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The Journal of Neuroscience, October 15, 2000, 20(20):7505-7509
Deficiency of Complement Defense Protein CD59 May Contribute to Neurodegeneration in Alzheimer's Disease
Li-Bang Yang1, Rena Li1, Seppo Meri2, Joseph Rogers1, and Yong Shen1 1 L. J. Roberts Center for Alzheimer's Research, Sun Health Research Institute, Sun City, Arizona 85351, and 2 Department of Immunology, Haartman Institute, University of Helsinki, Finland
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Complement defense 59 (CD59) is a cell surface glycophosphoinositol (GPI)-anchored protein that prevents complement membrane attack complex (MAC) assembly. Here, we present evidence from ELISA assays that CD59 protein levels are significantly decreased in the frontal cortex and hippocampus of Alzheimer's disease (AD) compared with nondemented elderly (ND) patients, whereas complement component 9, a final component to form MAC, is significantly increased. To further confirm the CD59 deficit, PI-specific phospholipase C (PIPLC) was used to cleave the CD59 GPI anchor at the cell surface in intact slices from AD and ND cortex. CD59 released by PIPLC cleavage was significantly reduced in AD compared with ND samples. By the use of a ribonuclease protection technique, amyloid
-peptide was found to downregulate CD59 expression at the mRNA level, suggesting a partial explanation of CD59 deficits in the AD brain. To evaluate the pathophysiological significance of CD59 alterations in neurons, we exposed cultured NT2 cells, which normally underexpress CD59, and NT2 cells transfected to overexpress CD59 to homologous human serum. Lactic acid dehydrogenase assays revealed significant complement-induced cell lysis in CD59-underexpressing NT2 cells and significant protection from such lysis in CD59-overexpressing NT2 cells. Moreover, cells expressing normal levels of CD59 showed no evidence of MAC assembly or damage after exposure to homologous serum, whereas pretreatment of these cells with a CD59-neutralizing antibody resulted in MAC assembly at the cell surface and morphological damage. Taken together, these data suggest that CD59 deficits may play a role in the neuritic losses characteristic of AD.
Key words: neurodegeneration; Alzheimer; neuron death; amyloid protein; complement; inflammation
INTRODUCTION
The activation of complement in Alzheimer's disease (AD) seems to occur via a unique, amyloid
; McGeer et al., 1989
One of the major defense mechanisms against MAC attack is that most cells express complement defense 59 (CD59) (membrane inhibitor of reactive lysis), a glycophosphoinositol (GPI)-anchored membrane protein that binds C8 or C9 and thereby prevents further assembly of the poly-C9 MAC and its full insertion into the cell membrane (Zalman et al., 1989
Here, we demonstrate a significant deficit in CD59 expression in AD compared with nondemented elderly (ND) hippocampus and cortex plus a significant increase in the levels of C9, the critical determinant of MAC pore formation and toxicity, in the same areas. As shown by further culture studies, such deficits in CD59 expression increase the vulnerability of neuron-like cells to homologous complement attack, a mechanism that may be relevant to AD because we also observe a significant correlation between immunoreactive synaptophysin and immunoreactive CD59 in the AD brain.
MATERIALS AND METHODS
Brain samples for research. Frontal neocortex and hippocampus samples from clinically diagnosed, neuropathologically confirmed AD and ND patients were frozen at autopsy and stored in vacuum-sealed plastic bags at
80°C until assay. A board-certified neuropathologist using CERAD criteria performed the neuropathology evaluation. Postmortem intervals averaged <3 hr. We have randomly selected 42 cases that consist of 22 AD cases (including 10 females, AD history of 7.5 ± 1.13 years, and 12 males, AD history of 7.3 ± 0.68 years) and 20 aged-matched and nondemented control cases (12 males and 8 females). All of the cases we have used died from lung or kidney failure, and they did not have other CNS diseases, sudden death, or infectious diseases on the basis of clinical records and pathological examination. However, it is possible that some particular infectious diseases might affect CD59 expression. Therefore, we have excluded patients with immunological disorders or severe infectious diseases. Age (XAD = 84.6 ± 6.12 years; XND = 84.0 ± 8.12 years) and postmortem intervals (XAD = 2.65 ± 0.77 hours; XND = 2.63 ± 0.94 hours) did not differ significantly between the patient groups and, in fact, were well matched.
