Abstract
Apolipoprotein (apo) E4 is a risk factor for heart disease, Alzheimer's disease, and other forms of neurodegeneration, but the underlying mechanisms are unknown. Domain interaction, a structural property that distinguishes apoE4 from apoE2 and apoE3, results in more rapid turnover and lower plasma levels of apoE4. To determine whether domain interaction affects brain apoE levels, we analyzed brain homogenates from human apoE3 and apoE4 knock-in mice, wild-type mice, and Arg-61 apoE mice, in which domain interaction was introduced by gene targeting. As determined on Western blots, the hemibrain, cortex, hippocampus, and cerebellum of knock-in mice had 30-40% lower levels of apoE4 than apoE3, and Arg-61 mice had 25-50% lower apoE levels than wild-type mice. In the CSF, Arg-61 apoE level was 40% lower than the wild-type level. Arg-61 apoE mRNA levels were similar to or slightly higher than wild-type apoE mRNA levels. Thus, the lower Arg-61 apoE levels were not attributable to decreased mRNA levels. In culture medium from heterozygous Arg-61/wild-type and apoE4/apoE3 primary astrocytes, Arg-61 apoE and apoE4 levels were lower than wild-type apoE and apoE3, respectively, suggesting that primary astrocytes secrete lower amounts of Arg-61 apoE and apoE4. These results demonstrate that domain interaction is responsible for the lower levels of both human apoE4 and mouse Arg-61 apoE in mouse brain. Cells may recognize apoE4 and Arg-61 apoE as misfolded proteins and target them for degradation or accumulation. Thus, degradation/accumulation or lower levels of apoE4 may contribute to the association of apoE4 with Alzheimer's disease.
- apolipoprotein E
- Alzheimer's disease
- domain interaction
- knock-in mice
- wild-type mice
- Arg-61 apoE mice
Introduction
Alzheimer's disease (AD), a neurodegenerative disorder whose incidence is rapidly increasing, is the leading cause of dementia in developed countries (Hebert et al., 2003). Apolipoprotein (apo) E, a plasma lipid transport protein that contains two structural domains, also plays a major role in the brain (Weisgraber and Mahley, 1996). There are three common apoE isoforms (apoE2, apoE3, and apoE4) that differ at positions 112 and 158: apoE3 contains cysteine 112 and arginine 158, whereas apoE2 has cysteines at both positions and apoE4 has arginines (Weisgraber et al., 1981). ApoE4 is associated with increased risk of late-onset familial and sporadic AD and has a gene dose effect on the risk and age of onset (Corder et al., 1993; Saunders et al., 1993; Strittmatter et al., 1993; Roses, 1996; Tang et al., 1998). It is also associated with poor outcome from head trauma, more rapid progression of multiple sclerosis and amyotrophic lateral sclerosis, and a modest increase in risk for cardiovascular disease (Utermann et al., 1984; Luc et al., 1994; Mayeux et al., 1995; Slooter et al., 1997; Teasdale et al., 1997; Drory et al., 2001; Fazekas et al., 2001; Eichner et al., 2002). The exact function of apoE in the CNS is not clear.
ApoE4 has two major structural and biophysical characteristics that distinguish it from the other isoforms. One is domain interaction, an interaction between the N- and C-terminal domains mediated by Arg-61 and Glu-255 (Weisgraber, 1990, 1994; Dong and Weisgraber, 1996). The second is the lower stability of apoE4 and its propensity to form folding intermediates or assume a molten globule state (Morrow et al., 2002). Although domain interaction has been suggested to contribute to the detrimental effects of apoE4 in disease (Dong and Weisgraber, 1996; Weisgraber and Mahley, 1996), the existing transgenic or knock-in models cannot distinguish between the relative contributions of domain interaction versus the stability differences to the detrimental effects of apoE4.
Wild-type mouse apoE does not display domain interaction because it contains threonine rather than arginine at a position equivalent to 61. Using gene targeting, we replaced the threonine codon with an arginine codon in wild-type mouse Apoe (Raffaï et al., 2001). Arg-61 mouse apoE has stability characteristics similar to those of wild-type apoE (Hatters et al., 2005). Therefore, the gene-targeted Arg-61 mouse is a specific model for apoE4 domain interaction. In vivo, Arg-61 apoE mouse reproduced the turnover characteristics of apoE4 in plasma, demonstrating that domain interaction occurs in this model. Heterozygous mice expressing wild-type and Arg-61 apoE had lower plasma levels of Arg-61 apoE than of wild-type apoE (Raffaï et al., 2001), indicating a more rapid turnover rate resulting from domain interaction, consistent with plasma apoE4 levels and turnover studies in humans (Gregg et al., 1986).
