Immunohistochemical detection of sphingosine-1-phosphate receptor 1 and 5 in human multiple sclerosis lesions.

AIMS: Sphingosine-1-phosphate receptor (S1PR) modulating therapies are currently in the clinic or undergoing investigation for multiple sclerosis (MS) treatment. However, the expression of S1PRs is still unclear in the central nervous system under normal conditions and during neuroinflammation. METHODS: Using immunohistochemistry we examined tissues from both grey and white matter MS lesions for sphingosine-1-phosphate receptor 1 (S1P1 ) and 5 (S1P5 ) expression. Tissues from Alzheimer's disease (AD) cases were also examined. RESULTS: S1P1 expression was restricted to astrocytes and endothelial cells in control tissues and a decrease in endothelial cell expression was found in white matter MS lesions. In grey matter MS lesions, astrocyte expression was lost in active lesions, while in quiescent lesions it was restored to normal expression levels. CNPase colocalization studies demonstrated S1P5 expression on myelin and both were reduced in demyelinated lesions. In AD tissues we found no difference in S1P1 expression. CONCLUSION: These data demonstrate a differential modulation of S1PRs in MS lesions, which may have an impact on S1PR-directed therapies.

A potent and selective S1P(1) antagonist with efficacy in experimental autoimmune encephalomyelitis.

Lymphocyte trafficking is critically regulated by the Sphingosine 1-phosphate receptor-1 (S1P(1)), a G protein-coupled receptor that has been highlighted as a promising therapeutic target in autoimmunity. Fingolimod (FTY720, Gilenya) is a S1P(1) receptor agonist that has recently been approved for the treatment of multiple sclerosis (MS). Here, we report the discovery of NIBR-0213, a potent and selective S1P(1) antagonist that induces long-lasting reduction of peripheral blood lymphocyte counts after oral dosing. NIBR-0213 showed comparable therapeutic efficacy to fingolimod in experimental autoimmune encephalomyelitis (EAE), a model of human MS. These data provide convincing evidence that S1P(1) antagonists are effective in EAE. In addition, the profile of NIBR-0213 makes it an attractive candidate to further study the consequences of S1P(1) receptor antagonism and to differentiate the effects from those of S1P(1) agonists.

The effect of FTY720 in the Theiler's virus model of multiple sclerosis.

FTY720 (fingolimod) has demonstrated efficacy in multiple sclerosis (MS). We evaluated the effects of FTY720 on progressive disability, viral load, and antibody responses in mice infected with Theiler's murine encephalomyocarditis virus (TMEV). FTY720 and phosphorylated FTY720 (FTY720-P) were detected in the brain after intraperitoneal injection of the drug. Bioactivity of FTY720 was confirmed by reduced numbers of mononuclear cells in the spleen and blood after treatment. No significant differences were found in disability progression, viral load, and serum antibody responses between the FTY720-treated versus the PBS-treated mice. There was less production of IgG within the CNS in the FTY-treated group on some measures.

Angiogenesis is present in experimental autoimmune encephalomyelitis and pro-angiogenic factors are increased in multiple sclerosis lesions.

BACKGROUND: Angiogenesis is a common finding in chronic inflammatory diseases; however, its role in multiple sclerosis (MS) is unclear. Central nervous system lesions from both MS and experimental autoimmune encephalomyelitis (EAE), the animal model of MS, contain T cells, macrophages and activated glia, which can produce pro-angiogenic factors. Previous EAE studies have demonstrated an increase in blood vessels, but differences between the different phases of disease have not been reported. Therefore we examined angiogenic promoting factors in MS and EAE lesions to determine if there were changes in blood vessel density at different stages of EAE. METHODS: In this series of experiments we used a combination of vascular casting, VEGF ELISA and immunohistochemistry to examine angiogenesis in experimental autoimmune encephalomyelitis (EAE). Using immunohistochemistry we also examined chronic active MS lesions for angiogenic factors. RESULTS: Vascular casting and histological examination of the spinal cord and brain of rats with EAE demonstrated that the density of patent blood vessels increased in the lumbar spinal cord during the relapse phase of the disease (p < 0.05). We found an increased expression of VEGF by inflammatory cells and a decrease in the recently described angiogenesis inhibitor meteorin. Examination of chronic active human MS tissues demonstrated glial expression of VEGF and glial and blood vessel expression of the pro-angiogenic receptor VEGFR2. There was a decreased expression of VEGFR1 in the lesions compared to normal white matter. CONCLUSIONS: These findings reveal that angiogenesis is intimately involved in the progression of EAE and may have a role in MS.

