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The Journal of Neuroscience, August 27, 2003, 23(21):7727-7736
Previous Article | Next Article
NMDA-Dependent Proteolysis of Presynaptic Adhesion Molecule L1 in the Hippocampus by Neuropsin
Kazumasa Matsumoto-Miyai, Ayako Ninomiya, Hironobu Yamasaki, Hideki Tamura, Yukiko Nakamura, andSadao Shiosaka Division of Structural Cell Biology, Nara Institute of Science and Technology, Ikoma, Nara 630-0192, Japan
Abstract
Top
Abstract
Introduction
Synaptic plasticity requires an activity-dependent, rapid, and long-lasting modification of synaptic character, including morphology and coupling strength. Here we show that a serine protease, neuropsin, directly and specifically modifies the synaptic adhesion molecule L1, which was localized to the presynaptic site of the asymmetric synapse in the mouse hippocampus. Increased neural activity triggered the rapid, transient activation of the precursor form of neuropsin in an NMDA receptor-dependent manner. The activated neuropsin immediately cleaved L1 and released a neuropsin-specific extracellular 180 kDa fragment. This neuropsin-specific L1-cleaving system is involved in NMDA receptor-dependent synaptic plasticity, such as the Schaffer collateral long-term potentiation.
Key words: serine protease; neuropsin; proteolysis; neural cell adhesion molecule L1; synaptic plasticity; hippocampus; Schaffer collateral long-term potentiation
Introduction
The dynamic regulation of synaptic strength by neural activity (activity-dependent synaptic plasticity) is a fundamental component of normal brain functions, such as learning and memory. Studies that have focused on this plasticity have concentrated on the postsynaptic intracellular signal transduction that leads to the regulation of neurotransmitter receptor function (Soderling and Derkach, 2000). In addition, evidence is accumulating that increased neural activity induces the rapid, synaptic morphological change that occurs during neural plasticity events (Engert and Bonhoeffer, 1999
Although the involvement of CAMs in synaptic plasticity is now accepted, few studies on the modulation of CAMs during synaptic interaction have been published. Previously, we found that the extracellular serine protease neuropsin is associated with activity-dependent neural plasticity, LTP, and kindling epileptogenesis (Okabe et al., 1996
Materials and Methods
In vivo LTP. Male mice (10 weeks old) were deeply anesthetized with urethane (1.25 gm/kg, i.p.) and fixed in a stereotaxic frame. To record field EPSPs (fEPSPs), a tungsten recording electrode was inserted into the CA1 stratum radiatum (2.46 mm posterior, 2.0 mm lateral to bregma), and a bipolar stainless steel stimulating electrode was placed along the Schaffer collaterals (2.46 mm posterior, 2.50 mm lateral to bregma). Test stimulation (100 sec duration) was applied at intervals of 30 sec, and its intensity was adjusted to produce an fEPSP with a slope that was50% of maximum. To induce LTP, theta-burst stimulation consisting of 10 burst-like trains (10 pulses at 200 Hz) at 5 Hz was applied four times every 30 sec to the Schaffer collaterals. In some experiments, the hippocampal region in which the electrode was inserted was dissected (approximately one-third of the unilateral hippocampus) at various time points before and after theta-burst stimulation and used for the measurement of the neuropsin activity.
Chemical stimulation of mouse hippocampus. According to the previous study (Li et al., 2001
Measurement of proteolytic activity of endogenous neuropsin. Each hippocampal organ was homogenized separately in 1 ml of lysis buffer (1% Triton X-100, 150 mM NaCl, 5 mM EDTA, and 50 mM HEPES, pH 7.4) and then centrifuged at 15,000 rpm to remove debris. The proteolytic activity of the endogenous neuropsin in this supernatant was measured as described previously (Momota et al., 1998
Preparation of recombinant neuropsin, the synaptoneurosomal fraction, and the synaptic membrane fraction. The nonactive precursor form of recombinant neuropsin (r-proNP) was generated with the baculovirus-insect cell system (Shimizu et al., 1998
Western blot analysis of CAMs in the SN and synaptic membrane fractions. The SN pellet was resuspended in 1 ml of lysis buffer, and then this suspension was centrifuged at 15,000 rpm for 30 min in a microfuge to clear the debris. We used this supernatant as the SN fraction. The synaptic membrane fraction was also lysed with the same buffer and microfused to remove debris. The total protein content of the SN and synaptic membrane fractions was determined using BCA Protein Assay Reagent (Pierce, Rockford, IL). We applied r-actNP at a final concentration of 250 nM to 1 mg/ml of the SN proteins prepared as described above. Then this mixture was incubated at 37°C for 5-60 min with gentle rotation. As a control, the same experiment was performed using r-proNP or its solvent only. To detect the CAMs, we performed Western blot analysis using the antibodies described below according to the conventional method. Band densities on an x-ray film were measured using a Discovery System Quantity One (Protein Databases Inc., New York, NY). Fibronectin and laminin (Invitrogen, Rockville, MD) were examined as to whether r-actNP can process them. Coomassie blue-stained band densities were analyzed with the ATTO densitograph system.
