over which synaptic vesicles dock,
fuse, and release neurotransmitter is called the active zone
(Landis et al., 1988). Typically, several hundred synaptic
vesicles are localized in the vicinity of the active zone
(Burns and Augustine, 1995
). Although a number of proteins that are involved in synaptic vesicle fusion and endocytosis have been identified and characterized (Südhof, 1995
; De Camilli and Takei, 1996
), the cellular mechanisms restricting synaptic vesicle fusion to the active zone
remain unclear. It is reasonable to assume that the cytomatrix at the active zone is intimately involved in determining the sites of synaptic vesicle fusion.
To date, only few cytomatrix proteins have been identified that may play a role in this process. One candidate
protein is synapsin I, which has been reported to link synaptic vesicles to the presynaptic cytoskeleton (Landis et al.,
1988; Hirokawa et al., 1989
). Further candidates are members of the family of membrane-associated guanylate kinase homologues (MAGUKs), the Rab3 effector protein
Rim, and the presynaptic cytomatrix component Piccolo.
MAGUKs, including synapse-associated proteins SAP90/ PSD-95, SAP97, and chapsyn-110/PSD-93, are found in
distinct presynaptic terminals, and bind and cluster presynaptic ion channels in vitro (Kistner et al., 1993
; Kim
et al., 1995
; Müller et al., 1995
; Kim et al., 1996
). In addition, presynaptic MAGUK expression appears to be essential for the proper assembly of the neuromuscular synapse in Drosophila (Budnik et al., 1996
; Thomas et al.,
1997a
; Thomas et al., 1997b
). However, to date no specific
function in synaptic vesicle docking and fusion could be
assigned to MAGUKs. Rim is a large presynaptic zinc-finger protein that interacts with Rab3 in its GTP (but not
GDP)-bound form and, when transfected into PC12 cells,
enhances regulated exocytosis in an Rab3-dependent manner (Wang et al., 1997
). Piccolo, a recently identified
420-kD cytoskeleton-associated protein, has been detected
primarily within presynaptic nerve terminals of asymmetric type I synapses (Cases-Langhoff et al., 1996
), but to
date its function is unknown. Both Rim and Piccolo are
highly enriched in synaptic junctional protein preparations (Cases-Langhoff et al., 1996
; Wang et al., 1997
).
In this study we have identified a novel protein that is
found in the presynaptic compartments of rat brain synapses. It appears exquisitely localized to the area just proximal to the active zone. We refer to this protein as Bassoon, a
novel member of the ensemble of presynaptic proteins that
are involved in orchestrating events at the nerve terminal.
Bassoon has two double-zinc finger domains known to be involved in protein-protein interactions (Sanchez-Garcia, 1994), three presumptive coiled-coil regions, and a stretch of 11 (mouse)-24 (rat) glutamine residues, most of them encoded by CAG repeats. This latter feature is shared, for example, with Huntingtin or the ataxins (for review see Reddy
and Housman, 1997). Abnormal expansion of the CAG/
glutamine repeats in these genes/proteins is involved in a
number of human genetic disorders, including Huntington's
disease or autosomal dominant cerebellar ataxias, that are
characterized by late onset of degeneration of particular groups of neurons (Reddy and Housman, 1997
).
![]() |
Materials and Methods |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Cloning and Sequence Analysis of Rat Bassoon cDNA and Mouse bassoon Gene
The cDNA clone sap7f was isolated from a gt11 expression library with
polyclonal antibodies generated against a rat brain synaptic junction preparation as described previously (Kistner et al., 1993
; Langnaese et al., 1996
).
Overlapping cDNA clones were obtained by several rounds of screening of
gt10 (CLONTECH Laboratories, Inc., Palo Alto, CA) and
ZAP II (Stratagene, La Jolla, CA) adult rat brain cDNA libraries with the 32P-labeled sap7f
cDNA or mouse genomic clones. Parts of the mouse genomic Bassoon DNA
were isolated by screening a 129 SVJ mouse genomic
FIXII library (Stratagene) with rat Bassoon probes. Deoxyoligonucleotides were derived from
exon 4 sequences (5'-TGTTTTAGGAGTCCCAGGAGGCA-3'; 5'-TGAAGCAGAAAGGGCCACAGGGG-3'), and were used to identify
P1 phages containing the bassoon gene by PCR (129 SVJ mouse genomic P1
library; Genome Systems Inc., St. Louis, MO). Exon-containing fragments were identified with rat Bassoon cDNA probes on Southern blots, isolated
from agarose gels, and subcloned into pBluescript (Stratagene). Hybridization to
-phage bound to Hybond N filters was carried out at 65°C in Rapid-hyb buffer (Amersham Corp., Arlington Heights, IL) as described by the supplier. Sequencing of the cDNA clones subcloned into pBluescript vectors was
performed using the fluorescent dye dideoxy termination method in combination with an automated DNA sequencer (Applied Biosystems, Inc., Foster
City, CA). Sequences were analyzed with the GCG program package
(Genetics Computer Group, Inc., Madison, WI).
Antibody Production
The cDNA insert of sap7f (733 bp) was subcloned into the unique EcoRI
site of the bacterial expression vector pGEX-1T (Pharmacia Biotech
Sverige, Uppsala, Sweden). A 75-kD glutathione S-transferase (GST)-
Bassoon fusion protein was expressed in Escherichia coli XL Blue and purified on glutathione-sepharose 4B as described by the manufacturer
(Pharmacia Biotech Sverige). The fusion protein was used to generate
Bassoon antibodies in mice and rabbits. The IgG fraction of rabbit antisera was isolated using GammaBind Plus SepharoseTM (Pharmacia Biotech
Sverige) following the instructions of the manufacturer. The monoclonal
antibody mab7f was produced by the Univeristy of Alabama at Birmingham hybridoma facilities. Antibodies against Piccolo were generated as
described previously (Cases-Langhoff et al., 1996
). Rabbit antiserum
against synapsin I was provided by Dr. M. Mäder, Göttingen, Germany.
Monoclonal antibody against synaptophysin was purchased from Boehringer Mannheim (Mannheim, Germany).
RNA Preparation, Northern Analysis, and In Situ Hybridization
Isolation of total RNA from several rat tissues as well as Northern blotting and hybridization with 32P-labeled sap7f cDNA probes was performed as described (Langnaese et al., 1997).