In this study, we sought to determine whether domain interaction also causes lower levels of apoE in the CNS. To address this question, we measured apoE protein levels in the brains of human apoE3 and apoE4 knock-in mice and wild-type and Arg-61 apoE mice.
Materials and Methods
Reagents. DMEM and fetal bovine serum were from Invitrogen (Carlsbad, CA), ECL was from Amersham Biosciences (Piscataway, NJ), goat anti-human apoE antibody was from Calbiochem (San Diego, CA), and horseradish peroxidase-coupled anti-rabbit and anti-goat IgG were from Dako (Carpinteria, CA).
Mice. Human apoE3 and apoE4 knock-in mice were from Taconic (Hudson, NY). Arg-61 apoE mice were generated as described previously (Raffaï et al., 2001) and backcrossed with wild-type C57BL/6J mice eight times.
Preparation of mouse brain tissue homogenates. Brains from human apoE knock-in, wild-type, and Arg-61 apoE mice were collected after a 3 min transcardial perfusion with PBS. One hemibrain from each mouse was analyzed separately; the other was dissected into subregions (cortex, hippocampus, and cerebellum). All tissues were homogenized in ice-cold lysis buffer (50 mm Tris-HCl, pH 8.0, 150 mm NaCl, 0.1% SDS, 0.5% Nonidet P-40, 0.5% sodium deoxycholate, and a mixture of protease and phosphatase inhibitors) and centrifuged at 30,000 rpm for 30 min at 4°C using a TLA 100.3 rotor in an Optima TL Ultracentrifuge (Beckman Instruments, Fullerton, CA). The supernatant was collected and analyzed for apoE.
Western blotting and quantitation of apoE levels. The supernatant (150 μg of protein) was subjected to SDS-PAGE and Western blotting. Human apoE3 and apoE4 were detected with antibody against full-length human apoE. Mouse wild-type apoE and Arg-61 apoE were detected with an antibody against recombinant, full-length wild-type mouse apoE. The protein bands were detected by chemiluminescence, using horseradish peroxidase-coupled anti-rabbit or anti-goat IgG as the secondary antibody. The blots were scanned, and the protein was quantitated by densitometry. The goat anti-human apoE antibody has equal affinity for apoE3 and apoE4 (Huang et al., 1998). The anti-mouse apoE antibody did not distinguish between the mouse isoforms (Fig. 1).
Extraction of CSF. Five-month-old heterozygous (Arg-61/wild-type apoE) mice were perfused with PBS for 7 min. The skull was exposed and punctured with a 30 gauge needle. CSF was slowly extracted using a 1 ml syringe connected to the needle (Raffaï et al., 2001).
Preparation of primary astrocyte-conditioned medium. Primary astrocytes from 3-d-old pups were grown to 80% confluence in medium containing DMEM and 20% fetal bovine serum in T75 flasks. The cells were washed three times with serum-free DMEM and incubated with 5 ml of serum-free DMEM containing B27 supplement (Invitrogen) for 72 h (Fagan et al., 1999). The conditioned medium was collected and dialyzed against 0.1 m ammonium bicarbonate for analysis of apoE levels by isoelectric focusing.
Isoelectric focusing. CSF and conditioned medium were lyophilized and delipidated in a mixture of chloroform and methanol (2:1, v/v). The delipidated samples were dried, resuspended in sample buffer (10% sucrose, 0.1% decyl sulfate, and 0.2 mm Tris, pH 9.0), and run on a 5% polyacrylamide gel containing 8 m urea and 200 mm ampholines, pH 3.5-6.5 (Amersham Biosciences). Mouse wild-type and Arg-61 apoE and human apoE3 and apoE4 were detected and quantitated as described above.