Antibodies. We used specific antibodies for Western blot analysis at adequate dilutions as follows: anti-neural cell adhesion molecule (NCAM) rabbit polyclonal antibody (Chemicon, Temecula, CA), 1:10000; anti-C-terminal L1 peptide goat polyclonal antibody (Santa Cruz Biotechnology, Santa Cruz, CA), 1:400; anti-pan-L1 rabbit polyclonal antibody (a gift from Dr. V. Lemmon, Case Western Reserve University, Cleveland, OH), 1:2000; anti-N-cadherin or anti-E-cadherin rabbit polyclonal antibody (Santa Cruz Biotechnology), 1:100; anti-fibronectin rabbit polyclonal antibody (Biogenesis, New Fields, UK), 1:400; anti-NMDA receptor type 1 (NMDAR1) or anti-NMDAR2B rabbit polyclonal antibody (Chemicon), 1:200; and anti-NMDAR2A, anti-glutamate receptor type 1 (GluR1), anti-GluR2/3, or anti-GluR4 rabbit polyclonal antibody (Upstate Biotechnology, Lake Placid, NY), 1 µg/ml.
L cell aggregation assay. The rat full-length L1 expression vector was provided by Dr. K. Itoh (Tokyo Metropolitan Institute of Medical Science, Tokyo, Japan). The vector was transfected into L cells using Lipofectamine reagent (Invitrogen) according to the procedure of the manufacturer. To achieve the highest efficiency transfections, transfection conditions were optimized by checking L1 protein yields using immunoblot analysis. Transfected L cells were detached from cell cultures by treatment with 0.0025% trypsin and 0.001% EDTA in PBS. Cells were resuspended in divalent cation-free HBSS supplemented with 1 mM HEPES, pH 7.3, and 0.2% BSA (HBSS-BSA) at densities of 3-4 x 106 cells/ml, and 0.6 ml was rotated at 37°C. r-actNP or r-proNP was added to HBSS-BSA at a final concentration of 250 nM. Aliquots were withdrawn after 2 hr of incubation, and particles were enumerated in a hemocytometer. Percentages of aggregated cells were represented by the index (1 - N2/N0) x 100, where N2 and N0 are the total number of particles at incubation times 2 and 0 hr, respectively.
Immunohistochemistry for L1. The preembedding and staining procedures were performed as described previously (Matsumoto et al., 1994
Results
Neuropsin is transiently activated in CA1 E-LTP in vivo
To reveal the involvement of the neuropsin activation in synaptic plasticity, we examined the neuropsin proteolytic activity in the hippocampus in which the Schaffer collateral LTP was induced in vivo. When theta-burst stimulation was applied to the Schaffer collateral pathway in anesthetized mice, the enhancement of fEPSP and LTP in the CA1 subfield was successfully induced (Fig. 1A). We in turn measured the immunoprecipitated endogenous neuropsin activity in hippocampi before and after theta-burst stimulation using the synthetic substrate. This assay is highly sensitive and specific for the detection of neuropsin activity for the following reasons: (1) mAbF12 specifically recognizes neuropsin in immunoprecipitation assays (Momota et al., 1998
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Figure 1. Neuropsin activation was transiently induced in the early phase of the Schaffer collateral LTP in vivo. A, Time course of changes in fEPSP slopes in anesthetized mice. The fEPSPs evoked by stimulation of the Schaffer collaterals were recorded from the CA1 stratum radiatum. The ordinate is expressed as a percentage of baseline values at time 0. Data are means ± SEM of six cases. The insets show typical field potentials immediately before (1) and 60 min after (2) theta-burst stimulation. B, Endogenous neuropsin was rapidly, transiently activated after theta-burst stimulation. The neuropsin activity at 5 and 6 min after stimulation was significantly increased[n = 5-8;*p<0.05 vs the activity before stimulation (0min)]. C, Typical field potentials immediately before and 5 min after theta-burst stimulation of the cases in which synaptic potentiation was successfully induced (LTP) and the stimulation failed to induce synaptic potentiation (No LTP). D, fEPSP slopes at 5 min after stimulation in the experiments in which the induction of synaptic potentiation was successful (LTP) or unsuccessful (No LTP). The ordinate is expressed as a percentage of baseline values at time 0. Data are means ± SEM of eight cases. E, The proteolytic activity of neuropsin in the hippocampal region in which synaptic potentiation was induced (LTP) or not (NoLTP) after the theta-burst stimulation. Neuropsin was activated only in the hippocampus in which synaptic potentiation was successfully induced (n = 8; *p < 0.05 vs Test Pulse or No LTP samples). The vertical axes of the graphs in B and E indicate the fluorescence intensity of 7-amino-4-methyl-coumarin (AMC), which was generated from the cleavage of Pro-Phe-Arg-MCA by endogenous neuropsin per 1 mg of total protein.