In situ hybridization experiments were performed as described previously (Langnaese et al., 1997) with a 40-mer antisense oligonucleotide derived from the Bassoon cDNA (5'-ACAGCGGTGTCGTCTTCCTCCAAGTTGTCTTCCTCGGCGC-3'). Identical results were obtained with
three independent oligonucleotides. Controls including competition with
100-fold excess of unlabeled oligonucleotide, RNAase treatment of sections
before hybridization or hybridization with sense probe did not yield any
specific signal (see Fig. 1 C). Hybridization signals were visualized with a
Fujix BAS 3000 Bio Imager (Fuji Photo Film Co., Ltd., Tokyo, Japan).
|
Chromosomal Localization of the Mouse bassoon Gene
For mapping the mouse bassoon gene, fluorescence in situ hybridization
(FISH) on mouse metaphase chromosomes was performed using standard
protocols (Lichter and Cremer, 1992). A mixture of four biotin-labeled
genomic clones in pBluescript containing in total 46 kb of the mouse bassoon
gene were hybridized to metaphase preparations from mouse embryonic fibroblast cultures. Signals were detected and amplified using biotin-conjugated anti-avidin antibody (5 µg/ml) and fluorescein-avidin (5 µg/ml). The
slides were counterstained with Vecta-Shield/DAPI (Vector Labs, Inc., Burlingame, CA). Signal detection and imaging were achieved using a DMRB/E
photomicroscope (Leica Mikrosysteme GmbH, Bensheim, Germany) and
the Cytovision system (Applied Imaging, Santa Clara, CA). Mouse chromosomes were identified by inverted DAPI banding.
Isolation of Subcellular Protein Fractions and Immunoblot Analysis
Tissue fractionation was carried out essentially as described by Carlin et
al. (1980) with some modifications: brains of 30-d-old rats were homogenized in homogenization buffer (5 mM Hepes, pH 7.4; 320 mM sucrose)
containing a protease inhibitor cocktail (Boehringer Mannheim, Mannheim, Germany); cell debris and nuclei were removed by 1,000 g centrifugation. The supernatant was spun for 20 min at 13,000 g, resulting in supernatant S2 and pellet P2 (crude membrane fraction). S2 was centrifuged
at 100,000 g for 1 h, and the resulting supernatant was taken as cytoplasmic fraction (S100). The P2 pellet was further fractionated by centrifugation in a sucrose step gradient as described by Carlin et al. (1980)
. For isolation of the synaptic junctional proteins (PSD fraction), the synaptosomal
fraction of the first gradient was diluted with 320 mM sucrose (60 ml/10g wet
tissue) and an equal volume of 1% Triton X-100, 320 mM sucrose, and 12 mM
Tris-HCl, pH 8.1. The suspension was kept on ice for 15 min, and was centrifuged for 30 min at 32,800 g. The pellet was resuspended in 320 mM sucrose, 1 mM NaHCO3 (6 ml/10 g wet tissue), and an equal volume of 1% Triton
X-100. 320 mM sucrose was added, and synaptic junctional proteins were pelleted by a 2-h centrifugation at 201,800 g. All steps were carried out at 4°C.
Extraction experiments of P2 pellets with various agents as specified in
Table I were performed in the following way: P2 pellets were resuspended
in homogenization buffer, aliquoted into six samples (200 µg protein each),
and centrifuged at 15,000 g for 20 min. Each pellet was then resuspended in
0.5 ml of one of the extraction buffers, incubated for 15 min at 4°C by gentle shaking, and centrifuged again for 15 min at 100,000 g. The resulting pellets were washed in homogenization buffer and dissolved in 80 µl gel-loading buffer (Laemmli, 1970). The supernatants were precipitated with
trichloro acetic acid, and the resulting pellets were dissolved in 80 µl loading buffer. For SDS-PAGE, 20 µl/lane of each fraction were loaded. Proteins were separated on 5-20% polyacrylamide gels under fully reducing
conditions, and were transferred onto nitrocellulose. For immunodetection, Western blots were incubated overnight with primary antibody and
processed using the ECL detection system (Amersham Buchler, Braunschweig, Germany).
|
Preparation and Immunofluorescence Microscopy of Primary Hippocampal Cultures
Hippocampal cultures were prepared and grown on coverslips as described
by Goslin and Banker (1991), washed in PBS (0.9% NaCl; 100 mM sodium
phosphate buffer, pH 7.4), fixed with methanol at
20°C for 15 min, and
blocked with 5% (vol/vol) FCS in PBS for 30 min. For immunofluorescence
double-labeling experiments, cultures were incubated overnight with rabbit
or mouse anti-Bassoon antibodies (1:250 dilution) and either a monoclonal
antibody against synaptophysin (1:10 dilution; Boehringer Mannheim) or a
polyclonal anti-Piccolo antiserum (1:1,000 dilution; Cases-Langhoff et al.,
1996
) at 4°C in 5% FCS in PBS. After three washes in PBS, coverslips were
incubated overnight at 4°C with goat anti-mouse and anti-rabbit IgG antibodies conjugated with either fluorescein, Cy3, or Cy2 (Jackson ImmunoResearch Laboratories, Inc., West Grove, PA). Secondary antibodies
were diluted 1:100 in 5% FCS in PBS. Photographs were taken using an Aristoplan photomicroscope (Leitz, Wetzlar, Germany).
Immunohistochemistry of Tissue Sections
30-d-old male rats were used for immunohistochemical studies. Tissue preparation for microscopic analysis was done as described (Richter et al., 1996).
Sections were incubated for 2 d at room temperature with mab7f Bassoon
antibody (1:5,000 dilution) in combination with rabbit antiserum against synapsin I (1:500 dilution). After three washes with PBS, application of secondary antibodies coupled to Cy3 or Cy2 followed for 1 h at room temperature.
Secondary antibodies were diluted 1:250 when coupled to Cy3, and 1:100
when coupled to Cy2. Both possible combinations of secondary antibodies, i.e., anti-rabbit Cy2/anti-mouse Cy3 and anti-rabbit Cy3/anti-mouse Cy2,
were used to exclude fluorescent dye effects and yielded identical results.
Analysis was done by confocal microscopy (TCS4D; Leica Mikrosysteme
GmbH) and scans in several consecutive layers were saved as single images.
Immunoelectron Microscopy
30-d-old male rats were used for immunohistochemical studies. Tissue
preparation for electron microscopic analysis was done as described by
Richter et al. (1996). To test for nonspecific immunolabeling, sections
were incubated exactly as described above, but in the absence of the first
antibody, with preimmune rabbit serum or with an antibody solution that
was preincubated with the fusion protein (2.3 mg/ml). In no case was any
nonspecific immunoreactivitiy observed.