ELISA assays of CD59 and C9. For CD59 and C9 ELISAs, purified CD59 standard, purified C9 standard, or brain cortex homogenates were added to polyclonal anti-CD59 (Serotec, Indianapolis, IN) or anti-C9 (PharMingen, San Diego, CA) antibody-coated plates and incubated at 25°C for 2 hr to permit CD59 or C9 capture. To bind captured CD59 or C9, 100 µl of 0.3 µg/ml monoclonal anti-CD59 antibody (PharMingen) or anti-C9 antibody (Quidel, San Diego, CA) was added. Biotinylated anti-mouse IgG and avidin-conjugated HRP and o-phenylenediamine dihydrochloride were used to detect binding. The specificity of the ELISA protocols was verified by serial dilutions of purified CD59 and C9 standards. Pilot studies with the CD59 ELISA demonstrated that it could detect as little as 3-8 pg/ml CD59 (data not shown).
Western blot analysis. AD and ND brain samples were individually homogenized in 5 vol of homogenizing buffer containing 10 mM Tris-HCl, pH 7.4, 25 mM NaCl, 50 mM EDTA, 1 mM EGTA plus 0.5% Triton X-100, 10% SDS, and a protease inhibitor cocktail (Boehringer Mannheim, Indianapolis, IN; 1 mM phenylmethylsulfonyl fluoride, 1 µg/ml pepstatin A, 5 µg/ml leupeptin, and 2 µg/ml aprotinin). For each sample, 20 µg of protein was separated on a 15% SDS Tricine gel and transferred to a polyvinylidene difluoride membrane electrophoretically for 2 hr with 0.1% Tween 20 in TBS. For CD59, a tissue membrane sample was used. The brain samples were homogenized in 5 vol of buffer containing 50 mM phosphate, pH 7.7, and a protease inhibitor cocktail. The tissue membrane sample (25000 × g; 30 min) was collected and dissolved in the homogenizing buffer. CD59 was detected with an affinity-purified antibody (Serotec) at a 1:1000 dilution for 12 hr at 4°C, followed by incubation with an HRP-conjugated secondary antibody and processing using ECL detection (Amersham Pharmacia Biotech).
PI-specific phospholipase C cleavage. PI-specific phospholipase C (PIPLC) was purchased from Sigma (St. Louis, MO) and diluted to graded concentrations of PIPLC from 0.0375 to 0.6000 units/ml in PBS. AD and ND brain samples were cut into 130 × 130 × 350 µm slices by the use of a McIlwain tissue chopper and then incubated at 37°C for 60 min with 0.5 ml of reaction buffer containing 5 mM EDTA, a protease inhibitor cocktail (Boehringer Mannheim), and the above-listed PIPLC solution. After incubation, the samples were centrifuged for 10 min at 20,000 × g, and the supernatant was collected. The cleaved CD59 was then measured by the use of CD59 ELISA.
Ribonuclease protection assay. Total RNA was prepared from A
-32P]UTP. The ribonuclease protection assay was performed with a commercially available kit (RPAII kit; Ambion). Three micrograms of total RNA were hybridized with 0.3 ng of the cRNA probe (specific activity, 5 × 107 cpm/µg of RNA) at 48°C for 16 hr and then digested with a mixture of RNase A and T1. The protected bands were separated on a 6% denaturing acrylamide gel and detected by autoradiography. The intensity of the bands was quantified by an imaging analyzer (Chemimager 4000). A riboprobe that was directed at
Cloning of human CD59 and C9. Poly(A+) RNA was isolated from the human brain cortex, and cDNA was synthesized with reverse transcriptase. PCR was used to amplify the coding regions of the CD59 and C9 genes. For convenience, the PCR primers were adapted to contain Xho and Xba restriction enzyme sites. The PCR conditions used were 55, 72, and 94°C for 34 cycles. After running the PCR products in a low-melting agarose gel, the specific band was excised and cloned into a pcDNA3.1 expression vector. cDNA plasmid products for CD59 and C9 were sequenced by the method of Sanger, and the sequences were found to be identical to the published gene bank DNA sequences for CD59 or C9.
Cell culture. Human NT2 cells, which can be terminally differentiated into cells bearing numerous specific characteristics of neurons (Shen et al., 1997
Cell transfection. Exogenous DNA transfection followed the calcium phosphate precipitation procedure. For transient transfection, the CD59 or C9 cDNA was inserted into a pcDNA3.1 expression vector that directs its expression from both cytomegalovirus and simian virus 40 promoters. These constructs were transfected into NT2 cells.