NMDA receptor-dependent activation of neuropsin ex vivo
To pharmacologically characterize the neuropsin activation after stimulation, we prepared unilateral intact hippocampal organs dissected from P14 mouse brain in which the hippocampal network was already established. We applied a brief chemical stimulation with the depolarizing agent 4-AP, a potassium channel blocker, to induce the depolarization and synaptic excitation (Perreault and Avoli, 1989
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Figure 2. Chemical stimulation of mouse hippocampus-activated neuropsin. A, Extracellular recording in the CA3 subfield during stimulation with 4-AP. The vertical axis indicates the number of pulses beyond the threshold (2 mV) per minute. 4-AP was applied for 10 min as indicated by the bold horizontal bar below the x-axis. Insets a1-a5 show the waveforms at time points indicated by arrowheads. 4-AP induced a biphasic rise in neural activity. B, Chemical stimulation by 4-AP or NMDA also induced the neuropsin activation. 4-AP or NMDA was applied for 10 min as indicated by the bold horizontal bar. A rapid, transient activation of neuropsin was triggered by either application. The neuropsin activity increased at two time points, 5 min after the onset of stimulation by 4-AP or NMDA, and 5 min after the washout of drugs. Neuropsin activity was significantly higher at these time points than in nonstimulated controls: NS (*p < 0.05 vs NS at 5 min; #p < 0.05 vs NS at 15 min; n = 3-10 hippocampal organs per group). C, D, Glutamate receptor blockers significantly eliminated the NMDA-induced or 4-AP-induced increase in neuropsin activity at 5 min (C) and 15 min (D) after stimulation. Note that AP-5 completely blocked the increase at both time points, whereas CNQX blocked it only at 15 min. At 5 min after stimulation (C), NMDA-induced neuropsin activation was partially (not significantly) blocked by only the MEK inhibitor U0126 among protein kinase inhibitors. At 15 min (D), U0126 and the PKA inhibitor H89 significantly blocked the NMDA-induced neuropsin activation, and the inhibitory effects of other kinase inhibitors were partial (*p < 0.05 vs NMDA; #p < 0.05 vs 4-AP; n = 5-10 hippocampal organs per group). The vertical axes in B-D indicate the fluorescence intensity of AMC, which was generated from the cleavage of Pro-Phe-Arg-MCA by endogenous neuropsin in a single hippocampal organ.
Screening of synaptic neuropsin substrate(s) in hippocampus
We screened candidate substrate(s) of neuropsin from mouse hippocampus, in which neuropsin mRNA is expressed predominantly. We used three screening methods; the first one (approach 1) was comparison of two-dimensional gel electrophoresis of the hippocampal SN fraction to which was added r-actNP or nonactive r-proNP. Synaptoneurosomes, which are snowman-shaped entities consisting of a pinched-off, resealed presynaptic moiety adhered to a pinched-off, resealed postsynaptic moiety (Fig. 3A), have considerable transmission function (Weiler and Greenough, 1991
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Figure 3. The proteolytic effects of neuropsin on CAMs and ECM proteins. A, An electron micrograph representing the prepared SN fraction. The synaptoneurosome consists of functional resealed presynaptic (Pre) plus postsynaptic (Post) entities. Scale bar, 0.5 µm. * indicates the synaptic adhesive site. B-E, Immunoblot analysis of the SN fractions treated for 60 min with a solvent (Buf), r-proNP (Pro), and r-actNP (Act) using anti-NCAM antibody (B), anti-L1 antibody (C), anti-E-cadherin antibody (D), and anti-N-cadherin antibody (E). Application of r-actNP resulted in a complete loss of intact 200 kDa L1 and a marked reduction in its 80 kDa C-terminal fragment (C). In contrast, NCAM (B), E-cadherin (D), and N-cadherin (E) were not affected by coincubation with r-actNP. F, G, Coomassie blue staining of laminin (F) and fibronectin (G) applied for 60 min with buffer only (Buf), r-proNP (Pro), and r-actNP (Act). The application of r-actNP with fibronectin resulted in a decrease in the intact 220 kDa band and the appearance of 215, 210, and 200 kDa fragments (G). In contrast, r-actNP was less effective against laminin (F). H, The time course in cleavage of CAMs and ECM molecules induced by coincubation with r-actNP. The band densities were quantified by densito-metric scanning setting densities in the SN fraction before application of r-actNP (0 min) as 100%, and the relative densities (vertical axis) were plotted at various time points after the application of r-actNP (horizontal axis). All data are presented as the mean ± SEM of two independent experiments. Of these molecules, L1 showed the highest velocity of cleavage. The 200 kDa band density of intact L1 was reduced to one-half at 15 min.