Complement C3 deficiency leads to accelerated amyloid beta plaque deposition and neurodegeneration and modulation of the microglia/macrophage phenotype in amyloid precursor protein transgenic mice.

Complement factor C3 is the central component of the complement system and a key inflammatory protein activated in Alzheimer's disease (AD). Previous studies demonstrated that inhibition of C3 by overexpression of soluble complement receptor-related protein y in an AD mouse model led to reduced microgliosis, increased amyloid beta (Abeta) plaque burden, and neurodegeneration. To further address the role of C3 in AD pathology, we generated a complement C3-deficient amyloid precursor protein (APP) transgenic AD mouse model (APP;C3(-/-)). Brains were analyzed at 8, 12, and 17 months of age by immunohistochemical and biochemical methods and compared with age-matched APP transgenic mice. At younger ages (8-12 months), no significant neuropathological differences were observed between the two transgenic lines. In contrast, at 17 months of age, APP;C3(-/-) mice showed significant changes of up to twofold increased total Abeta and fibrillar amyloid plaque burden in midfrontal cortex and hippocampus, which correlated with (1) significantly increased Tris-buffered saline (TBS)-insoluble Abeta(42) levels and reduced TBS-soluble Abeta(42) and Abeta(40) levels in brain homogenates, (2) a trend for increased Abeta levels in the plasma, (3) a significant loss of neuronal-specific nuclear protein-positive neurons in the hippocampus, and (4) differential activation of microglia toward a more alternative phenotype (e.g., significantly increased CD45-positive microglia, increased brain levels of interleukins 4 and 10, and reduced levels of CD68, F4/80, inducible nitric oxide synthase, and tumor necrosis factor). Our results suggest a beneficial role for complement C3 in plaque clearance and neuronal health as well as in modulation of the microglia phenotype.

Osteopetrotic (op/op) mice have reduced microglia, no Abeta deposition, and no changes in dopaminergic neurons.

BACKGROUND: Activation of microglia is a part of the inflammatory response in neurodegenerative diseases but its role in the pathophysiology of these diseases is still unclear. The osteopetrotic (op/op) mouse lacks colony-stimulating factor-1 (CSF-1) and thus has a deficiency in microglia and macrophages. Prior reports have demonstrated that op/op mice deposit amyloid beta (Abeta) plaques, similar to those found in Alzheimer's disease. The purpose of these studies was to confirm this and to determine if the lack of CSF-1 affects the development of dopaminergic neurons and the expression of CD200, a known microglial inhibitory protein. METHOD: We examined the central nervous system of op/op mice at 30 days, 60 days and 7 months of age and wildtype littermates at 30 days using immunohistochemistry and histochemistry. RESULTS: We found a decrease in the number of microglia in 1 month-old op/op mice compared to wildtype (WT) littermates as measured by CD11b, CD45, CD32/16, CD68, CD204 and F4/80 immunoreactivity. Abeta plaques were not detected, while the number of dopaminergic neurons appeared normal. The expression of CD200 appeared to be normal, but there appeared to be a lower expression in the substantia nigra. CONCLUSION: In contrast to a prior report we did not detect Abeta deposition in the central nervous system of op/op mice at 30 days, 60 days or 7 months of age and there was a normal number of dopaminergic neurons. This indicates that op/op mice may be useful to examine the effects of microglia on neurodegenerative disease progression by breeding them to different transgenic mouse models. In addition, the lack of CSF-1 does not appear to affect CD200 expression by neurons but we did note a decrease in the substantia nigra of op/op and WT mice, suggesting that this may be a mechanism by which microglia control may be attenuated in this specific area during Parkinson's disease.