Localization of Bassoon in isolated synaptic structures with gold-conjugated antibodies was done using a modified protocol of De Camilli et al.
(1983b). In brief, cortex and cerebellum from P30 rat brain were homogenized in homogenization buffer (0.25 M sucrose, 25 mM KCl, 5 mM
MgCl2, 2 mM EGTA in 10 mM phosphate buffer, pH 7.4) and centrifuged
for 10 min at 1,000 g to remove nuclei and cell debris. The supernatant (5 ml) was mixed with 35 ml fixation buffer (3% paraformaldehyde, 0.1% glutardialdehyde in 5 mM phosphate buffer), kept on ice for 30 min, and spun
at 13,000 g for 45 min. The resulting pellet was rehomogenized in 0.6 ml of 5 mM phosphate buffer (pH 7.4), mixed with an equal volume of prewarmed
2% agarose in 5 mM phosphate buffer, and gently poured into coverslip
frames. The agarose blocks were cut into 60-µm slices using a vibratom (Leica
Inc., Deerfield, IL) and incubated for 30 min at room temperature in PBS
containing 5% BSA and 0.1% CWF skin gelatin (Aurion) to block nonspecific binding. After this preincubation, sections were incubated overnight
with rabbit anti-Bassoon antibody diluted 1:100 in PBS containing 0.1% BSA-C (Aurion, Wageningen, The Netherlands) and 0.2% sodium azide at
room temperature. The sections were rinsed in BSA-C/PBS (3 × 10 min)
and incubated with 50-fold diluted anti-rabbit IgG gold conjugate (5 nm;
Sigma Chemical Co., St. Louis, MO) in BSA-C/PBS for 4 h. After extensive
washing in PBS, sections were postfixed in 2% glutardialdehyde in PBS (15 min), and in 1% osmium tetroxide in PBS for 1 h. Further preparation for
electron microscopic analysis was performed as described by Richter et al.
(1996)
. The ultrathin sections were examined with a Leo912 electron microscope (Leo Elektronenmikroskopie GmbH, Oberkochen, Germany) and
imaged with a Megascan 2K CCD camera (Gatan, Inc., Plasanton, CA)
using the digital micrograph Gatan 2.5 software.
![]() |
Results |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Identification of Bassoon
In search for new components of central nervous system
synapses, we have used rabbit antisera against brain synaptic junctional protein preparations to screen a rat brain
cDNA expression library (Garner et al., 1993; Kistner et al.,
1993
; Langnaese et al., 1996
). One of the isolated clones,
sap7f, contained a 733-nucleotide-long cDNA insert with a
continuous open reading frame; its sequence did not resemble that of any known protein. Northern hybridization of sap7f cDNA probes to RNA preparations from 30-d-old
rats revealed a band at ~13 kb in the brain, but not in liver,
heart, skeletal muscle, or C6 glioma cells (Fig. 1 A), nor in
testis, kidney, spleen, or thymus (data not shown). To
determine the transcript distribution in the brain, in situ
hybridization experiments were performed with a 35S-
labeled antisense oligonucleotide probe. As shown in Fig.
1 B, sap7f transcripts are widely expressed in the rat brain
with highest levels in the cerebellum, the hippocampal formation, the piriform cortex, and the cerebral cortex. Application of 100-fold excess of unlabeled oligonucleotide
specifically blocked hybridization signals (Fig. 1 C).
Starting with sap7f cDNA as probe, a set of overlapping
clones spanning the entire protein coding region and parts
of the untranslated regions of the corresponding mRNA
was isolated from rat brain cDNA libraries (Fig. 2 A).
Moreover, recombinant - and P1-phages were isolated
containing the murine bassoon gene, and its exon-intron
organization was determined by comparing mouse genomic DNA and rat cDNA. The gene has at least 13 exons, 10 of which harbor the entire open reading frame for
Bassoon (Fig. 2 B). The positions of these introns with respect to the protein sequence are indicated in Fig. 3 A. Interestingly, approximately half of the cDNA sequence is
contained in the large exon 5 (6.6 kb). The gene displays a
rather compact structure in the region of exons 4-11 containing only introns <2 kb. In contrast, exons 1, 2, and 3 are spaced by larger introns. The 5' end of the gene has
not yet been identified. Using FISH, the bassoon gene has been mapped to mouse chromosome 9F (data not shown).
|
|
As deduced from the nucleotide sequences, the encoded
protein, hereafter referred to as Bassoon, consists of 3938 and 3942 amino acid (aa) residues in rat and mouse, respectively (Fig. 3 A), and has a calculated Mr of ~420 kD.
The overall sequence identity of the two proteins is 96%.
The putative initiation site for translation in rat and mouse
(CCACCAUGG) favorably coincide with the consensus
motif described for vertebrates (Kozak, 1987). In rat
cDNA the putative start codon is preceded by an in-frame stop codon. Comparison of nucleotide and deduced amino
acid sequences to public databases showed that Bassoon
has no significant overall similarity to any known protein.
However, computer analysis of the predicted amino acid
sequence revealed that Bassoon harbors two zinc-finger
domains (aas 162-223 and 457-518 in rat), each with two
zinc-finger motifs. The two Bassoon motifs share a higher degree of sequence identity with each other (47%) than
with the zinc fingers of any other protein included in public
databases (Fig. 3 B). The most closely related double zinc
fingers are those of rabphilin, the rabphilin-related protein
Noc2, and the Rab3a-interacting molecule Rim. Between
aas 568 and 588 of the rat sequence, a region of three consecutive heptad repeats occurs. The corresponding region
of murine Bassoon contains two additional repeats of this motif (consensus sequence: K-A-S-P-Q-A/T-A/T/K). Proximal to the COOH terminus (rat aa 3775-3799), a stretch of
24 consecutive glutamine residues is predicted (Fig. 3 A).
Nineteen of these glutamines
14 consecutive ones
are
encoded by CAG triplets. Interestingly, the number of
glutamines in murine Bassoon (11 residues; Fig. 3 A) differs
from that in rat. A computer-assisted examination of secondary structure of Bassoon predicts long
-helical regions. In particular for three regions high probabilities for coiled-coil structures are predicted (Figs. 2 A and 3 A).
