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Previous Article | Next Article
Volume 16, Number 24, Issue of December 15, 1996 pp. 7910-7919
Copyright ©1996 Society for NeuroscienceMatrix Metalloproteinase-9 (MMP-9) Is Synthesized in Neurons of the Human Hippocampus and Is Capable of Degrading the Amyloid-
Peptide (1-40)
Jon R. Backstrom1, Giselle P. Lim2, Michael J. Cullen2, and Zoltán A. Tökés1, 3 Departments of 1 Biochemistry and Molecular Biology and 2 Cell and Neurobiology, and the 3 USC/Norris Comprehensive Cancer Center, School of Medicine, University of Southern California, Los Angeles, California 90089
ABSTRACT
We reported earlier that the levels of Ca2+-dependent metalloproteinases are increased in Alzheimer's disease (AD) specimens, relative to control specimens. Here we show that these enzymes are forms of the matrix metalloproteinase MMP-9 (EC3.4.24.35) and are expressed in the human hippocampus. Affinity-purified antibodies to MMP-9 labeled pyramidal neurons, but not granular neurons or glial cells. MMP-9 mRNA is expressed in pyramidal neurons, as determined with digoxigenin-labeled MMP-9 riboprobes, and the presence of this mRNA is confirmed with reverse transcriptase PCR. The cellular distribution of MMP-9 is altered in AD because 76% of the total 100 kDa enzyme activity is found in the soluble fraction of control specimens, whereas only 51% is detectable in the same fraction from AD specimens. The accumulated 100 kDa enzyme from AD brain is latent and can be converted to an active form with aminophenylmercuric acetate.
MMP-9 also is detected in close proximity to extracellular amyloid plaques. Because a major constituent of plaques is the 4 kDa
Key words: matrix metalloproteinases; Alzheimer's disease; amyloid cleavage; amyloid plaques; gelatinase; protease activation-amyloid peptide, synthetic A
INTRODUCTION
The amyloid
). An enzyme termed
-secretase cleaves amyloid precursor protein (APP) within the A
The secreted portions of APPs contain inhibitor domains that may regulate the activities of extracellular proteinases. Secreted APP-751 and APP-770, termed protease nexin II, contain a serine proteinase inhibitor domain that inactivates chymotrypsin-like enzymes (Kitaguchi et al., 1988
The human hippocampus contains proteinases that are biochemically similar to the Ca2+- and Zn2+-dependent MMP family (Backstrom et al., 1992
APMA causes the autocatalytic conversion of the latent MMPs to active forms by a ``cysteine switch'' mechanism (Sprinman et al., 1990
The cleavage sites of A
MATERIALS AND METHODS
Tissue specimens. Hippocampal specimens were obtained from the Alzheimer's Disease Research Center at the University of Southern California. Ten Alzheimer's patients (3 males and 7 females) and seven normal patients who died of non-neurological disorders (5 males and 2 females) were used in this study. Patients with metastatic cancer to the brain or cerebral hemorrhage were excluded. The ages of the patients ranged from 33 to 91 years; the mean age of Alzheimer's patients was 76.4 ± 7.9 and 64 ± 19 years for normal patients. The mean postmortem interval (PMI) for Alzheimer's patients was 4.3 ± 2.7 and 10.3 ± 4.2 hr for normal patients. Previous studies indicated that PMIs <15 hr did not affect the activities of MMPs (Backstrom et al., 199270°C for various biochemical experiments or fixed in 4% paraformaldehyde for immunohistochemistry.
Table 1.