Extraction of RNA and reverse-transcription-real-time PCR. Total RNA from brain tissue and primary astrocytes was extracted with the RNeasy kit (Qiagen, Valencia, CA). Reverse transcription was performed with 300 ng of total RNA, oligo dT, random primers, and TaqMan reverse transcription reagents (Applied Biosystems, Foster City, CA) according to the manufacturer's instructions. PCR was performed in real time with 6 ng of cDNA and the ABI PRISM-7700 sequence detector (Applied Biosystems). Mouse wild-type and Arg-61 apoE were amplified with forward primer 5′-AAGCAACCAACCCTGGGAG-3′ and reverse primer 5′-TGCACCCAGCGCAGGTA-3′. The mouse 18s gene was used as an internal standard and amplified with forward primer 5′-AGGAATTGACGGAAGGGCAC-3′ and reverse primer 5′-GGACATCTAAGGGCATCACA-3′. Mouse apoE mRNA levels were calculated and normalized to 18s mRNA.
Statistical analysis. Values are reported as mean ± SEM. Statistical significance was determined with the t test.
Results
Lower brain levels of apoE4 than apoE3 in human knock-in mice
Levels of apoE3 and apoE4 in the brains from 5-month-old apoE3 and apoE4 knock-in mice were determined by Western blot analysis of brain homogenates (Fig. 2). Significant differences were observed between apoE3 and apoE4 levels (p < 0.01, n = 3). In the hemibrain, the apoE4 level was 28% lower than the apoE3 level. ApoE4 levels were 37% lower in the cortex, 36% lower in the cerebellum, and 26% lower in the hippocampus.
Lower brain levels of Arg-61 apoE than wild-type apoE
To determine whether domain interaction is responsible for the difference in apoE3 and apoE4 levels in the brains of human apoE knock-in mice, we analyzed tissue homogenates from hemibrains of 5-month-old wild-type and Arg-61 apoE mice. In female mice, the Arg-61 apoE level was 43% lower than the wild-type apoE level (Fig. 3) (p < 0.01; n = 6). Anaylsis of subregions showed that the Arg-61 apoE level was 33% lower in the cortex, 45% lower in the hippocampus, and 47% lower in the cerebellum (Fig. 3) (p < 0.01; n = 6). Similar differences were observed in 5-month-old male mice (data not shown).
Lower level of Arg-61 apoE is not age dependent or gender specific
To investigate the effect of age on apoE levels, we analyzed brain-tissue homogenates from embryonic day 18 (E18) embryos, 3-d-old pups, and 1- and 2-year-old mice. The Arg-61 apoE level was 39% lower than the wild-type level in the embryos and 49% lower in the 3-d-old pups (Table 1). Analysis of hemibrains showed that the Arg-61 apoE level was 44% lower in 1-year-old mice and 36% lower in 2-year-old mice (Fig. 4) (p < 0.01; n = 6). In both 1- and 2-year-old mice, the cortical, cerebellar, and hippocampal levels of Arg-61 apoE were ∼25-50% lower than those of wild-type apoE (data not shown).
To assess gender effects, we examined apoE levels in the brains of male and female mice at 5 months and 1 and 2 years of age. In all mice, the Arg-61 apoE levels were ∼25-50% lower than the levels of wild-type apoE (data not shown), indicating that there was no gender-specific effect.
These findings demonstrate that Arg-61 apoE levels are lower than wild-type apoE levels in the brains of E18 mouse embryos and remain lower up to 2 years of age.
Arg-61 apoE level is lower than wild-type apoE level in CSF
Next, the levels of wild-type and Arg-61 apoE in CSF from 5-month-old Arg-61/wild-type heterozygous mice were compared by isoelectric focusing. The Arg-61 apoE level was 40 ± 2.4% lower (Fig. 5) (p < 0.01; n = 5).
Lower level of Arg-61 apoE is not attributable to lower mRNA level
Next, we assessed the levels of Arg-61 and wild-type apoE mRNA in the hemibrain, cortex, hippocampus, and cerebellum from 5-month-old male and female mice. In both sexes, the levels of Arg-61 apoE mRNA were similar to or slightly higher than the levels of wild-type mRNA in the hemibrain, cortex, and hippocampus (Fig. 6). The Arg-61 and wild-type apoE mRNA levels were also similar in the cerebellum (data not shown).