Novel Abeta immunogens: is shorter better?

Active and passive Abeta immunotherapy in Alzheimer's disease (AD)-like mouse models lowers cerebral amyloid-beta protein (Abeta) levels, especially if given early in the disease process, and improves cognitive deficits. In 2002, a Phase IIa clinical trial was halted due to meningoencephalitis in approximately 6% of the AD patients. It is hypothesized that the immunogen, full-length Abeta1-42, may have led to an autoimmune response. Currently, we are developing novel Abeta peptide immunogens for active immunization in amyloid precursor protein transgenic mice (APP Tg) to target Abeta B cell epitopes (within Abeta1-15) and avoid Abeta-specific T cell epitopes (Abeta16-42) so as to generate a safe and effective AD vaccine. Intranasal immunization with dendrimeric Abeta1-15 (16 copies of Abeta1-15 on a lysine core) or a tandem repeat of Abeta1-15 joined by 2 lysines and conjugated to an RGD motif with a mutated form of an E. coli-derived adjuvant generated robust Abeta titers in both wildtype and APP Tg mice. The Abeta antibodies recognized a B cell epitope within Abeta1-7, were mostly T-helper 2 associated immunoglobulin isotypes, bound human AD and APP Tg plaques, and detected Abeta oligomers. Splenic T cells reacted to the immunogens but not full-length Abeta. Six months of intranasal immunization (from 6-to-12 months of age) of J20 mice with each immunogen lowered insoluble Abeta42 by 50%, reduced plaque burden and gliosis, and increased Abeta in plasma. Interestingly, Abeta antibody generation was influenced by route of immunization. Transcutaneous immunization with dbeta1-15, but not full-length Abeta, led to high Abeta titers. In summary, our short Abeta immunogens induced robust titers of predominantly Th2 antibodies that were able to clear cerebral Abeta in the absence of Abeta-specific T cell reactivity, indicating the potential for a safer vaccine. We remain optimistic about the potential of such a vaccine for prevention and treatment of AD.

Dendrimeric Abeta1-15 is an effective immunogen in wildtype and APP-tg mice.

Immunization of humans and APP-tg mice with full-length beta-amyloid (Abeta) results in reduced cerebral Abeta levels. However, due to adverse events in the AN1792 trial, alternative vaccines are required. We investigated dendrimeric Abeta1-15 (dAbeta1-15), which is composed of 16 copies of Abeta1-15 peptide on a branched lysine core and thus, includes an Abeta-specific B cell epitope but lacks the reported T cell epitope. Immunization by subcutaneous, transcutaneous, and intranasal routes of B6D2F1 wildtype mice led to anti-Abeta antibody production. Antibody isotypes were mainly IgG1 for subcutaneous or transcutaneous immunization and IgG2b for intranasal immunization, suggestive of a Th2-biased response. All Abeta antibodies preferentially recognized an epitope in Abeta1-7. Intranasal immunization of J20 APP-tg mice resulted in a robust humoral immune response with a corresponding significant reduction in cerebral plaque burden. Splenocyte proliferation against Abeta peptide was minimal indicating the lack of an Abeta-specific cellular immune response. Anti-Abeta antibodies bound monomeric, oligomeric, and fibrillar Abeta. Our data suggest that dAbeta1-15 may be an effective and potentially safer immunogen for Alzheimer's disease (AD) vaccination.

Boosting with intranasal dendrimeric Abeta1-15 but not Abeta1-15 peptide leads to an effective immune response following a single injection of Abeta1-40/42 in APP-tg mice.