ID# Age Sex PMI Ethnicity Age of onset Autopsy diagnosis Education Family history MMSE CDR BNT 4 63 M 11 Cauc 49 AD 12 No 0 1 1 41 80 F 2 Cauc 68 AD 16 Mother, sister 0 NA NA 107 82 F 2.5 Cauc 69 AD 11 Cousin 1 NA NA 161 73 M 7.5 Cauc 64 AD/MID 12 Mother, brother (Parkinson's) 0 NA NA 206 81 F 4 Cauc 65 AD 14 No 1 NA NA 235 72 M 2.3 Cauc 61 AD 13 Two aunts 0 NA NA 342 91 F 5 Cauc 77 AD 12 NO NA 3 NA 538 66 F 3 Cauc 57 AD 12 Mother, grandmother 9 2 21 595 75 F 3.5 Cauc 57 AD NA Mother, uncle NA 3 NA 602 81 F 2.2 Cauc NA AD NA NA NA NA NA 95 77 F 3.3 Cauc Not appl Norm 12 Brother, grandmother, two uncles 30 0 52 343 83 M 14 Af-Am Not appl Norm NA NA NA NA NA 351 71 M 11.5 Af-Am Not appl Norm NA NA NA NA NA 359 64 M 11 Cauc Not appl Norm NA NA NA NA NA 381 38 M 8.5 NA Not appl Norm NA NA NA NA NA 559 82 F 17 Cauc Not appl Norm 12 No 27 0 54 612 33 M 7 Af-Am Not appl Norm NA NA NA NA NA PMI, Postmortem interval is given in hours; NA, not available; Not appl, not applicable; MMSE, Mini Mental State Examination [where a score of 22 or less (of a possible 30) indicates dementia]; CDR, Clinical Dementia Rating (where 0 = normal and 3 = moderate dementia); BNT, Boston Naming Test (where the highest score is 60); Cauc, Caucasian; Af-Am, African-American.
Assessment of metalloproteinase activities in hippocampal fractions. Matrix proteinase activities were measured by gelatin zymography on hippocampal specimens from 10 AD and 7 control patients (Backstrom et al., 1992
For the substrate gel assay, 40 µl of the Tris-, Triton-, and SDS-soluble fractions (containing identical tissue weight-equivalents per fraction) were electrophoresed in gelatin-containing substrate gels as described [Backstrom et al. (1992)
For the gelatin-biotin assay, Tris-soluble samples were analyzed as described (Davis and Martin, 1990
The gelatinase activity of a soluble brain fraction was compared with the activity of 3.3 mg of wet weight tissue. Therefore, specific activities (nanograms of chymotryptic-equivalent activity in soluble fraction/mg tissue) can be calculated by dividing the activities by 3.3.
For the activation of latent enzymes, the Tris-soluble fractions containing protease inhibitors were collected and treated with 1 mM APMA at 37°C. Aliquots (100 µl) were removed at the appropriate times (0, 6, 12, and 24 hr), treated with 100 µl of 2× sample buffer, and stored overnight at 4°C. Zymography was performed with 7.5% substrate gels.
Purification of MMP-9 from cell cultures. MMP-9 was purified from the conditioned media of the human promyelocytic leukemia cell line HL-60. Stimulation of these cells with phorbol esters causes them to secrete predominantly latent forms of MMP-9 (Davis and Martin, 1990
Immunodepletion of MMP-9 activity. All procedures were performed at 4°C. Brain tissue (150 mg) was cut from snap-frozen specimens and washed 4× in PBS. Three wet-weight volumes of TBS containing a proteinase inhibitor cocktail (50 µg/ml leupeptin, 50 µg/ml pepstatin A, and 50 µg/ml phenylmethylsulfonyl fluoride in 1% DMSO) were added, and the samples were incubated for 15 min. The samples were sonicated at 100 W for two 10 sec intervals and centrifuged for 30 min at 13,000 × g. The supernatant was collected, and the total soluble brain protein concentration was determined. On the basis of our previous observation that a representative sample of 200 µg of brain protein contained ~10 ng of MMPs (Backstrom, unpublished data), 50 µl samples were incubated with an estimated 40-fold excess of murine monoclonal MMP-9 antibodies (Oncogene Science, Cambridge, MA). Two different monoclonal antibodies were used; Ab-1 recognizes both the latent and active forms of human MMP-9, whereas Ab-2 recognizes only the latent form. The specificity of monoclonal antibodies was established with Western blots and HT1080 cell culture supernatant in which only MMP-9 was recognized (Oncogene Science). The solutions were incubated for 8-12 hr with gentle rocking. Aliquots of protein G-Sepharose beads (Sigma) were added in an estimated 300-fold excess of the amount of antibodies added, and samples were incubated for 10-12 hr. The samples were centrifuged for 30 min at 13,000 × g to spin down the beads, and the supernatant was removed for zymography to determine the remaining enzyme activities. Controls were incubated with only the protein G-Sepharose beads. Supernatant containing 200 µg of brain protein was electrophoresed as described before, and the gels were incubated in 5 µM ZnCl2 for 60 min before the final incubation in 5 mM CaCl2 for 18 hr at 37°C; the Coomassie blue-stained gels were scanned as outlined before.