To characterize the protein encoded by the Bassoon transcript, rabbit polyclonal antisera and a mouse monoclonal antibody, mab7f, were generated against a recombinant fusion protein containing the sap7f-encoded polypeptide fragment. On immunoblots of rat brain membrane fractions, these antisera detect two major protein bands of >400 and 350 kD (Fig. 4). In addition, a number of smaller immunoreactive bands are detectable. We assume that mature Bassoon migrates at >400 kD, while the other protein bands are proteolytic degradation products. This assumption is based on several observations: (a) the apparent molecular mass of >400 kD favorably coincides with the calculated Mr of ~420,000; (b) Two rabbit antisera and mab7f recognize a similar protein pattern on immunoblots (not shown), and yield identical results in immunohistochemistry (see below); (c) Both the number of bands <400 kD and their relative intensity as compared with that of the largest polypeptide varied from preparation to preparation (data not shown). (d) Northern analyses using probes derived from different regions of the Bassoon cDNA did not detect additional Bassoon transcripts in the adult brain, suggesting that the smaller polypeptides are not products from alternatively processed transcripts.
|
Bassoon is a Synaptic Protein
As the sap7f cDNA was isolated using antibodies against
synaptic junctional protein preparations, we sought to examine whether Bassoon actually copurifies with these
preparations, and how its subcellular distribution compares to that of other synaptic proteins. These include the
presynaptic cytomatrix component Piccolo (Cases-Langhoff et al., 1996), the PSD protein SAP102 (Müller et al.,
1996
), the integral synaptic vesicle protein synaptophysin
(Wiedenmann and Franke, 1985
), and the vesicle- and cytoskeleton-associated protein synapsin I (De Camilli et al.,
1983a
, De Camilli et al., 1983b
). Bassoon immunoreactivity is present in the crude membrane (P2) fraction of rat
brain (Fig. 4, lane 2), but not in the soluble protein fraction
(Fig. 4, lane 1). During subcellular fractionation of brain
tissue by differential centrifugation, Bassoon immunoreactivity is enriched in the synaptosomal fraction, detergent-extracted synaptosomes, and the synaptic junctional protein fraction (Fig. 4, lanes 5-7), the so-called PSD fraction
that contains elements of both the postsynaptic and the presynaptic apparatus (Langnaese et al., 1996
; Ziff, 1997
).
Bassoon is absent from the myelin fraction (Fig. 4, lane 3),
while some immunoreactivity is found in the light membrane fraction (lane 4) that is supposed to include a considerable percentage of synaptic vesicles. Piccolo and the postsynaptic marker protein SAP102 copartition with Bassoon (Fig. 4). Synapsin also shows a similar distribution
but, in contrast to the other three proteins, could be extracted from the synaptic junctional protein preparation
with 150 mM KCl (data not shown). This fact indicates the
different type of association of synapsin with synaptic
structures. As expected, synaptophysin is absent from the
synaptic junctional protein fraction (Fig. 4).
The above biochemical data suggest that Bassoon is a
synaptic protein. This hypothesis was tested by performing double-fluorescence immunocytochemistry on primary
cultures of hippocampal neurons using Bassoon antibodies
in combination with antibodies against synaptic marker
proteins. As shown in Fig. 5, A and B, Bassoon displays a
punctate distribution on hippocampal neurons cultured for 21 d in vitro that is virtually identical to that of the synaptic vesicle protein synaptophysin (Wiedenmann and
Franke, 1985). Also, Piccolo, a component of the presynaptic cytomatrix primarily of asymmetric type I synapses
(Cases-Langhoff et al., 1996
), is essentially co-distributed
with Bassoon in processes of hippocampal neurons (Fig. 5,
C and D). These observations support the view that Bassoon is a synaptic protein.
|
We next determined the distribution of Bassoon as compared with synapsin I (Fig. 6) and synaptophysin (not
shown, data are similar to that of synapsin) in rat brain sections by immunofluorescence microscopy. As an example,
the hippocampal CA3 region was analyzed. At an intermediate magnification, synapsin and Bassoon appear largely
codistributed as indicated by the emergence of yellow mixed color of the two fluorescent dyes (Fig. 6, A-C; Cy2,
Bassoon; Cy3 synapsin). At a high magnification the two
antigens do not colocalize. Bassoon immunoreactivity appears as distinct little spots adjacent to unstained dendrites,
whereas synapsin displays a more homogeneous distribution within synaptic terminals (Fig. 6, D-K). A similar differential localization within presynapses has been observed
for Piccolo vs synaptophysin (Cases-Langhoff et al., 1996).
|
Bassoon is Associated with Presynaptic Structures of Hippocampal Synapses
The subsynaptic localization of Bassoon was further explored by immunoelectron microscopy on ultrathin sections from various regions of 30-d-old rat brain. In all preparations, Bassoon immunoreactivity was detected with both polyclonal antibodies and monoclonal antibody mab7f exclusively in presynaptic nerve terminals (Fig. 7). Generally the immunoreaction product is highly concentrated at sites of synaptic contact. For example, in excitatory mossy fiber terminals in the stratum lucidum of the hippocampal CA3 region, which make multiple contacts to postsynaptic neurons, Bassoon immunoreactivity is largely restricted to regions at the presynaptic membrane opposite to PSDs (Fig. 7 A). Figs. 7 B and C give examples of the distribution of Bassoon immunoreactivity at shaft and spine synapses in the stratum lucidum and the stratum moleculare of CA3, respectively. Again, immunoreactivity is very strong at the synaptic contact site, and at least the shaft synapses contain synaptic vesicles not surrounded by immunoreaction product.
|
To confirm further the presynaptic localization of Bassoon
we have applied immunogold electron microscopy to isolated synaptosomes. No specific labeling of synaptic structures was observed when the first antibody was omitted (Fig.
7 F), or when a rabbit antibody against the extracellular
matrix protein brevican (Seidenbecher et al., 1995) was used
(data not shown). As shown in Fig. 7 D, gold particles are restricted to the presynaptic element, and are interspersed between clear synaptic vesicles. In the presynaptic compartment, the distribution appears nonhomogeneous with the highest concentration of particles in the vicinity of the electron-dense material at the synaptic contact site, although
particles were barely found directly at the presynaptic membrane. It has to be noted that in using preembedding immunogold labeling, the nonhomogeneous distribution of
Bassoon in nerve terminals is not as obvious as when it is revealed by immunoperoxidase staining in situ (Figs. 7 A-C).