Lower levels of Arg-61 apoE and apoE4 than wild-type apoE and apoE3 in conditioned medium from primary astrocyte cultures
Differential secretion of wild-type and Arg-61 apoE by astrocytes, the major producers of apoE in the brain (Boyles et al., 1985; Pitas et al., 1987), is a potential mechanism for the lower level of Arg-61 apoE. To evaluate this possibility, we compared the amount of Arg-61 and wild-type apoE in conditioned media from primary cultures of astrocytes obtained from 3-d-old Arg-61/wild-type heterozygous pups. The medium contained 45.7 ± 8.4% (p < 0.01; n = 3) less Arg-61 apoE than wild-type apoE (Fig. 7A). Further analysis showed no significant difference in the levels of Arg-61 and wild-type apoE mRNA (data not shown), demonstrating that the lower amount of Arg-61 apoE in conditioned medium was not attributable to a lower mRNA level. These results suggest that the primary astrocytes secrete less Arg-61 apoE than wild-type apoE.
We also compared the levels of human apoE3 and apoE4 in the conditioned medium from heterozygous apoE3/apoE4 primary astrocyte cultures obtained from 3-d-old pups. ApoE4 levels were ∼24.6 ± 3.2% (p < 0.01; n = 3) lower than apoE3 levels in the conditioned medium (Fig. 7B), suggesting that primary astrocytes secrete less apoE4 than apoE3. Together, these results indicate that domain interaction contributes to primary astrocytes secreting lower levels of human apoE4 and mouse Arg-61 apoE compared with apoE3 and mouse wild-type apoE, respectively.
Discussion
This study shows that, in the CNS, apoE4 is present at lower levels than apoE3 and Arg-61 apoE is present at lower levels than wild-type apoE. Lower levels of Arg-61 apoE were found in E18 embryos through 2 years of age. The lower levels of Arg-61 apoE were not as a result of decreased mRNA levels, suggesting a post-translational effect. Consistent with this possibility, conditioned medium from primary astrocytes contained less Arg-61 apoE and apoE4 than wild-type apoE and apoE3, respectively.
ApoE4 levels are also lower than apoE3 levels in human plasma, reflecting the more rapid turnover of apoE4 (Gregg et al., 1986). Because of domain interaction (Dong and Weisgraber, 1996), apoE4 binds preferentially to large, triglyceride-rich, very low density lipoproteins, which are more rapidly removed from plasma than other lipoprotein classes such as high-density lipoproteins, to which apoE3 binds preferentially (Gregg et al., 1986; Steinmetz et al., 1989; Weisgraber, 1990). The Arg-61 apoE mouse model reproduces these features of apoE4 in plasma and is therefore a model for apoE4 domain interaction. The lower plasma levels of Arg-61 apoE do not stem from reduced secretion because cultured primary hepatocytes, the major source of apoE in the plasma, from heterozygous Arg-61/wild-type mice secrete similar amounts of each mouse isoform (Raffaï et al., 2001).
Because large triglyceride-rich lipoproteins are not present in the CNS, the lower levels of Arg-61 apoE cannot be explained by a more rapid clearance through this mechanism. One potential mechanism is that the cellular quality control machinery recognizes Arg-61 apoE as a misfolded protein and targets it for degradation. This would reduce secretion of the mature protein. Fluorescence resonance energy transfer studies showed that apoE4 domain interaction occurs in living cells (Xu et al., 2004). Although the exact mechanism responsible for the lower levels of apoE4 and Arg-61 apoE in mouse brains is not entirely clear, our results demonstrate that domain interaction is a major contributing factor.
Our finding of the lower levels of apoE4 than of apoE3 in knock-in mice contradicts a previous report in which equal levels of the two proteins were shown (Sullivan et al., 2004). Similarly, we found lower levels of Arg-61 apoE than of wild-type apoE in CSF from heterozygous mice. In contrast, previous studies showed higher apoE4 levels in CSF from apoE3/apoE4 heterozygous humans (Fukumoto et al., 2003; Wahrle and Holtzman, 2003). These differences may reflect methodological differences of analysis (i.e., immunoassay versus Western blotting) and methods of extracting brain apoE.
The previous studies did not use detergents to extract brain apoE, likely leading to incomplete and variable efficiency of extraction. In addition, detergents were not included in the immunoassays, also likely leading to variable results on apoE levels. This is based on the fact that apoE is a lipid-binding protein and binds to membrane fragments, released lipids, and lipoproteins, making the extraction difficult in the absence of detergents. Even in soluble fractions, lipid binding can be problematic. This was recognized more than 20 years ago as immunoassays were being developed for quantitation of apoE in plasma. All successful apoE assays require a delipidation step using a variety of detergents (Lippel et al., 1983; Labeur et al., 1990; Krul and Cole, 1996). Epitopes on apoE3 and apoE4 can be masked to different degrees because each isoform has different preferences for lipids, making it difficult for the antibody to recognize the two proteins with equal intensity without detergent treatment. In addition, apoE tends to oligiomerize and stick to surfaces.