Preparation of tissue sections. Tissue sections were fixed in 4% paraformaldehyde (J. T. Baker Chemical Company, Phillipsburg, NJ) in PBS for 1-7 d. The samples were rinsed in PBS for 1 d and cryoprotected in 5% sucrose in PBS for 1 d, followed by 15% sucrose in PBS for 1-2 d. Tissue specimens were frozen in the vapor phase of liquid nitrogen on cryostat blocks with Tissue-Tek O.C.T. (Miles, Elkhart, IN). Sections were cut (8 µm) on a Reichert Histostat at
Immunolocalization of metalloproteinases. Rabbit anti-MMP-9, a generous gift of Dr. Margaret Hibbs (Veterans Administration Medical Center, Newington, CT), was affinity-purified with enzymes that were partially purified from cell cultures. The antibodies were purified against the activated form of MMP-9. Material from the gelatin-agarose column (50 µg of protein from the first step of purification; see above) was activated with APMA, electrophoresed in preparatory SDS-polyacrylamide gels, and then Western-blotted to nitrocellulose. The paper was incubated in 0.1% Ponceau S in 5% acetic acid to locate and cut out the activated and stained 84 kDa region. The nitrocellulose strip was incubated in a Tris buffer, pH 7.6, containing 3% BSA for 2 hr at RT, and then incubated with antisera diluted 1:10-1:50 in TBS containing 1% BSA. After 1-2 hr at RT, the nitrocellulose was washed with TBS, and the antibodies were desorbed with 4 ml of a 0.05 M glycine buffer, pH 3.0. The buffer that contained the antibodies was neutralized with 40 µl of 1.0 M Tris, pH 9.0, and then concentrated and exchanged for TBS in Centricon-30 units (30,000 molecular weight cutoff; Amicon, Denvers, MA). The affinity-purified antibodies were stored at 4°C. The specificity of the antibodies was established with Western blots that used HL-60 cell culture supernatant in which only the latent and active forms of MMP-9 were recognized (data not illustrated).
Sections from five AD and three control hippocampal specimens were treated with anti-MMP-9 to determine the location of the enzyme in situ. Sections were rinsed three times for 10 min with PBS and then incubated with PBS containing 10% ethanol and 1% H202 for 30 min. After three rinses with PBS, the sections were incubated for 15 min in a blocking buffer (PBS containing 5% BSA and 1% normal goat serum; Dako, Carpinteria, CA). Subsequently, the sections were incubated for 1 hr at RT with anti-MMP-9 diluted to a final concentration of 6 µg/ml in blocking buffer. After several rinses with PBS, the sections were processed with the peroxidase ABC kit according to the manufacturer's recommendations (Vector Laboratories, Burlingame, CA). Negative controls consisted of sections incubated in solutions of preimmune rabbit serum (Dako). To identify plaques, we stained sections by a modified Bielschowsky stain.
To determine the percentage of MMP-9-labeled cells, we counted the numbers of positively and negatively stained pyramidal neurons on three sections from two representative AD patients (average age of 78 years). A 20× objective lens was used to review the slides, and any pyramidal cell >25 µm diameter present within the field was assessed. Representative areas from each CA region were counted in duplicate.
In situ hybridization of metalloproteinase mRNA. The matrix metalloproteinase-9 gene (Wilhelm et al., 1989 UTR and sequences that encode the pre- and pro-domains of the enzyme. The fragment was cloned into the respective sites in pBluescript II KS(+) (Stratagene, La Jolla, CA). The identity of the insert was confirmed by restriction mapping and partial sequencing. The plasmid was column-purified (Qiagen, Chatsworth, CA) and digested with BssHII (Boehringer Mannheim, Indianapolis, IN); the fragment containing the polymerase sites was gel-purified (Bio-101, La Jolla, CA). Riboprobes were generated with T3 or T7 polymerases (Promega, Madison, WI) and an NTP mix containing digoxigenin-UTP (Boehringer Mannheim). The concentrations of the riboprobes were quantified as per the manufacturer's recommendations (Boehringer Mannheim), and the integrity of the probes was checked in agarose gels.