Lactic acid dehydrogenase assay. For quantitative assessment of neuronal cell damage, the release of lactic acid dehydrogenase (LDH) from degenerating neurons was measured by the use of a CytoTox 96 nonradioactive cytotoxicity assay kit (Promega, Madison, WI) as described previously (Piddlesden and Morgan, 1993
A
RESULTS
CD59 reduction in AD brains
Using the ELISA assay for CD59, we are able to measure CD59 protein levels at the picogram level. Brain homogenates were assayed in triplicate, and the mean for each sample was used in further calculations. The average yield of total protein, 40 mg/gm wet weight of tissue, was the same for both ND and AD hippocampus and frontal cortex tissue samples. The yield of total protein did not correlate with age at the time of death or with the postmortem interval for ND or AD patients (data not shown).
The CD59 ELISA quantitation of 20 ND and 22 AD hippocampus and frontal cortex tissue homogenates was performed as described in Materials and Methods. The specificity of the ELISA protocol was verified by testing purified CD59 samples in the same ELISA (Wertkin et al., 1993
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Figure 1. Reduction of CD59 by ELISA in the AD and ND brains. The data represent the mean (± SE) quantification analysis of 20-22 cases using a specific ELISA assay showing that CD59 immunoreactivity was decreased by 52% in AD compared with ND (nondemented aged-matched controls). Results from three independent measurements displayed a significant difference between AD and ND samples (*p < 0.05).
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Figure 2. Relationship of CD59 deficiency to neuronal or synaptic loss in AD brains. A, Western blot studies on CD59, synaptophysin, and neuron-specific enolase (NSE) in AD and ND brains are shown. B, Data represent the mean (± SD) quantification analysis using densitometry imaging (Chemimager 4000) showing that CD59 immunoreactivity was decreased by 39% in AD compared with ND, whereas synaptophysin was decreased ~26%. There is no significant change in NSE expression levels. Results from three independent measurements displayed a significant difference between AD and ND samples (**p < 0.01). AIDV, Average integrated density value.
CD59 is a GPI-anchored membrane protein that is susceptible to PIPLC cleavage. Because CD59 is specifically bound to the cell surface, to verify further the CD59 deficit in AD brains, we have used PIPLC, an enzyme that cleaves GPI-anchored proteins from the cell surface, to cleave the GPI-anchored protein from hippocampus sections. After PIPLC was incubated with these tissue sections from AD and ND brains (n = 6) at graded concentrations (0.0375-0.6 units/ml), ELISA assays again demonstrated a significant CD59 deficit in AD compared with ND patients (p < 0.01). As seen in Table 1, after incubation with increasing concentrations of PIPLC, increasing amounts of CD59 were released. AD groups had significantly lower concentrations of CD59 than that found in ND groups at each PIPLC concentration treatment (Table 1). These results are consistent with the CD59 ELISA data from the AD and ND brain homogenates and further suggest that the normal brain has much higher levels of membrane-bound CD59.
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Table 1. Effects of PIPLC treatment on the amount of CD59 released in hippocampus tissue sections from AD and ND brains To analyze steady-state levels of CD59 mRNA in the cortical tissues, a ribonuclease protection assay was performed on brain tissues from AD and ND patients. A riboprobe that directs to the
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Figure 3. CD59 mRNA expression in the AD brain and A
It is well established that one of the pathological hallmarks in the AD brain is the presence of plaques containing A
C9 production in AD brains
Because the complement C9 component is a final component to be added into the C5b-8 subcomplex of MAC, it would be important to examine whether the C9 expression level is altered in the same regions where CD59 protein is deficient in AD brains. To address this issue, C9 component levels in frontal cortex and hippocampus brain homogenates were measured by C9 ELISA. We found that C9 protein levels were significantly elevated in both the frontal cortex (p < 0.05) and hippocampus (p < 0.01) of AD compared with ND patients (Fig. 4). Within subjects, C9 and CD59 protein levels were significantly correlated across all patients (r = 0.88; p < 0.01) and in the AD group alone (r = 0.81; p < 0.01).
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Figure 4. C9 production in AD brains. Data represent the mean (± SE) quantification analysis of 20-22 cases using a specific ELISA assay showing that C9 immunoreactivity was increased by 35% in AD compared with ND. Results from repeated measurements displayed a significant difference between AD and ND samples (*p < 0.05; **p < 0.01).
Relationship of CD59 deficiency to neuronal or synaptic loss in AD brains
Densitometry of CD59-immunoreactive bands in CD59 Western blots and of NSE- or synaptophysin-immunoreactive bands in Western blots from the same patients and the same brain regions showed a 26% reduction in synaptophysin and a 39% decrease in CD59 in AD frontal tissue compared with that found in ND tissue (Fig. 2). Furthermore, this analysis revealed a significant correlation between CD59 and synapse decrements (r = 0.81; p < 0.05). We also note that the decreased level (52%) of CD59 from ELISA data is lower than that from the Western blot study (39%), suggesting that our CD59 ELISA is more sensitive than regular Western analysis. Meanwhile, we have also used NSE, a neuronal cell body marker, to evaluate neurodegeneration in AD brains (Fig. 2). Our results demonstrate that NSE has little change between AD and ND brains. These results suggest that CD59 deficiency may cause neuronal vulnerability and that the CD59 deficiency may not be entirely caused by neuronal loss.