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Figure 4. Cleavage of L1 at its extracellular membrane-proximal site by neuropsin-inhibited aggregation of L1-expressing cells. A, Western blot analysis of L1 in the synaptic membrane fraction. L1 was detected in the synaptic membrane fraction by both anti-pan-L1 antibody (Pan-L1) and C-terminal L1 peptide-specific antibody (L1-C). B, Western blot analysis of L1 cleavage by r-actNP. Full-length L1-recognizing polyclonal antibody could stain all of the degradation derivatives of L1: L1-200, L1-140, and L1--80 in the SN fraction treated with the buffer only (Buf). Coincubation of r-actNP with the SN fraction for 60 min (Act) resulted in the disappearance of L1-200 and L1-80 and, instead, the appearance of new fragments of L1-180 and L1-60. Both the band density and position of L1-140 never changed. C, The effect of extracellularly applied recombinant neuropsin on the aggregation of L1-transfected L cells. The vertical bar indicates the percentage of aggregation at 2 hr after detachment from the plastic dish. Incubation with r-actNP inhibited the aggregation of L1-transfected L cells (*p < 0.05 vs L1 full control), whereas r-proNP had no effect. Values shown are the means of five independent experiments. Error bars indicate SEM. D, Cleavage site of L1 on the basis of these experiments.
To confirm the synaptic localization of L1 as shown above, the purified synaptic membrane fraction was examined by Western blot analysis using two different anti-L1 antibodies. We could detect L1 in the synaptic membrane fraction prepared from mouse hippocampi using anti-pan L1 and anti-C-terminal L1 peptide antibodies (Fig. 4A). The experiment could also determine its site of cleavage by neuropsin. Using an anti-pan-L1 polyclonal antibody that recognizes the whole sequence of L1, the 200 kDa full-length L1 (L1-200), the 140 kDa N-terminal fragment (L1-140), and the 80 kDa C-terminal fragment (L1-80) were detected (Fig. 4A,B). The L1-140 and L1-80 fragments are known to be posttranslationally processed end products cleaved by plasmin in the third fibronectin-like domain of L1 (Fig. 4D) (Nayeem et al., 1999
To examine whether extracellularly applied r-actNP can induce proteolysis-dependent segregation, we analyzed the effect of r-actNP on L1-transfected L cells, which themselves do not express CAMs significantly. L1-transfected L cells readily aggregated as observed previously (Hillenbrand et al., 1999
V
1 (Bodary and McLean, 1990
The results show significant effects of neuropsin on L1: (1) L1 is the most suitable substrate for neuropsin; (2) neuropsin cleaves the extracellular domain of L1; (3) L1 is localized to synaptic membrane; and (4) the cleavage caused segregation of L1-expressing cultured cells.
NMDA-dependent cleavage of L1 by neuropsin ex vivo
Because it was found that L1 is the most suitable substrate for neuropsin, it is important to determine whether the cleavage of L1 depends on endogenous neuropsin activated by potentiated neural activity as observed in Figure 2B. We therefore analyzed the time course of neuropsin-specific cleavage of L1 by 4-AP and NMDA in hippocampus. We detected L1 protein in the stimulated hippocampal organ by immunoblotting with anti-pan-L1 polyclonal antibody recognizing full-length L1. The new 180 kDa band of L1, which was exclusively produced by neuropsin (Fig. 4B), appeared in the hippocampal organ at 15 and 30 min after stimulation by 4-AP or NMDA (Fig. 5A). On the other hand, the intensity of the L1-180 band was faint when the hippocampus was not stimulated by these agents (Fig. 5A,B, NS). The temporal change in L1-180 band density (Fig. 5B, top) and the density ratio of L1-180/L1-200 (Fig. 5B, bottom) revealed a rapid increase in the chemically stimulated hippocampus. The band density increased markedly from 10 to 70 min after 4-AP and NMDA treatment (Fig. 5B, 4-AP, NMDA), whereas it did not show any increase when the organ was nonstimulated (Fig. 5B, NS). The application of 4-AP or NMDA resulted in a rapid increase in the band density of L1-180 at as early as 5 min (NMDA) or 10 min (4-AP). Such an early response was consistent with the time course of the increase in the enzymatic activity of neuropsin (Fig. 2B). The increase in L1-180 density continued between 15 and 70 min after the stimulation (Fig. 5B). The increase was completely blocked after pretreatment with the NMDA receptor antagonist AP-5 (Fig. 5A,B, 4-AP + AP5), showing that this increase was dependent on the activation of the NMDA receptor. To clarify whether the appearance of L1-180 was mediated by endogenous neuropsin, we performed the same experiment using NMDA-stimulated hippocampus from neuropsin-deficient mice. The L1-180 band density was found to be negligible [Fig. 5A,B, NMDA (NP-/-)]. To further confirm the dependence on the proteolytic action of endogenous neuropsin, we analyzed whether the activity-neutralizing anti-neuropsin antibody mAbB5 blocked the NMDA-induced increase in L1-180. The penetration of mAbB5 into hippocampus was checked by an immunohistological analysis using biotinylated anti-rat IgG recognizing mAbB5. Strong immunoreactivity for bath-applied mAbB5 was found in the stratum oriens, pyramidale, and radiatum in the hippocampus. The density of immunoreactivity in the core region of CA1 subfield of treated hippocampus (5.08 ± 2.01 x 106/1.44 mm2) was significantly higher than the control without mAbB5 (1.16 ± 0.78 x 106/1.44 mm2; p < 0.05). No increase of L1-180 was found in NMDA-stimulated hippocampal organs treated with neutralizing antibody (Fig. 5A,B, NMDA + mAbB5). This neutralizing antibody also impaired the hippocampal Schaffer collateral E-LTP (H. Tamura, K. Matsumoto-Miyai, and S. Shiosaka, unpublished observations) (Komai et al., 2000