In situ hybridizations were performed with AD and control hippocampal tissues that also were evaluated by immunohistochemistry. The sections were treated with 0.25% acetic anhydride in 0.1% triethanolamine, pH 8.0, for 0.5 hr. The tissues were prehybridized for 2 hr at 37°C in Northern prehybridization buffer (5 Prime-3 Prime, Boulder, CO) containing 200 µg/ml salmon sperm DNA and 200 µg/ml yeast tRNA, 45% formamide (Sigma), and 5% vanadate ribonucleotide complex. The riboprobes were diluted to 0.1 ng/µl in Northern hybridization buffer (5 Prime-3 Prime), which contained the same additives as the prehybridization buffer, added to the sections, and incubated for 18 hr at 37°C. The slides were washed extensively with 4× SSC (20× SSC = 3 M NaCl and 0.3 M sodium citrate, pH 7.0) and then with 1× SSC at RT. The sections were treated with 1% normal sheep serum (Dako) in TBS for 1 hr at RT. Alkaline phosphatase-labeled anti-digoxigenin (Boehringer Mannheim) was added to the sections at a dilution of 1:500 for 1 hr at RT. The washed slides were incubated for 12 hr at RT with nitro blue tetrazolium, 5-bromo-4-chloro-3-indolyl phosphate, and 0.25 mg/ml levamisole prepared in phosphatase buffer containing (in mM): 50 Tris-HCl, 100 NaCl, and 5 MgCl2, pH 9.5.
Detection of MMP-9 mRNA with RT-PCR. The isolation of mRNA from AD hippocampal specimens was based on the method of Chomczynski and Sacchi (1987)
A pool of normal human hippocampal poly(A+) RNA (aged 16-72 years, Clontech, Palo Alto, CA) was reverse-transcribed with random hexamers and Superscript II transcriptase according to the manufacturer's instructions (Life Technologies). After digestion with RNase H, cDNA was PCR-amplified with Taq polymerase (Perkin-Elmer, Norwalk, CT), which used previously described primers (Devarajan et al., 1992
Digestion of A
RESULTS
To examine the subcellular distribution of the metalloproteinase activities in the human hippocampus, we fractionated four representative AD and four control tissues sequentially into Tris-soluble, Triton-soluble, and then SDS-soluble fractions. The three fractions were electrophoresed in substrate gels and then incubated in a buffer overnight to allow the enzymes in the polyacrylamide gel to digest the gelatin substrate. Table 2 shows that the distribution of the 100 kDa metalloproteinase differs between AD and control tissues. The majority (76 ± 11%) of extractable activity from normal aged tissues was found in the Tris-soluble fraction, and the remaining 24% of the total activity was located in the SDS-soluble fraction. In contrast, 51 ± 16% of the activity from the AD samples was partitioned to the Tris-soluble fraction. No significant activity was found in the Triton-soluble fraction. In contrast to the 100 kDa activity, no differences between AD and control tissues were observed in the three fractions for the 70 kDa activity (data not illustrated).
Table 2. Distribution of the 100 kDa form of MMP-9 activities from hippocampus fractions
Fractiona Tris-soluble Triton-soluble SDS-soluble Alzheimer 51 (61)b 1 (1) 48 (16)b Control 76 (11)b 0 (0) 24 (11)b Four Alzheimer (Patient ID Nos. 4, 41, 161, 235) and four control tissues (Patient ID Nos. 343, 351, 359, 381) were fractionated sequentially into Tris-soluble, 1% Triton-soluble, and SDS-soluble fractions (see Materials and Methods for experimental details). The average ages were 72 and 64 years for the AD and control patients, respectively. All four AD patients had severe-to-moderate neurofibrillary tangles and neuritic plaques. Of the control patients, only one (No. 343) had moderate neurofibrillary tangles, but no neuritic plaques; all others had mild or no tangles and no plaques. a The percentage of activity in each fraction for the 100 kDa form of MMP-9. The percentage of SD is listed in parentheses. b The difference in MMP-9 activity from Alzheimer and control samples was significant at p < 0.05 (t test).
The Tris-soluble brain fractions were treated with APMA to determine whether the 100 kDa enzyme is latent or active. In the presence of APMA, the enzyme showed a time-dependent decrease in both molecular mass and in activity of the 100 kDa latent form (Fig. 1A). A time-dependent increase was observed in the 90 kDa form of the activated enzyme. A decrease in the molecular mass of the 130 kDa latent form to 120 kDa also was observed. 