To avoid these problems, we used a mixture of detergents to extract apoE from the brain tissue and quantitated apoE under denaturing conditions (SDS) by Western blotting. The advantage of using detergents is that any lipid bound to apoE will be removed, making all of the epitopes on apoE equally available for recognition by the antibody. Using denaturing conditions prevents oligomerization. These strategies provide an accurate and quantitative method to determine total apoE levels in the brain. In addition, much of our data were obtained with Arg-61/wild-type and apoE4/apoE3 heterozygous mice, in which we could compare the levels of wild-type and Arg-61 apoE, and apoE3 and apoE4 in the same heterozygous mouse brain and the wild-type apoE and apoE3 served as internal controls to normalize the apoE protein level. This reduced the effect of variations between animals. Also, the possibility that the lower Arg-61 apoE level may be attributable to a specific effect of mouse apoE is ruled out because the Arg-61 apoE and the human apoE4 essentially behaved identically in the two mouse models that were examined. Lower levels of apoE4 than of apoE3 have been shown in AD brains (Bertrand et al., 1995; Beffert et al., 1999; Poirier, 2005). However, difficulty in controlling for the variation in protein level because of different stages of the disease and the low numbers of samples examined confound the interpretation.
The lower level of apoE4 than of apoE3 in the brain suggests new potential mechanisms by which apoE4 could contribute to AD. Although a gain of toxic function for apoE4 was demonstrated in transgenic mice producing apoE3 and apoE4 in neurons in a behavioral paradigm (Buttini et al., 1999), it is possible that apoE4 functions less effectively because it is present at lower levels with expression driven by endogenous promoters. In addition, the fraction of the apoE4, which is recognized as a misfolded protein, may be degraded into toxic fragments or accumulate as toxic aggregates. Emerging evidence indicates that apoE is expressed in neurons in response to stress (Bao et al., 1996; Metzger et al., 1996; Boschert et al., 1999; Xu et al., 1999; Harris et al., 2004), and apoE4 expressed in neurons is more susceptible than apoE3 to C-terminal cleavage, which results in the formation of cytotoxic fragments (Huang et al., 2001; Harris et al., 2003). This enhanced cleavage of apoE4 is mediated by domain interaction (Q. Xu and Y. Huang, unpublished observation). Cleavage of apoE leading to generation of these fragments in neurons in response to a stress to the brain may be an early event in the pathogenesis of AD (Huang et al., 2001; Harris et al., 2003; Brecht et al., 2004). Another possibility is that in astrocytes, domain interaction in apoE4 is recognized as a misfolded protein in the endoplasmic reticulum (ER) by the quality control machinery, activating an ER stress response pathway and targeting the protein for degradation. Alternatively, accumulation of apoE4 in the ER may lead to an ER overload response (Pahl and Baeuerle, 1997) and subsequent activation of nuclear factor κB (NF-κB), which could have a negative impact on normal astrocyte function because of a chronic inflammatory response. Interestingly, inflammation, NF-κB activation, and apoE have been recently connected (Ophir et al., 2005). All of these possibilities are not necessarily mutually exclusive.
In conclusion, our results demonstrate that domain interaction, which is one of the structural features distinguishing apoE4 from the other apoE isoforms, is responsible for lower levels of apoE4 in the brain. This finding emphasizes the importance of structural differences among apoE isoforms as likely contributing factors to the association of apoE4 with AD and other forms of neurodegeneration.
Footnotes
This work was supported in part by National Institutes of Health Grants AG20235, HL37063, and C06 RR018928. We thank Belinda Bituin and Walter Brecht for excellent technical assistance, Gui-Qiu Yu and Dr. Luke Esposito for advice on real-time PCR, John Carroll and Chris Goodfellow for graphics, Stephen Ordway and Gary Howard for editorial assistance, and Karina Fantillo for manuscript preparation.
Correspondence should be addressed to Dr. Karl H. Weisgraber, Gladstone Institute of Neurological Disease, 1650 Owens Street, San Francisco, CA 94158. E-mail: kweisgraber{at}gladstone.ucsf.edu.
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