BACKGROUND: Immunotherapy for Alzheimer's disease (AD) is emerging as a potential treatment. However, a clinical trial (AN1792) was halted after adverse effects occurred in a small subset of subjects, which may have been caused by a T cell-mediated immunological response. In general, aging limits the humoral immune response, therefore, immunogens and vaccination regimes are required that induce a strong antibody response with less potential for an adverse immune response. METHOD: In the current study, we immunized both wildtype and J20 APP-tg mice with a priming injection of Abeta1-40/42, followed by multiple intranasal boosts with the novel immunogen dAbeta1-15 (16 copies of Abeta1-15 on a lysine tree), Abeta1-15 peptide or Abeta1-40/42 full length peptide. RESULTS: J20 APP-tg mice primed with Abeta1-40/42 subcutaneously and subsequently boosted intranasally with Abeta1-15 peptide did not generate a cellular or humoral immune response. In contrast, J20 APP-tg mice boosted intranasally with dAbeta1-15 or full length Abeta1-40/42 produced high levels of anti-Abeta antibodies. Splenocyte proliferation was minimal in mice immunized with dAbeta1-15. Wildtype littermates of the J20 APP-tg mice produced higher amounts of anti-Abeta antibodies compared to APP-tg mice but also had low T cell proliferation. The anti-Abeta antibodies were mainly composed of IgG2b and directed to an epitope within the Abeta1-7 region, regardless of the immunogen. Examination of the brain showed a significant reduction in Abeta plaque burden in the J20 APP-tg mice producing antibodies compared to controls. Biochemically, Abeta40 or Abeta42 were also reduced in brain homogenates and elevated in plasma but the changes did not reach significance. CONCLUSION: Our results demonstrate that priming with full length Abeta40/42 followed by boosting with dAbeta1-15 but not Abeta1-15 peptide led to a robust humoral immune response with a minimal T cell response in J20 APP-tg mice. In addition, Abeta plaque burden was reduced in mice producing anti-Abeta antibodies. Interestingly, wildtype mice produced higher levels of anti-Abeta antibodies, indicating that immune tolerance may be present in J20 APP-tg mice. Together, these data suggest that dAbeta1-15 but not Abeta1-15 peptide may be useful as a boosting immunogen in an AD vaccination regime.

Short amyloid-beta (Abeta) immunogens reduce cerebral Abeta load and learning deficits in an Alzheimer's disease mouse model in the absence of an Abeta-specific cellular immune response.

Amyloid-beta (Abeta) immunotherapy lowers cerebral Abeta and improves cognition in mouse models of Alzheimer's disease (AD). A clinical trial using active immunization with Abeta1-42 was suspended after approximately 6% of patients developed meningoencephalitis, possibly because of a T-cell reaction against Abeta. Nevertheless, beneficial effects were reported in antibody responders. Consequently, alternatives are required for a safer vaccine. The Abeta1-15 sequence contains the antibody epitope(s) but lacks the T-cell reactive sites of full-length Abeta1-42. Therefore, we tested four alternative peptide immunogens encompassing either a tandem repeat of two lysine-linked Abeta1-15 sequences (2xAbeta1-15) or the Abeta1-15 sequence synthesized to a cross-species active T1 T-helper-cell epitope (T1-Abeta1-15) and each with the addition of a three-amino-acid RGD (Arg-Gly-Asp) motif (R-2xAbeta1-15; T1-R-Abeta1-15). High anti-Abeta antibody titers were observed in wild-type mice after intranasal immunization with R-2xAbeta1-15 or 2xAbeta1-15 plus mutant Escherichia coli heat-labile enterotoxin LT(R192G) adjuvant. Moderate antibody levels were induced after immunization with T1-R-Abeta1-15 or T1-Abeta1-15 plus LT(R192G). Restimulation of splenocytes with the corresponding immunogens resulted in moderate proliferative responses, whereas proliferation was absent after restimulation with full-length Abeta or Abeta1-15. Immunization of human amyloid precursor protein, familial AD (hAPP(FAD)) mice with R-2xAbeta1-15 or 2xAbeta1-15 resulted in high anti-Abeta titers of noninflammatory T-helper 2 isotypes (IgG1 and IgG2b), a lack of splenocyte proliferation against full-length Abeta, significantly reduced Abeta plaque load, and lower cerebral Abeta levels. In addition, 2xAbeta1-15-immunized hAPP(FAD) animals showed improved acquisition of memory compared with vehicle controls in a reference-memory Morris water-maze behavior test that approximately correlated with anti-Abeta titers. Thus, our novel immunogens show promise for future AD vaccines.