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Figure 5. Chemical stimulation induced neuropsin-dependent L1 cleavage. A, Immunoblot analysis showed that L1-180 (arrowheads) increased in the hippocampal organs stimulated by 4-AP or NMDA but not in the absence of stimulation (NS) or in the neuropsin-deficient hippocampus stimulated with NMDA [NMDA (NP-/-)] at both 15 and 30 min after treatment. The 4-AP-induced or NMDA-induced increase of L1-180 was blocked by preincubation with AP-5 (4-AP + AP5) or anti-neuropsin antibody mAbB5 (NMDA + mAbB5). B, Temporal change in the L1-180 band density (top) and the band density ratio of L1-180/L1-200 (bottom graph) after chemical stimulation. Error bars indicate SEM. A rapid neuropsin-dependent increase in L1-180 was induced by chemical stimulation with 4-AP and NMDA. C, D, Immunoblot analyses using anti-N-cadherin (C) and anti-fibronectin (D) antibodies revealed that no change in N-cadherin and fibronectin in the hippocampal organs was induced by chemical stimulation (4-AP or NMDA).
Presynaptic localization of L1 in hippocampus
Because the present study revealed the involvement of the neuropsin-L1 processing system in synaptic potentiation, and presumably Schaffer collateral plasticity, it is important to examine whether L1 protein is associated with the synaptic machinery. Strong dot-like L1 immunoreactivity was found to be scattered in the stratum radiatum of the CA1 subfield by a light microscopic observation of L1 immunohistochemistry using C-terminal L1 peptide-specific antibody (Fig. 6A,B). Axon bundles projecting from the CA3 cell bodies, which were Schaffer collateral pathways, were immunostained (Fig. 6A,B, arrowheads). The L1-immunoreactive fiber bands projected toward the stratum radiatum of the CA1 subfield. Epon-embedded immunostained tissue sections were sectioned further after bright-field micrographs had been taken and observed under an electron microscope. The immunoreactive nerve terminals apparently formed asymmetrical synapses on the dendrites and dendritic spines of the CA1 pyramidal neurons (Fig. 6C). L1 immunoreactivity in the CA1 subfield was confined to the presynapses that apposed nonimmunoreactive dendritic spines protruding from apical and secondary apical dendrites (Fig. 6C-E). These observations imply that L1 protein exhibits heterophilic binding with unidentified CAMs localized in postsynapses. We also confirmed the L1 localization by immunohistochemical analysis using another anti-pan-L1 antibody, which was applied in former immunohistochemical studies (Miller et al., 1993
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Figure 6. L1 immunoreactivity in the mouse hippocampus. A-E, L1 immunohistochemistry using C-terminal L1 peptide-specific antibody. A, B, Light microscopic observation of L1 immunoreactivity in Epon-embedded mouse hippocampal tissue. Schaffer collateral axons projecting from CA3 to CA1 showed intense L1-immunoreactive bundles (A, B, arrowheads). B shows a higher-magnification view of the stratum radiatum of the CA1 subfield indicated by the white rectangle in A. L1-immunoreactivity showed a fine granular pattern. C, Electron microscopic observation of the immunoreactivity in the stratum radiatum of the CA1 subfield. L1 was exclusively localized to the presynaptic membrane in the asymmetrical synapses. AD, Apical dendrite; S, dendritic spine. D, E, L1 localization in the multisynaptic boutons (black arrowheads). L1 immunoreactivity was observed in both presynaptic sites in some multisynaptic boutons (D, white arrowheads). In another multisynaptic bouton, only one presynaptic site was positive (E, left synapse, white arrowhead) and the other was negative (E, right synapse, white arrow). A nonimmunoreactive presynaptic bouton is also seen in D (asterisk). F, G, L1 immunohistochemistry using anti-pan-L1 antibody. F, Light microscopic observation of the immunoreactivity with anti-pan-L1 antibody revealed a similar pattern to that with C-terminal L1 peptide-specific antibody (A). G, Anti-pan-L1 antibody also labeled the presynaptic bouton (black arrowhead) in the CA1 stratum radiatum. The postsynaptic site is indicated by a white arrowhead. Scale bars: A, F, 200 µm; B, 50 µm; C, 500 nm; D, E, G, 100 nm.
Not all of the presynaptic boutons forming asymmetric synapses were immunoreactive for L1. Non-L1-immunoreactive synaptic boutons were also frequently seen (Fig. 6D, asterisk). The immunoreactive boutons are generally small compared with nonimmunoreactive axodendritic asymmetry synapses (Fig. 6D,E). In some cases, there were L1-associated and nonassociated synapses at the presynaptic membrane in one multisynapse bouton (Fig. 6E), suggesting that two kinds of synaptic interactions exist, L1-dependent and L1-independent, in a single bouton.