This fact may be due to the labeling method where gold- labeled antibodies can merely enter synaptosomes that are
open for some time during incubation, and thus may have
lost a fraction of their reserve pool vesicles. In this context it
is interesting that synaptic structures were observed that
have lost the plasma membrane around the presynaptic element during preparation (Fig. 7 E). In these structures clear
synaptic vesicles remain embedded in a network of amorphous material labeled with gold particles.
To assess the nature of Bassoon interaction with the presynaptic element, biochemical extraction studies were performed with various agents on the brain P2 crude membrane
fraction. Neither high-salt conditions, nonionic detergents
like Triton X-100 or Octylglucoside, nor zwitter ionic detergents such as CHAPS, are able to solubilize significant
amounts of Bassoon (Table I). In contrast, combinations of
CHAPS and high salt result in a partial solubilization of the
protein. Combinations of nonionic detergents and high salt
also lead to partial solubilization of Bassoon (data not
shown); however, under these conditions enhanced proteolysis is observed to hinder the reliable interpretation of the
results. One molar Tris-HCl that partly solubilizes spectrin
from the cortical cytoskeleton (Hayes et al., 1991) does not
release Bassoon. On the other hand, alkaline conditions that
typically bring peripheral membrane proteins into solution
also solubilize Bassoon, as do the chaotropic salt potassium
rhodanite, urea, or the ionic detergent SDS. These results indicate that Bassoon is not an integral membrane protein, but
tightly interacts with preparations of the membrane-associated cortical cytoskeleton.
![]() |
Discussion |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Bassoon is a novel protein expressed in brain. It contains
only few predictable structural features, including two
zinc-finger and three coiled-coil domains, and harbors a
stretch of polyglutamines encoded by CAG repeats. This
later feature makes the human BASSOON gene a candidate for an association with late-onset neurodegenerative diseases caused by expansion of CAG repeats (Reddy and
Housman, 1997). Bassoon copurifies with synaptic junctional protein preparations (PSD fraction)2 and is detected
in presynaptic nerve terminals of a variety of synapses.
Within nerve terminals, Bassoon immunoreactivity is found concentrated in patches underneath the plasma
membrane at regions located opposite to PSDs. This particular localization together with its biochemical characteristics is consistent with the hypothesis that Bassoon is
tightly associated with or an integral component of the presynaptic cytomatrix at the site of neurotransmitter release.
Lessons from the Primary Structure of Bassoon
Bassoon is a very large polypeptide consisting of 3938 (rat)
and 3942 (mouse) amino acid residues that do not belong
to any known protein family. Nonetheless, Bassoon contains a number of sequence motifs that allow some speculation concerning its functions. Two double zinc-finger
motifs are located in the amino-terminal part of Bassoon.
Multiple classes of zinc finger-containing proteins have
been described that are involved either in protein-nucleic acid or protein-protein interactions. The Bassoon zinc-finger motifs show some structural features related to LIM
(lin-11/ISL-1/mec-3-like) domains, a steadily growing family of structural motifs involved in protein-protein interactions (Sánchez-Garcia, 1994). Typically, LIM domains appear as double zinc fingers with a finger loop size of 17 ± 1 residues and a spacing of two amino acid residues between the two fingers. With sizes of 16 (first loop) and 14 amino
acids (second loop), the putative zinc fingers in Bassoon
almost match this LIM motif size. The spacing between
the two finger entities is four instead of two residues. Although Bassoon lacks a conserved coordinating histidine
in the first finger structure as well as some other characteristic amino acid residues characteristic for LIM domain
proteins, the structural features described above suggest a
role for the zinc finger motif in protein-protein interactions. This protein-protein interaction is underscored by
the fact that the Bassoon zinc-finger motifs show highest
similarity to the zinc fingers of rabphilin (Shirataki et al.,
1993), a protein known to interact with and regulate the
activity of the synaptic vesicle-associated small GTPase
Rab3 (for review see Südhof, 1997
). Interestingly, Rim,
another potential regulator of Rab3, also interacts with its
target via a zinc-finger domain (Wang et al., 1997
). The
sizes of the zinc-finger loops of rabphilin, its relative Noc2
(Kotake et al., 1997
), and Rim differ even more from those of
typical LIM-type domains than the lengths of Bassoon zinc
fingers. However, all four proteins share the four-amino acid
residue spacing between the two finger structures (see Fig. 3
B). Thus, the zinc fingers of Bassoon may interact with vesicle-associated proteins in the presynapse, and may potentially be involved in regulating the synaptic vesicle cycle.
Superhelix-forming coiled-coil domains are another
class of structural entities involved in inter- or intramolecular protein-protein interactions (Lupas, 1996). By computer analysis, Bassoon is predicted to have three coiled-coil-forming domains of various lengths that may play a
role in the interaction of Bassoon with other presynaptic proteins. Another remarkable feature is the region of heptad repeats (K-A-S-P-Q-A/T-X) that varies in length between rat (three copies) and mouse (five copies) Bassoon.
The repeats may serve as phosphorylation sites for proline-directed protein kinases, including stress-activated and mitogen-activated protein kinases (for review see Cohen,
1997
). Proline-directed protein kinases are known to phosphorylate and thereby regulate a number of cellular substrates, including cytoskeletal components such as neurofilament proteins in response to various kinds of extracellular
signals (Cohen, 1997
; Giasson and Mushynski, 1997
).
Intriguingly, proximal to the COOH-terminal end of
Bassoon is a polyglutamine region encoded by multiple
CAG codons. Also, this polyglutamine stretch is variable
in length between the two species. The presence of expanded CAG repeats in a number of genes has been described, and has been directly implicated in dominantly inherited neurodegenerative disorders characterized by
anticipation (for review see Reddy and Housman, 1997;
Ross, 1997
). These disorders include Huntington's disease
caused by CAG expansion in the HD gene; spinobulbar
muscular atrophy where the androgen receptor gene is affected; dentatorubral-pallidoluysian atrophy, and several types of spinocerebellar ataxias (Reddy and Housman,
1997
; Ross, 1997
). At present it is unclear whether the
CAG repeats in the BASSOON gene are associated with
any neurodegenerative disorder. Mapping of the mouse
bassoon gene to chromosome 9F did not immediately suggest a candidate gene, but clearly will facilitate the characterization and mapping of the human BASSOON gene-an
important first step in assessing its involvement in debilitating diseases.