Amyloid-beta immunotherapy for the prevention and treatment of Alzheimer disease: lessons from mice, monkeys, and humans.

Alzheimer disease (AD), the most common form of dementia, is without an effective cure or preventive treatment. Recently, amyloid-beta protein (Abeta) has become a major therapeutic target. Many efforts are underway to either reduce the production of Abeta or enhance its clearance. In 1999, Schenk and colleagues first showed that active immunization with full-length Abeta lowered cerebral Abeta levels in transgenic mice. These findings have been confirmed and extended in various transgenic mouse models of AD using both active and passive Abeta immunization. Cognitive improvement also has been reported in association with active and passive Abeta vaccination in AD-like mouse models, even in the absence of significant reductions in cerebral Abeta loads. In 2004, the authors reported that active immunization with full-length Abeta in aged nonhuman primates, Caribbean vervets, reduced cerebral Abeta levels and gliosis. Proposed mechanisms of Abeta clearance by immunotherapy include disruption of Abeta aggregates, Abeta phagocytosis by microglia, neutralization of Abeta oligomers at the synapse, and increased efflux of Abeta from brain to blood. A phase IIa clinical trial was halted in 2002 because of the appearance of meningoencephalitis in approximately 6% of the AD patients. Although the exact cause of these adverse events is unknown, the immunogen, full-length Abeta1-42, may have been recognized as a self-antigen leading to an autoimmune response in some patients. Limited cognitive stabilization and apparent plaque clearance have been reported in subsets of patients who generated antibody titers. Currently, a passive immunization trial with a recombinant humanized monoclonal Abeta antibody is underway in humans. In the meantime, the authors are developing novel Abeta peptide immunogens for active immunization to target Abeta B cell epitope(s) and avoid Abeta-specific T-cell reactions in order to generate a safe and effective AD vaccine. The authors remain optimistic about the potential of such a vaccine for the prevention and treatment of AD.

Minocycline affects microglia activation, Abeta deposition, and behavior in APP-tg mice.

Activated microglia and reactive astrocytes invade and surround cerebral beta amyloid (Abeta) plaques in Alzheimer's disease (AD), but the role of microglia in plaque development is still unclear. In this study, minocycline was administered for 3 months, prior to and early in Abeta plaque formation in amyloid precursor protein transgenic mice (APP-tg). When minocycline was given to younger mice, there was a small but significant increase in Abeta deposition in the hippocampus, concurrent with improved cognitive performance relative to vehicle treated mice. If APP-tg mice received minocycline after Abeta deposition had begun, microglial activation was suppressed but this did not affect Abeta deposition or improve cognitive performance. In vitro studies demonstrated that minocycline suppressed microglial production of IL-1beta, IL-6, TNF, and NGF. Thus, minocycline has different effects on Abeta plaque deposition and microglia activation depending on the age of administration. Our data suggest that this may be due to the effects of minocycline on microglial function. Therefore, anti-inflammatory therapies to suppress microglial activation or function may reduce cytokine production but enhance Abeta plaque formation early in AD.

Modulation of the humoral and cellular immune response in Abeta immunotherapy by the adjuvants monophosphoryl lipid A (MPL), cholera toxin B subunit (CTB) and E. coli enterotoxin LT(R192G).