Overall, the present study clearly showed that a neuropsin-dependent presynaptic L1-cleaving system that is activated in an NMDA receptor-dependent manner is present in the specific subpopulation of hippocampal CA1 synapses.
Discussion
The present study showed that increased neural activity triggered a rapid, transient increase in the proteolytic activity of a limbic-specific serine protease, neuropsin (Chen et al., 1995In this study, we found that L1 is a Schaffer collateral presynaptic component. The localization of L1 in the presynaptic components was confirmed with two different analyses in the present study: (1) Western blot analysis of the synaptic membrane fraction; and (2) light microscopic and electron microscopic observations of immunohistochemistry using two kinds of anti-L1 antibodies. Thus, we concluded that L1 was present in synapses of the hippocampal CA1 subfield. The present study is consistent with a light microscopic immunohistochemical study demonstrating that L1 is localized to the unmyelinated Schaffer collateral fiber system (Miller et al., 1993
Several studies showed that ankyrins and syntenin-1 bind to the cytoplasmic region of the L1 subfamily (Brummendorf and Lemmon, 2001
Footnotes
Received Jan 13, 2003; revised April 21, 2003; accepted April 21, 2003.This work was supported by a grant-in-aid for Scientific Research on Priority Areas (A) from the Ministry of Science, Sport, Culture, and Technology, and the Sasakawa Scientific Research Grant from the Japan Science Society. We thank Dr. S. F. Traynelis for reading this manuscript and making helpful suggestions, Dr. M. Tohyama for supportive encouragement, Drs. T. Tsumoto, Y. Hata, F. Kimura, and S. Komai for discussion and technical advice on electrophysiology, Dr. K. Itoh for advice on the L1 experiment, Drs. N. Matsuki, Y. Ikegaya, and K. Nakao for technical advice on the in vivo LTP experiment, and Y. Sato and M. Sano for technical assistance.
Correspondence should be addressed to Dr. Kazumasa Matsumoto-Miyai, Division of Structural Cell Biology, Nara Institute of Science and Technology, 8916-5 Takayama, Ikoma, Nara 630-0192, Japan. E-mail: kmatsumo{at}bs.aist-nara.ac.jp.
Copyright © 2003 Society for Neuroscience 0270-6474/03/237727-10$15.00/0
References
Abel T, Kandel E (1998) Positive and negative regulatory mechanisms that mediate long-term memory storage. Brain Res Brain Res Rev 26: 360-378.[Medline]
Aicher B, Lerch MM, Muller T, Schilling J, Ullrich A (1997) Cellular redistribution of protein tyrosine phosphatases LAR and PTPsigma by inducible proteolytic processing. J Cell Biol 138: 681-696.
[Abstract/Free Full Text] Arami S, Jucker M, Schachner M, Welzl H (1996) The effect of continuous intraventricular infusion of L1 and NCAM antibodies on spatial learning in rats. Behav Brain Res 81: 81-87.[Web of Science][Medline]
Bahr BA, Staubli U, Xiao P, Chun D, Ji ZX, Esteban ET, Lynch G (1997) Arg-Gly-Asp-Ser-selective adhesion and the stabilization of long-term potentiation: pharmacological studies and the characterization of a candidate matrix receptor. J Neurosci 17: 1320-1329.
[Abstract/Free Full Text] Bailey CH, Kandel ER (1993) Structural changes accompanying memory storage. Annu Rev Physiol 55: 397-426.[Web of Science][Medline]
Benson DL, Tanaka H (1998) N-cadherin redistribution during synaptogenesis in hippocampal neurons. J Neurosci 18: 6892-6904.
[Abstract/Free Full Text] Benson DL, Schnapp LM, Shapiro M, Huntley GW (2000) Making memories stick: cell-adhesion molecules in synaptic plasticity. Trends Cell Biol 10: 473-482.[Web of Science][Medline]
Bodary SC, McLean JW (1990) The integrin beta 1 subunit associates with the vitronectin receptor alpha v subunit to form a novel vitronectin receptor in a human embryonic kidney cell line. J Biol Chem 265: 5938-5941.
[Abstract/Free Full Text] Bozdagi O, Shan W, Tanaka H, Benson DL, Huntley GW (2000) Increasing numbers of synaptic puncta during late-phase LTP: N-cadherin is synthesized, recruited to synaptic sites, and required for potentiation. Neuron 28: 245-259.[Web of Science][Medline]
Brummendorf T, Lemmon V (2001) Immunoglobulin superfamily receptors: cis-interactions, intracellular adapters and alternative splicing regulate adhesion. Curr Opin Cell Biol 13: 611-618.[Web of Science][Medline]
Chen ZL, Yoshida S, Kato K, Momota Y, Suzuki J, Tanaka T, Ito J, Nishino H, Aimoto S, Kiyama H, Shiosaka S (1995) Expression and activity-dependent changes of a novel limbic-serine protease gene in the hippocampus. J Neurosci 15: 5088-5097.[Abstract]
Chetkovich DM, Gray R, Johnston D, Sweatt JD (1991) N-methyl-D-aspartate receptor activation increases cAMP levels and voltage-gated Ca2+ channel activity in area CA1 of hippocampus. Proc Natl Acad Sci USA 88: 6467-6471.