Bassoon is Concentrated at the Presynaptic Active Zone
Bassoon exhibits a widespread synaptic distribution throughout the adult rat brain. High levels of Bassoon transcripts
are observed in several brain regions including the hippocampus and the cerebellum. We have analyzed several
types of synapses in these two brain regions for the distribution of Bassoon at the ultra-structural level. The most
striking feature is the restricted distribution of Bassoon
immunoreactivity within presynaptic terminals. This is
most obvious in the large mossy fiber boutons in the stratum lucidum of the hippocampal CA3 region. These large
fusiform expansions, filled with synaptic vesicles and mitochondria, are studded with excitatory synapses (Llinás and
Walton, 1990; Amaral and Witter, 1994
). Bassoon immunoreactivity is unevenly localized within these nerve terminals, and appears to be concentrated at regions of the
presynaptic bouton that are juxtaposed to the PSD. This
restricted localization contrasts with the much-wider distribution of other presynaptic proteins such as synapsin I
(De Camilli et al., 1983a
), synaptophysin (Wiedenmann
and Franke, 1985
; Kagotani et al., 1991
), syntaxin (Garcia
et al., 1995
), and SNAP-25 (Garcia et al., 1995
), and suggests a role for Bassoon in events occurring near or at the
active zone. Immunogold localization studies on isolated
synaptic structures support this view. Bassoon is found interspersed between a subpopulation of synaptic vesicles
proximal to the synaptic cleft. However, no or very few
Bassoon molecules appear to be associated directly with
the presynaptic membrane facing the synaptic junction.
Electron microscopic studies of the presynapse have revealed the presence of a fine filamentous network anchored to the junctional plasmalemma (Landis et al., 1988;
Hirokawa et al., 1989
). In synaptic junction preparations,
frequently vesicle-containing presynaptic structures that
are not wrapped by a plasma membrane are observed. We
assume that these structures represent the presynaptic cytomatrix that sticks to the junctional membrane as a gel-like amorphous network. Bassoon molecules are included
in this cytomatrix.
In a recent study we described another presynaptic protein called Piccolo (Cases-Langhoff et al., 1996). This 420-kD
protein is also found in a wide variety of presynaptic terminals throughout rat brain. This observation, as well as
the colocalization of Piccolo and Bassoon in cultured hippocampal neurons shown here, implies that both proteins
can occur in an overlapping, if not identical, set of synapses. Interestingly, the subsynaptic localization of Piccolo
in asymmetric type I synapses, e.g., in hippocampal mossy
fiber terminals, is virtually identical to that described here
for Bassoon, suggesting that both proteins are concentrated near the active zone of the same synapse.
Immunogold localization studies presented here and in
a previous paper (Cases-Langhoff et al., 1996) raise the
question as to whether Bassoon and Piccolo may directly
interact with synaptic vesicles. Immunoreactivity of both
proteins is found in the light membrane fraction (see Fig.
4) which includes a major fraction of synaptic vesicles. Preliminary experiments suggest that Bassoon is present in
crude conventional vesicle preparations as described by
Huttner et al. (1983)
. There is, however, no enrichment of Bassoon immunoreactivity in this fraction, and at present
we cannot exclude that Bassoon partitions into this fraction
as a contamination (Sanmartí-Vila, unpublished observation). In any case, association with detergent-insoluble
cytomatrix is much stronger than with detergent-soluble
membrane fractions.
Possible Functional Implications
The restricted localization of Bassoon and Piccolo suggests that they serve specific functions at synaptic junctions. Both proteins are components of the presynaptic cytomatrix. As such they may play a role in the structural
and functional organization of the synaptic vesicle cycle,
i.e., the release of neurotransmitter by calcium-triggered
exocytosis, the endocytotic retrieval of vesicles and the refilling with neurotransmitter (for review of the synaptic
vesicle cycle see Südhof, 1995; De Camilli and Takei, 1996
).
Synapsins are presynaptic proteins thought to anchor
synaptic vesicles to actin filaments (Hirokawa et al., 1989).
The exact localization of synapsin-associated synaptic vesicles within the presynaptic terminal is still a matter of debate (compare Pieribone et al., 1995
; Rosahl et al., 1995
).
One hypothesis implies that synapsin I is associated with
the reserve pool of vesicles that are localized in a zone distal from the transmitter release site, whereas vesicles in
the proximal zone are devoid of synapsin I (Pieribone et al.,
1995
; Takei et al., 1995
). We have shown that within the
presynaptic terminal, Bassoon and Piccolo are concentrated adjacent to the synaptic cleft. This distribution is
complementary to that proposed for synapsin I. Adopting
the abovementioned hypothesis, Bassoon and Piccolo may
be associated with synaptic vesicles of the release pool,
and thus exert their functions (e.g., in synaptic vesicle cycling) in a compartment spatially distinct from that of synapsin I action.
![]() |
Footnotes |
---|
Received for publication 10 April 1998 and in revised form 12 June 1998.
S. tom Dieck, L. Sanmartí-Vila, and K. Langnaese contributed equally to this work. The present address of Heike Wex is Department of Human Genetics, Mount Sinai School of Medicine, New York, NY 10029-6514.We are grateful to Kathrin Hartung, Kathrin Zobel, and Kathrin Schumacher for expert technical assistance, Claudia Cases-Langhoff and Thomas Dresbach for helpful suggestions and discussions, Werner Zuschratter for help with confocal microscopy, Dietmar Richter and Peter Wieacker for generous support, and Michael Mäder for the gift of synapsin antibodies.
This work was supported by the Deutsche Forschungsgemeinschaft (SFB 426, Kr1255/4-1) and the Fonds der Chemischen Industrie to E.D. Gundelfinger, and by the National Institutes of Health (P50 HD32901) and the Keck Foundation to C.C. Garner.
![]() |
Abbreviations used in this paper |
---|
aa, amino acid; LIM, lin-11/ISL-1/mec-3-like; MAGUK, membrane-associated guanylate kinase homologue; PSD, postsynaptic density.