CD59 deficiency and overexpression in in vitro models
To determine further the possible activity of CD59 on neurons, cultured NT2 cells, which normally underexpress CD59, and NT2 cells, transfected to overexpress CD59, were exposed to 1-3% homologous human complement-containing serum. LDH assays revealed significant complement-induced cell lysis in CD59-underexpressing NT2 cells and significant protection from such lysis in CD59-overexpressing NT2 cells (Fig. 5).
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Figure 5. Overexpression of CD59 protects neurons against cell lysis by complement. Human neuronal NT2 cells were transfected with human CD59 cDNA and then exposed to 1 and 3% human complement for 24 hr. Values represent the mean (± SE) of four separate determinations (**p < 0.01 when compared with transfected and nontransfected cells by Student's paired t test).
C9 overexpression and MAC induction in vitro
In AD brains, we found a CD59 deficit and C9 elevation. To examine further whether the upregulated complement C9 component would functionally induce MAC formation in vitro, silver enhancement of the peroxidase-diaminobenzidine (DAB) immunocytochemistry technique was used for MAC detection. MAC was detected on cells only after C9 transfection before C9-deficient serum treatment in NT2 cells (Fig. 6D). No MAC DAB-silver deposit was observed with C9-deficient serum alone, in C9-transfected cells alone, or in nontransfected cells (Fig. 6A-C). Dramatic morphological changes, e.g., broken neurites, in C9-transfected NT2 cells were noted at 18 hr after treatment with C9-deficient serum (Fig. 6D).
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Figure 6. Detection of MAC from human neuronal cells by silver-staining enhancement for peroxidase-DAB. A, Cells after supplementation with human C9-deficient serum yielded minimal MAC detection in cells expressing CD59. B-D, Anti-CD59 antibody treatment alone for 18 hr (B), A
DISCUSSION
This is the first report of CD59 deficits in the AD brain. The absence of membrane-bound CD59 has been suggested to be causally related to the increased vulnerability of AD neurons to complement attack (Shen et al., 1998
We have developed an ELISA method to measure the CD59 protein at the picogram level. This assay demonstrates specific CD59 detection by the use of purified CD59 as an internal control. Moreover, we have characterized CD59 protein expression using Western blotting and found that a single band was detectable using each anti-CD59 antibody used in the ELISA (data not shown), suggesting that the antibodies are specific to CD59 detection. Because CD59 is expressed in all areas of the brain, one would expect that when PIPLC cleaves GPI-anchored CD59 proteins from ND brain slices, the released soluble CD59 in the media would be increased. However, if CD59 is previously lost in the AD brain, the cleaved CD59 in the media by PIPLC from AD brain slices would continue to be detected at the low level. Our experimental results support this hypothesis.
The level of CD59 released by PIPLC from both AD and ND brain slices was proportionally increased as the PIPLC concentration rose (Table 1), and we also found no mutation in the CD59 polymorphism (data not shown), suggesting that PIPLC cleaves the same site of CD59 in both AD and ND cases.
Although deficiency of CD59 might render cells vulnerable to MAC-mediated attack, it is possible that exposure to complement also might stimulate and increase CD59 expression in AD. Two studies (McGeer et al., 1991
In the present study, analyses of CD59 mRNA and protein levels were performed using the same tissue samples from cortex regions of AD and nondemented aged-matched controls. All the tissues were collected, stored, and processed similarly. By the use of the RNase protection assay, examination of the CD59 mRNA expression in both AD and ND brain tissues and the effect of A
FOOTNOTES Received July 3, 2000; revised July 20, 2000; accepted July 20, 2000.
This work was supported by grants from the Alzheimer's Association and the Arizona Alzheimer's Research Center and by National Institute of Aging Grant NIAAGO7367. We thank Dr. T. Beach for the neuropathology evaluation and L. Sue, S. Guest, K. Lindholm, M. Gurule, and R. Lee for technical assistance.
Correspondence should be addressed to Dr. Yong Shen, L. J. Roberts Center for Alzheimer's Research, Sun Health Research Institute, P.O. Box 1278, Sun City, AZ 85351. E-mail: yshen{at}mail.sunhealth.org.
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