[Abstract/Free Full Text] Colicos MA, Collins BE, Sailor MJ, Goda Y (2001) Remodeling of synaptic actin induced by photoconductive stimulation. Cell 107: 605-616.[Web of Science][Medline]
Cremer H, Lange R, Christoph A, Polmann M, Vopper G, Roes J, Brown R, Baldwin S, Kraemer P, Scheff S (1994) Inactivation of the N-CAM gene in mice results in size reduction of the olfactory bulb and deficits in spatial learning. Nature 367: 455-459.[Medline]
Davies B, Kearns IR, Ure J, Davies CH, Lathe R (2001) Loss of hippocampal serine protease BSP1/neuropsin predisposes to global seizure activity. J Neurosci 21: 6993-7000.
[Abstract/Free Full Text] Demyanenko GP, Tsai AY, Maness PF (1999) Abnormalities in neuronal process extension, hippocampal development, and the ventricular system of L1 knockout mice. J Neurosci 19: 4907-4920.
[Abstract/Free Full Text] Einheber S, Schnapp LM, Salzer JL, Cappiello ZB, Milner TA (1996) Regional and ultrastructural distribution of the alpha 8 integrin subunit in developing and adult rat brain suggests a role in synaptic function. J Comp Neurol 370: 105-134.[Web of Science][Medline]
Engert F, Bonhoeffer T (1999) Dendritic spine changes associated with hippocampal long-term plasticity. Nature 399: 66-70.[Medline]
Fannon AM, Colman DR (1996) A model for central synaptic junctional complex formation based on the differential adhesive specificities of the cadherins. Neuron 17: 423-434.[Web of Science][Medline]
Fields RD, Itoh K (1996) Neural cell adhesion molecules in activity-dependent development and synaptic plasticity. Trends Neurosci 19: 473-480.[Web of Science][Medline]
Geinisman Y, Berry RW, Disterhoft JF, Power JM, Van der Zee EA (2001) Associative learning elicits the formation of multiple-synapse boutons. J Neurosci 21: 5568-5573.
[Abstract/Free Full Text] Hillenbrand R, Molthagen M, Montag D, Schachner M (1999) The close homologue of the neural cell adhesion molecule L1 (CHL1): patterns of expression and promotion of neurite outgrowth by heterophilic interactions. Eur J Neurosci 11: 813-826.[Web of Science][Medline]
Hirata A, Yoshida S, Inoue N, Matsumoto-Miyai K, Ninomiya A, Taniguchi M, Matsuyama T, Kato K, Iizasa H, Kataoka Y, Yoshida N, Shiosaka S (2001) Abnormalities of synapses and neurons in the hippocampus of neuropsin-deficient mice. Mol Cell Neurosci 17: 600-610.[Web of Science][Medline]
Husi H, Ward MA, Choudhary JS, Blackstock WP, Grant SGN (2000) Proteomic analysis of NMDA receptor-adhesion protein signaling complexes. Nat Neurosci 3: 661-669.[Web of Science][Medline]
Kato K, Kishi T, Kamachi T, Akisada M, Oka T, Midorikawa R, Takio K, Dohmae N, Bird PI, Sun J, Scott F, Miyake Y, Yamamoto K, Machida A, Tanaka T, Matsumoto K, Shibata M, Shiosaka S (2001) Serine proteinase inhibitor 3 and murinoglobulin I are potent inhibitors of neuropsin in adult mouse brain. J Biol Chem 276: 14562-14571.
[Abstract/Free Full Text] Komai S, Matsuyama T, Matsumoto K, Kato K, Kobayashi M, Imamura K, Yoshida S, Ugawa S, Shiosaka S (2000) Neuropsin regulates an early phase of Schaffer-collateral long-term potentiation in the murine hippocampus. Eur J Neurosci 12: 1479-1486.[Web of Science][Medline]
Koroll M, Rathjen FG, Volkmer H (2001) The neural cell recognition molecule neurofascin interacts with syntenin-1 but not syntenin-2, both of which reveal self-associating activity. J Biol Chem 276: 10646-10654.