Fig. 1. Activation of latent MMP-9 from the hippocampus. A, Densitometric scan of a substrate gel with gelatin as the substrate. Aliquots of the inhibitor-treated soluble brain fraction were incubated in the absence (
[View Larger Version of this Image (17K GIF file)]
To measure the increase in MMP activity after APMA activation, we performed the gelatin-biotin plate assay with the Tris-soluble brain fraction from a representative AD sample. Approximately 0.5 ng of chymotryptic-equivalent gelatinase activity was observed before activation (Fig. 1B). At the addition of APMA for 1 and 3 hr (optimum activation condition), the activity increased to 26 and 35 ng, respectively. This represents a 70-fold increase in activity because of APMA activation. An APMA-activated sample was treated with the metal ion chelator 1,10-phenanthroline (1.4 mM final concentration) and then added to wells containing gelatin. After a 3 hr incubation, the activity was reduced by 93%, confirming that the gelatinase activity was divalent ion-dependent (data not illustrated).
Immunodepletion experiments established that the 100 kDa enzyme activity was removed selectively with two different specific monoclonal antibodies to MMP-9 without any decrease in the 70 kDa activity (Fig. 1C). The 130 kDa activity also was removed, indicating that this enzyme represents a complexed form of MMP-9. The 70 kDa enzyme activity was removed with specific monoclonal antibodies to MMP-2 with no effect on the 100 kDa activity (G. P. Lim et al., unpublished data). This is consistent with the observation that the 70 kDa enzyme is MMP-2, of glial origin, in ALS brain and spinal cord specimens (Lim et al., 1996
Human hippocampus sections from AD and control tissues were stained with affinity-purified antibodies and riboprobes to determine the location of MMP-9 in situ. Although anti-MMP-9 did not label cells and perivascular areas in control sections (Fig. 2A), the antibodies labeled pyramidal neurons from AD sections (Fig. 2B). Prominent cytoplasmic staining appeared granular and did not accumulate in the nuclei (Fig. 2C). However, the stained material extended into the neurites (Fig. 2D). Significant levels of immunoreactive MMP-9 were not detected either in the granule cell neurons in the dentate gyrus, glial cells, or in perivascular regions (data not illustrated). An identical staining pattern was observed with MMP-9-specific murine monoclonal antibodies. Figure 3 summarizes the distribution of anti-MMP-9 staining in the human hippocampus. The number of positively stained neurons varied by region. The percentage of immunoreactive pyramidal neurons in the CA1, 2, 3, and 4 regions were 78.7 ± 12.1, 61.6 ± 10.1, 52.6 ± 9.7, and 21.8 ± 3.2%, respectively. 
Fig. 2. Localization of immunoreactive MMP-9 in the human hippocampus. A, Control section demonstrating that reactivity was below the level of detection (200×). B, AD section illustrating reactivity in pyramidal cells (200×). Glial cells and perivascular areas were unstained. C, Higher magnification of pyramidal neuron from AD section showing granular accumulation of immunoreactive MMP-9 in the cytoplasm. D, Pyramidal neuron showing stained material extending into the neurite. E, Senile plaque illustrating positively stained cellular process (arrowheads). F, Neuritic processes labeled with Bielschowsky stain. (Samples from AD patients 107, 342, 538, 595, and 602 and from control patients 95, 559, and 612 were investigated. Specimens from 595 and 559 are used for illustration.)
[View Larger Version of this Image (100K GIF file)]
Fig. 3. Summary of anti-MMP-9 staining in the human hippocampus. Pyramidal neurons that were positively stained with anti-MMP-9 (filled triangles) were found in the CA1-CA3 subfields from AD sections. Increasing numbers of unstained neurons (open triangles) were seen from the CA1-CA3 regions. Neurons in the CA4 subfield, as well as granule neurons (open circles) in the dentate gyrus, were unstained. PRES, Presubiculum; PROS, prosubiculum; SUB, subiculum; PARA, parahippocampal gyrus. (Specimens from AD patients 107, 595, and 602 were used for the studies.)
[View Larger Version of this Image (19K GIF file)]
MMP-9 immunoreactivity also was detected near the extracellular amyloid plaques (Fig. 2E). The antibodies consistently labeled the cellular processes of classical and diffuse senile plaques throughout Ammon's horn (Fig. 2E, arrow), but not the dense amyloid core lesions. Bielschowsky-stained sections confirmed that these structures were the neuritic portions of the plaques (Fig. 2F).
The results from the in situ hybridization experiments that used MMP-9 riboprobes correlated with the results from immunohistology. The MMP-9 subclone containing the 5 
Fig. 4. The antisense MMP-9 riboprobe labels pyramidal neurons in the human hippocampus. The Alzheimer sections were treated with sense (A) or antisense (B) riboprobes. The CA3 region of the hippocampus is illustrated. (Specimens from patient 107 were used for the illustration.)