Abeta vaccination or passive transfer of human-specific anti-Abeta antibodies are approaches under investigation to prevent and/or treat Alzheimer's disease (AD). Successful active Abeta vaccination requires a strong and safe adjuvant to induce anti-Abeta antibody formation. We compared the adjuvants monophosphoryl lipid A (MPL)/trehalose dicorynomycolate (TDM), cholera toxin B subunit (CTB) and Escherichia coli heat-labile enterotoxin LT(R192G) for their ability to induce a humoral and cellular immune reaction, using fibrillar Abeta1-40/42 as a common immunogen in wildtype B6D2F1 mice. Subcutaneous (s.c.) administration with MPL/TDM resulted in anti-Abeta antibodies levels up to four times higher compared to s.c. LT(R192G). Using MPL/TDM, the anti-Abeta antibodies induced were mainly IgG2b, IgG1 and lower levels of IgG2a and IgM, with a moderate splenocyte proliferation and IFN-gamma production in vitro upon stimulation with Abeta1-40/42. LT(R192G), previously shown by us to induce robust titers of anti-Abeta antibodies, generated predominantly IgG2b and IgG1 anti-Abeta antibodies with very low splenocyte proliferation and IFN-gamma production. Weekly intranasal (i.n.) administration over 11 weeks of Abeta40/42 with CTB induced only moderate levels of antibodies. All immunogens generated antibodies that recognized mainly the Abeta1-7 epitope and specifically detected amyloid plaques on AD brain sections. In conclusion, MPL/TDM, in addition to LT(R192G), is an effective adjuvant when combined with Abeta40/42 and may aid in the design of Abeta immunotherapy.

Developing novel immunogens for an effective, safe Alzheimer's disease vaccine.

Active amyloid beta (A beta) vaccination has been shown to be effective in clearing cerebral A beta and improving cognitive function in mouse models of Alzheimer's disease. However, an A beta vaccine clinical trial was suspended after meningoencephalitis was detected in a subset of subjects. Passive immunization has been suggested to be a safer alternative to active A beta immunization but there are reports of increased risk of microhemorrhages associated with its administration in aged beta-amyloid precursor protein transgenic mice bearing abundant vascular amyloid deposition. In addition, the cost may be prohibitive for large-scale clinical use. Therefore, we are designing novel A beta immunogens that encompass the B cell epitope of A beta but lack the T cell-reactive sites. These immunogens induced the production of A beta-specific antibodies in the absence of an A beta-specific cellular immune response in wild-type mice and are being tested in beta-amyloid precursor protein transgenic mice. These data together with published reports from several other groups suggest that a safe, active A beta vaccine is a tenable goal.

Differences in the immune response to long term Abeta vaccination in C57BL/6 and B6D2F1 mice.

The cerebral accumulation of beta-amyloid (Abeta) is a pathological hallmark of Alzheimer's disease (AD). Abeta vaccination or anti-Abeta specific antibodies may be a possible therapeutic option for AD. Previously, we demonstrated variation in the humoral response between B6D2F1 and C57BL/6 during short term (14 weeks) Abeta immunization. In the present study, we determined the humoral and cellular immune responses in these same mouse strains to a longer period of Abeta vaccination and further refined the major B cell epitope to Ass1-7. B6D2F1 mice generated a greater humoral and Th1 immune response versus C57BL/6 mice. Immunization with 25 microg Abeta produced a greater T cell response in B6D2F1 mice compared to 50 or 100 microg Abeta but resulted in comparable humoral immunity. Thus, Abeta vaccination is affected by the genetic background and amount of Abeta peptide used as immunogen. These data may help explain some differences observed in Abeta immunization studies in mice of various genetic backgrounds and aid in the design of Abeta vaccines.

Species-specific immune response to immunization with human versus rodent A beta peptide.