[Abstract/Free Full Text] Li J, Shen H, Naus CCG, Zhang L, Carlen PL (2001) Upregulation of gap junction connexin 32 with epileptoform activity in the isolated mouse hippocampus. Neuroscience 105: 589-598.[Medline]
Luthl A, Laurent JP, Figurov A, Muller D, Schachner M (1994) Hippocampal long-term potentiation and neural cell adhesion molecules L1 and NCAM. Nature 372: 777-779.[Medline]
Lynch G, Halpain S, Baudry M (1982) Effects of high-frequency synaptic stimulation on glutamate receptor binding studied with a modified in vitro hippocampal slice preparation. Brain Res 244: 101-111.[Web of Science][Medline]
Malenka RC, Nicoll RA (1993) NMDA-receptor-dependent synaptic plasticity: multiple forms and mechanisms. Trends Neurosci 16: 521-527.[Web of Science][Medline]
Maletic-Savatic M, Malinow R, Svoboda K (1999) Rapid dendritic morphogenesis in CA1 hippocampal dendrites induced by synaptic activity. Science 283: 1923-1927.
[Abstract/Free Full Text] Matsumoto K, Wanaka A, Takatsuji K, Muramatsu H, Muramatsu T, Tohyama M (1994) A novel family of heparin-binding growth factors, pleiotrophin and midkine, is expressed in the developing rat cerebral cortex. Brain Res Dev Brain Res 79: 229-241.[Medline]
Miller PD, Chung WW, Lagenaur CF, DeKoskey ST (1993) Regional distribution of neural cell adhesion molecule (NCAM) and L1 in human and rodent hippocampus. J Comp Neurol 327: 341-349.[Web of Science][Medline]
Momota Y, Yoshida S, Ito J, Shibata M, Kato K, Sakurai K, Matsumoto K, Shiosaka S (1998) Blockade of neuropsin, a serine protease, ameliorates kindling epilepsy. Eur J Neurosci 10: 760-764.[Web of Science][Medline]
Nayeem N, Silletti S, Yang X, Lemmon VP, Reisfeld RA, Stallcup WB, Montgomery AM (1999) A potential role for the plasmin(ogen) system in the posttranslational cleavage of the neural cell adhesion molecule L1. J Cell Sci 112: 4739-4749.[Abstract]
Nishimura SL, Boylen KP, Einheber S, Milner TA, Ramos DM, Pytela R (1998) Synaptic and glial localization of the integrin alphavbeta8 in mouse and rat brain. Brain Res 791: 271-282.[Web of Science][Medline]
Oka T, Hakoshima T, Itakura M, Yamamori S, Takahashi M, Hashimoto Y, Shiosaka S, Kato K (2002) Role of loop structures of neuropsin in the activity of serine protease and regulated secretion. J Biol Chem 277: 14724-14730.
[Abstract/Free Full Text] Okabe A, Momota Y, Yoshida S, Hirata A, Ito J, Nishino H, Shiosaka S (1996) Kindling induces neuropsin mRNA in the mouse brain. Brain Res 728: 116-120.[Web of Science][Medline]
Perreault P, Avoli M (1989) Effects of low concentration of 4-aminopyridine on CA1 pyramidal cells of the hippocampus. J Neurophysiol 61: 953-970.
[Abstract/Free Full Text] Persohn E, Schachner M (1990) Immunohistological localization of the neural cell adhesion molecules L1 and NCAM in the developing hippocampus of the mouse. J Neurocytol 19: 807-819.[Web of Science][Medline]
Shimizu C, Yoshida S, Shibata M, Kato K, Momota Y, Matsumoto K, Shiosaka T, Midorikawa R, Kamachi T, Kawabe A, Shiosaka S (1998) Characterization of recombinant and brain neuropsin, a plasticity-related serine protease. J Biol Chem 273: 11189-11196.
[Abstract/Free Full Text] Soderling TR, Derkach VA (2000) Postsynaptic protein phosphorylation and LTP. Trends Neurosci 23: 75-80.[Web of Science][Medline]
Srinivasan Y, Elmer L, Davis J, Bennett V, Angelides K (1988) Ankyrin and spectrin associate with voltage-dependent sodium channels in brain. Nature 333: 177-180.[Medline]
Staubli U, Chun D, Lynch G (1998) Time-dependent reversal of long-term potentiation by an integrin antagonist. J Neurosci 18: 3460-3469.
[Abstract/Free Full Text] Tang L, Hung CP, Schuman EM (1998) A role for the cadherin family of cell adhesion molecules in hippocampal long-term potentiation. Neuron 20: 1165-1175.[Web of Science][Medline]
Toni N, Buchs PA, Nikonenko I, Bron CR, Muller D (1999) LTP promotes formation of multiple spine synapses between a single axon terminal and a dendrite. Nature 402: 421-425.[Medline]
Toni N, Buchs PA, Nikonenko I, Povilaitite P, Parisi L, Muller D (2001) Remodeling of synaptic membranes after induction of long-term potentiation. J Neurosci 21: 6245-6251.
[Abstract/Free Full Text] Weiler IJ, Greenough WT (1991) Potassium ion stimulation triggers protein translation in synaptoneurosomal polyribosomes. Mol Cell Neurosci 2: 305-314.[Medline]
Yoshida S, Shiosaka S (1999) Plasticity-related serine proteases in the brain [review]. Int J Mol Med 3: 405-409.[Web of Science][Medline]
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