[View Larger Version of this Image (142K GIF file)]
Attempts to perform Northern blot analysis for MMP-9 mRNA revealed substantial RNA degradation in the postmortem brain specimens. Consequently, two sets of RT-PCR experiments were performed. In the first set of experiments, the 211 bp fragment of the MMP-9 active site region was PCR-amplified successfully from AD hippocampus specimens (Fig. 5A). Positive controls included the 275 bp fragment of human thymidylate synthase and the 252 bp fragment of human 
Fig. 5. Reverse transcriptase-PCR of hippocampus RNA. A, PCR amplification of the MMP-9 active site from an AD sample (No. 206). Lane 1, Size standards; lanes 2, 4, 275 bp fragment of the human thymidylate synthase gene and 252 bp fragment of the human
[View Larger Version of this Image (24K GIF file)]
Because endogenous MMP-9 was immunolocalized to amyloid plaques (Fig. 2E), the purified and activated enzyme was incubated with synthetic A 
Fig. 6. Summary of the results from the digestion of A
[View Larger Version of this Image (6K GIF file)]
DISCUSSION
We have demonstrated previously that the activities of a 100 kDa metalloproteinase from AD tissues were increased, relative to control tissues (Backstrom et al., 1992
Monoclonal antibodies to MMP-9 (Ab-1 and Ab-2) specifically removed the 100 kDa activity from AD brain extracts. These experiments also establish that the enzyme is in the latent form, because Ab-2 selectively binds to only the inactive proenzyme. Furthermore, activation studies confirm that the 100 kDa enzyme is latent. The APMA treatment of soluble brain fractions reduced the molecular mass by 10 kDa and increased the gelatinase activity 70-fold (Fig. 1). Furthermore, the presence of a chelating agent, 1,10-phenanthroline, inhibited >90% of the enzyme activity obtained after APMA treatment, indicating that divalent metal ions were essential for activity. These observations are consistent with previous reports for MMP-9 (Wilhelm et al., 1989
Evidence for the expression of MMP-9 in the hippocampus comes from two sets of RT-PCR experiments. A fragment of 211 bp consisting of the active site region of MMP-9 from position 1132 to 1342 (Wilhelm et al., 1989
Other metalloproteinases recently have been identified from human brain. McDermott and Gibson (1991)
To determine the cellular location of MMP-9 in the human hippocampus, we performed immunohistology and in situ hybridization experiments. In the AD hippocampus, anti-MMP-9 labeled pyramidal neurons in the CA1-CA3 fields, but not granular neurons in the dentate gyrus or glial cells (Fig. 2B-D). The distribution of MMP-9 staining corresponds to the hippocampal regions that are most affected in AD (Davies et al., 1992
The results of tissue fractionation experiments were in agreement with the immunohistochemical staining. The majority (76%) of the 100 kDa enzyme activity from control samples was partitioned in the Tris-soluble fraction, which is consistent with an enzyme that is present in a secretory form. Only 51% of the activity from the Alzheimer-affected tissue was present in the same soluble form. Less than 2% of the activity was extracted into a Triton-soluble fraction, signifying that the enzyme was not membrane-associated. Nonionic detergents were able to solubilize other metalloproteinases, such as the membrane-associated enkephalinases (Fulcher and Kenny, 1983
Because MMP-9 was detected in the regions near plaques (Fig. 2E), we questioned whether the active form of the enzyme could process the major plaque component,
Secreted, latent MMP-9 can be processed proteolytically to an active form by serine proteinases such as elastase and cathepsin G, metalloproteinases, and superoxide anions such as HOCl (Murphy et al., 1980
FOOTNOTES
Received Feb. 7, 1996; revised Sept. 3, 1996; accepted Oct. 4, 1996.
This work was supported by National Institute on Aging Grant R01-AG09681 to Z.T. We thank Dr. Audree Fowler, Protein Microsequencing Facility, and Dr. Kym Faull, Center for Molecular and Medical Sciences Mass Spectroscopy, University of California at Los Angeles, for their assistance in protein sequencing and mass spectroscopy analyses, respectively. The assistance of Dr. Peter Danenberg, Kathleen Danenberg, and Dr. Heinz-Josef Lenz with the RT-PCR studies of MMP-9 active site region is greatly appreciated.
Correspondence should be addressed to Dr. Zoltán A. Tökés, Cancer Research Laboratories, 1303 North Mission Road, Los Angeles, CA 90033.
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