Amyloid beta (A beta) immunization of amyloid precursor protein (APP)-transgenic (tg) mice with human A beta induces humoral immunity, however, the immune response to endogenous rodent A beta is unknown. Fourteen-month J20 APP-tg mice and non-tg littermates were immunized subcutaneously followed by chronic intranasal boosting with human or rodent A beta peptide and adjuvant LT(R192G). Rodent A beta-immunized APP-tg mice had anti-rodent A beta antibody levels of 257.8 micrograms/ml and those immunized with human A beta had anti-human A beta antibodies of 120.8 micrograms/ml. Non-tg littermates had anti-rodent and anti-human A beta antibody concentrations of 98.8 and 231.1 microgram/ml, respectively. Inter-species cross-reactivity was minimal. Anti-human A beta antibodies were predominately IgG1 and IgG2b, while anti-rodent A beta antibodies were equally IgG1, IgG2a, and IgG2b. Anti-human A beta antibodies recognized an epitope within human A beta1-9. Anti-rodent A beta antibodies did not stain Alzheimer's disease (AD) plaques but bound some plaques in APP-tg mice. Splenocytes proliferated modestly to their respective antigen and secreted low levels of IL-2 and IFN-gamma. Therefore, immunizing APP-tg and non-tg mice with rodent A beta resulted in a species-specific humoral response with modest T cell reactivity.

Alzheimer's disease abeta vaccine reduces central nervous system abeta levels in a non-human primate, the Caribbean vervet.

Amyloid beta (Abeta) protein immunotherapy lowers cerebral Abeta and improves cognition in mouse models of Alzheimer's disease (AD). Here we show that Caribbean vervet monkeys (Chlorocebus aethiops, SK) develop cerebral Abeta plaques with aging and that these deposits are associated with gliosis and neuritic dystrophy. Five aged vervets were immunized with Abeta peptide over 10 months. Plasma and cerebral spinal fluid (CSF) samples were collected periodically from the immunized vervets and five aged controls; one monkey per group expired during the study. By Day 42, immunized animals generated plasma Abeta antibodies that labeled Abeta plaques in human, AD transgenic mouse and vervet brains; bound Abeta1-7; and recognized monomeric and oligomeric Abeta but not full-length amyloid precursor protein nor its C-terminal fragments. Low anti-Abeta titers were detected in CSF. Abetax-40 levels were elevated approximately 2- to 5-fold in plasma and decreased up to 64% in CSF in immunized vervets. Insoluble Abetax-42 was decreased by 66% in brain homogenates of the four immunized animals compared to archival tissues from 13 age-matched control vervets. Abeta42-immunoreactive plaques were detected in frontal cortex in 11 of the 13 control animals, but not in six brain regions examined in each of the four immunized vervets. No T cell response or inflammation was observed. Our study is the first to demonstrate age-related Abeta deposition in the vervet monkey as well as the lowering of cerebral Abeta by Abeta vaccination in a non-human primate. The findings further support Abeta immunotherapy as a potential prevention and treatment of AD.

Amyloid-beta immunization in Alzheimer's disease transgenic mouse models and wildtype mice.

Alzheimer's disease is the most prevalent form of dementia worldwide. Therapies are desperately needed to prevent and cure the disease. Mouse models of amyloid-beta deposition [APP and PSAPP transgenic (tg) mice] have been useful in determining the role of amyloid-beta (A beta) in both the pathogenesis and cognitive changes in AD. In addition, they have allowed scientists to investigate potential AD therapies in living animals. Active and passive A beta immunizations have been employed successfully in APP and PSAPP tg mice to lower cerebral A beta levels and improve cognition. Optimization of immunization protocols and characterization of immune responses in wildtype mice have been reported. Based on the promising results of A beta immunization studies in mice, a clinical trial was initiated for A beta vaccination in humans with AD. Although no adverse effects were reported in the Phase I safety trials, about 5% of AD patients in the phase II clinical trial developed meningoencephalitis, ending the trial prematurely in March 2002. Studies in AD mouse models and wildtype mice may help elucidate the mechanism for these unwanted side effects and will be useful for testing newer, safer vaccines for future use in human clinical trials.