![]() |
References |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
1. | Amaral, D.G., and M.P. Witter. 1994. Hippocampal Formation. In The Rat Nervous System. G. Paxinos, editor. Academic Press Limited, London, United Kingdom. 443-494. |
2. | Budnik, V., Y.H. Koh, B. Guan, B. Hartmann, C. Hough, D. Woods, and M. Gorczyca. 1996. Regulation of synapse structure and function by the Drosophila tumor suppressor gene dlg. Neuron 17: 627-640 |
3. | Burns, M.E., and G.J. Augustine. 1995. Synaptic structure and function: dynamic organization yields architectural precision. Cell 83: 187-194 |
4. | Carlin, R.K., D.J. Grab, R.S. Cohen, and P. Siekevitz. 1980. Isolation and characterization of postsynaptic densities from various brain regions: enrichment of different types of postsynaptic densities. J. Cell Biol 86: 831-843 [Abstract]. |
5. | Cases-Langhoff, C., B. Voss, A.M. Garner, U. Appeltauer, K. Takei, S. Kindler, R.W. Veh, P. De Camilli, E.D. Gundelfinger, and C.C. Garner. 1996. Piccolo, a novel 420 kDa protein associated with the presynaptic cytomatrix. Eur. J. Cell Biol 69: 214-223 |
6. | Cohen, P.. 1997. The search for physiological substrates of MAP and SAP kinases in mammalian cells. Trends Cell Biol 7: 353-361 . |
7. | De Camilli, P., R. Cameron, and P. Greengard. 1983a. Synapsin I (protein I), a nerve terminal-specific phosphoprotein. I. Its general distribution in synapses of the central and peripheral nervous system demonstrated by immunofluorescence in frozen and plastic sections. J. Cell Biol 96: 1337-1354 [Abstract]. |
8. | De Camilli, P., S.M. Harris, W.B. Huttner, and P. Greengard. 1983b. Synapsin I (protein I), a nerve terminal-specific phosphoprotein. II. Its specific association with synaptic vesicles demonstrated by immunocytochemistry in agarose-embedded synaptosomes. J. Cell Biol 96: 1355-1373 [Abstract]. |
9. | De Camilli, P., and K. Takei. 1996. Molecular mechanisms in synaptic vesicle endocytosis and recycling. Neuron 16: 481-486 |
10. | Froehner, S.C.. 1991. The submembrane machinery for nicotinic acetylcholine receptor clustering. J. Cell Biol 114: 1-7 |
11. | Garcia, E.P., P.S. McPherson, T.J. Chilcote, K. Takei, and P. De Camilli. 1995. rbSec1A and B colocalize with syntaxin 1 and SNAP-25 throughout the axon, but are not in a stable complex with syntaxin. J. Cell Biol 129: 105-120 [Abstract]. |
12. | Garner, C.C., A. Garner, B. Voss, U. Appeltauer, and E.D. Gundelfinger. 1993. Identifying novel synapse associated proteins. In Neuronal Cytoskeleton- Morphogenesis, Transport and Synaptic Transmission. N. Hirokawa, editor. Japan Scientific Societies Press, Tokyo, Japan. 317-329. |
13. | Garner, C.C., and S. Kindler. 1996. Synaptic proteins and the assembly of synaptic junctions. Trends Cell Biol 6: 429-433 . |
14. |
Giasson, B.I., and
W.E. Mushynski.
1997.
Study of proline-directed protein kinases involved in phosphorylation of the heavy neurofilament subunit.
J.
Neurosci
17:
9466-9472
|
15. | Goslin, K., and G. Banker. 1991. Rat hippocampal neurons in low-density culture. In Culturing Nerve Cells. G. Banker and K. Goslin, editors. MIT Press, Cambridge, MA. 251-281. |
16. | Hall, Z.W., and J.R. Sanes. 1993. Synaptic structure and development: the neuromuscular junction. Cell. 72 (Suppl):99-121. |
17. | Hayes, N.V.L., D.A. Rayner, and A.J. Baines. 1991. Purification and properties of p103, a novel 103-kDa component of postsynaptic densities. J. Neurochem 57: 397-405 |
18. | Hirokawa, N., K. Sobue, K. Kanda, A. Harada, and H. Yorifuji. 1989. The cytoskeletal architecture of the presynaptic terminal and molecular structure of synapsin 1. J. Cell Biol 108: 111-126 [Abstract]. |
19. | Huttner, W.B., W. Schiebler, P. Greengard, and P. De Camilli. 1983. Synapsin I (protein I), a nerve terminal-specific phosphoprotein. III. Its association with synaptic vesicles studied in a highly purified synaptic vesicle preparation. J. Cell Biol 96: 1374-1388 [Abstract]. |
20. | Kagotani, Y., R. Picart, A. Barret, B. Wiedenmann, W.B. Huttner, and A. Tixier-Vidal. 1991. Subcellular localization of secretogranin II and synaptophysin by immunoelectron microscopy in differentiated hypothalamic neurons in culture. J. Histochem. Cytochem 39: 1507-1518 [Abstract]. |
21. | Kennedy, M.. 1997. The postsynaptic density at glutamatergic synapses. Trends Neurosci 20: 264-268 |
22. | Kim, E., M. Niethammer, A. Rothschild, Y.N. Jan, and M. Sheng. 1995. Clustering of shaker-type K+ channels by interaction with a family of membrane-associated guanylate kinases. Nature 378: 85-88 |
23. | Kim, E., K. Cho, A. Rothschild, and M. Sheng. 1996. Heteromultimerization and NMDA receptor-clustering activity of chapsyn-110, a member of the PSD-95 family of proteins. Neuron 17: 103-113 |
24. | Kirsch, J., G. Meyer, and H. Betz. 1996. Synaptic targeting of ionotropic neurotransmitter receptors. Mol. Cell. Neurosci 8: 93-98 . |
25. |
Kistner, U.,
B.M. Wenzel,
R.W. Veh,
C. Cases-Langhoff,
A.M. Garner,
U. Appeltauer,
B. Voss,
E.D. Gundelfinger, and
C.C. Garner.
1993.
SAP90, a rat
presynaptic protein related to the product of the Drosophila tumor suppressor gene dlg-A.
J. Biol. Chem
268:
4580-4583
|
26. |
Kotake, K.,
N. Ozaki,
M. Mizuta,
S. Sekiya,
N. Inagaki, and
S. Seino.
1997.
Noc2, a putative zinc-finger protein involved in exocytosis in endocrine cells.
J. Biol. Chem
272:
29407-29410
|
27. | Kozak, M.. 1987. An analysis of 5'-noncoding sequences from 699 vertebrate messenger RNAs. Nucl. Acids Res 15: 8125-8148 [Abstract]. |
28. | Laemmli, U.K.. 1970. Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 227: 680-685 |
29. | Landis, D.M.D., A.K. Hall, L.A. Weinstein, and T.S. Reese. 1988. The organization of cytoplasm at the presynaptic active zone of a central nervous system synapse. Neuron 1: 201-209 |
30. |
Langnaese, K.,
P.W. Beesley, and
E.D. Gundelfinger.
1997.
Synaptic membrane glycoproteins gp65 and gp55 are new members of the immunoglobulin
superfamily.
J. Biol. Chem
272:
821-827
|
31. | Langnaese, K., C. Seidenbecher, H. Wex, B. Seidel, K. Hartung, U. Appeltauer, A. Garner, B. Voss, B. Mueller, C.C. Garner, and E.D. Gundelfinger. 1996. Protein components of a rat brain synaptic junctional protein preparation. Mol. Brain Res 42: 118-122 |
32. | Lichter, P., and T. Cremer. 1992. Chromosome analysis by non-isotopic in situ hybridization. In Human Cytogenetics: A Practical Approach. 2nd ed., Vol. 1. D.E. Rooney, and B.H. Czepulkowski, editors. IRL Press at Oxford University Press, Oxford, United Kingdom. 157-192. |
33. | Llinás, R.R., and K.D. Walton. 1990. Cerebellum. In The Synaptic Organization of the Brain. G.M. Shepherd, editor. Oxford University Press, New York. |
34. | Lupas, A.. 1996. Coiled coils: new structures and new functions. Trends Biochem. Sci 21: 375-382 |
35. | Lupas, A., M. Van Dyke, and J. Stock. 1991. Predicting coiled coils from protein sequences. Science 252: 1162-1164 |
36. | Müller, B.M., U. Kistner, R.W. Veh, C. Cases-Langhoff, B. Becker, E.D. Gundelfinger, and C.C. Garner. 1995. Molecular characterization and spatial distribution of SAP 97, a novel presynaptic protein homologous to SAP 90 and the Drosophila discs-large tumor suppressor protein. J. Neurosci 15: 2354-2366 [Abstract]. |
37. | Müller, B.M., U. Kistner, S. Kindler, W.J. Chung, S. Kuhlendahl, S.D. Fenster, L.F. Lau, R.W. Veh, R.L. Huganir, E.D. Gundelfinger, and C.C. Garner. 1996. SAP102, a novel postsynaptic protein that interacts with NMDA Receptor complexes in vivo. Neuron 17: 255-265 |
38. | Pieribone, V.A., O. Shupliakov, L. Brodin, S. Hilfiker-Rothenfluh, A.J. Czernik, and P. Greengard. 1995. Distinct pools of synaptic vesicles in neurotransmitter release. Nature 375: 493-497 |
39. | Reddy, S.P., and D.E. Housman. 1997. The complex pathology of trinucleotide repeats. Curr. Opin. Cell Biol 9: 364-372 |
40. | Richter, K., B. Hamprecht, and H. Scheich. 1996. Ultrastructural localization of glycogen phosphorylase predominantly in astrocytes of the gerbil brain. Glia 17: 263-273 |
41. | Rosahl, T.W., D. Spillane, M. Missler, J. Herz, D.K. Selig, J.R. Wolff, R.E. Hammer, R.C. Malenka, and T.C. Südhof. 1995. Essential functions of synapsins I and II in synaptic vesicle regulation. Nature 375: 488-493 |
42. | Ross, C.. 1997. Intranuclear neuronal inclusions: a common pathogenic mechanism for glutamine-repeat neurodegenerative diseases? Neuron 19: 1147-1150 |
43. | Sánchez-García, I.. 1994. The LIM domain: a new structural motif found in zinc-finger-like proteins. Trends Genet 10: 315-320 |
44. |
Seidenbecher, C.I.,
K. Richter,
U. Rauch,
R. Fässler,
C.C. Garner, and
E.D. Gundelfinger.
1995.
Brevican, a chondroitin sulfate proteoglycan of rat
brain, occurs as secreted and cell surface glycosylphosphatidylinositol-
anchored isoforms.
J. Biol. Chem
270:
27206-27212
|
45. | Shirataki, H., K. Kaibuchi, T. Sakoda, S. Kishida, T. Yamaguchi, K. Wada, M. Miyazaki, and Y. Takai. 1993. Rabphilin-3A, a putative target protein for smg p25A/rab3A p25 small GTP-binding protein related to synaptotagmin. Mol. Cell. Biol 13: 2061-2068 [Abstract]. |
46. | Sikorski, A.F., G. Terlecki, I.S. Zagon, and S.R. Goodman. 1991. Synapsin I-mediated interaction of brain spectrin with synaptic vesicles. J. Cell Biol 114: 313-318 [Abstract]. |
47. | Südhof, T.C.. 1995. The synaptic vesicle cycle: a cascade of protein-protein interactions. Nature 375: 645-653 |
48. | Südhof, T.C.. 1997. Function of Rab3 GDP-GTP exchange. Neuron 18: 519-522 |
49. | Takei, Y., A. Harada, S. Takeda, K. Kobayashi, S. Terada, T. Noda, T. Takahashi, and N. Hirokawa. 1995. Synapsin I deficiency results in the structural change in the presynaptic terminals in the murine nervous system. J. Cell Biol 131: 1789-1800 [Abstract]. |
50. | Thomas, U., B. Phannavong, B. Müller, C.C. Garner, and E.D. Gundelfinger. 1997a. Functional expression of rat synapse-associated proteins SAP97 and SAP102 in Drosophila dlg-1 mutants: effects on tumor suppression and synaptic bouton structure. Mech. Dev 62: 161-174 |
51. | Thomas, U., E. Kim, S. Kuhlendahl, Y.H. Koh, E.D. Gundelfinger, M. Sheng, C.C. Garner, and V. Budnik. 1997b. Synaptic clustering of the cell adhesion molecule fasciclin II by discs- large and its role in the regulation of presynaptic structure. Neuron 19: 787-799 |
52. | Wang, Y., M. Okamoto, F. Schmitz, K. Hofmann, and T.C. Südhof. 1997. Rim is a putative Rab3 effector in regulating synaptic-vesicle fusion. Nature 388: 593-598 |
53. | Wiedenmann, B., and W.W. Franke. 1985. Identification and localization of synaptophysin, an integral membrane glycoprotein of Mr 38.000 characteristic of presynaptic vesicles. Cell 41: 1017-1028 |
54. | Ziff, E.B.. 1997. Enlightening the postsynaptic density. Neuron. 19: 1163-1174 |