The neuropathological features of Alzheimer's disease (AD) include neurofibrillary tangles (NFT), deposition of amyloid-β (Aβ) in senile plaques, and neuronal loss in affected brain regions 1. The Aβ is cleaved from the amyloid precursor protein (APP) by the β- and γ-secretases 234, and is believed to play an important role in the onset and progression of AD 56. Accordingly, many of the strategies currently being proposed as therapies for AD are aimed at reducing the level of Aβ in the brain, and/or preventing the assembly of this peptide into pathological forms. One potentially powerful strategy for reducing the level of Aβ in the brain is immunotherapy, in which antibodies specific for Aβ facilitate the clearance amyloid deposits and a reduction in other forms Aβ in the brain parenchyma. Both active and passive Aβ-immunotherapy significantly decrease amyloid deposits, neuritic dystrophy and gliosis in the brain, as well as improve behavioural measures in APP/Tg mice 789101112. Based on these and other studies in several animal models, the AN-1792 clinical trial was initiated in patients with mild-to-moderate AD, however the trial was halted during the phase II portion of the trial when approximately 6% of the AD patients vaccinated with AN1792 developed meningoencephalitis and in some cases CAA associated haemorrhages. The cause of the encephalitis in these patients has not yet been determined, however speculation has focused on autoreactive T-cells and the proinflammatory Th1 type of adjuvant that was used in the clinical trial 13141516. Of note, there is only one unconfirmed report about lymphocyte infiltration detected in the brains of wildtype mice immunized with Aβ₄₂ formulated in FCA/FIA followed by injection with pertussis toxin 17. In addition to T cell infiltration into the brain parenchyma, another participant in the clinical trial developed widespread cortical hemorrhages 16. Microhemorrhages in the cerebral vasculature have also been observed in different strains of very old (21–26 month-old) APP/Tg mice injected weekly with high doses of anti-Aβ monoclonal antibodies, and the sites of microhemorrhage have been co-localized with cerebral vascular Aβ deposits 18192021. Recently, it was reported that active immunizations of APP/Tg mice with fibrillar Aβ₄₂ formulated in a strong conventional adjuvant, Freund's complete adjuvant system (FCA), could also increase microhemorrhages in the brains of vaccinated animals 22. Collectively, these adverse events emphasized the need for further refinement of vaccines for AD in order to eliminate, or at least attenuate, the potential adverse events initiated by infiltration of autoreactive T cells and peripheral macrophages, as well as inflammation-induced cerebral vascular microhemorrhages.

Mannan and other polysaccharides are recognized by collectins, such as, Mannose-Binding Lectin (MBL) 232425, as well as Mannose Binding Receptors (MBRs) expressed on dendritic cells, some endothelial cells and macrophages 26272829. After binding to mannan, MBL initiates the complement pathway via an activation of the MASP-1 & MASP-2 proteases, and is antibody- and C1q-independent. Therefore, immunization of mice with Aβ peptide sequences conjugated to mannan should induce complement activation and C3d opsonization on the Aβ. Moreover, MBL, which also has opsonic function like complement C1q (homologue of MBL), binds to complement receptor type 1 (CR1/CD35) 30 and therefore stimulates phagocytosis of the conjugated antigen. Finally, T-cell dependent B-cell immune responses can be activated not only by simultaneous triggering of BCR and C' receptor type 2 (CD21), but also by simultaneous triggering of BCR and C' receptor type 1 (CD35) 3132. Importantly, different groups have already demonstrated enhancement of T-helper and B-cell immune responses against several mannosylated-antigens, including peptide-antigens 333435. In addition to the direct activation of C', Aβ-mannan conjugates will be recognized by MBRs found on dendritic cells, some endothelial cells and macrophages 262728. The macrophage mannose receptor (MMR) and DEC-205 found on dendritic and some endothelial cells bind multiple carbohydrates 36. These receptors significantly enhance phagocytosis of antigens containing an appropriate carbohydrate, such as mannose residues. In addition, the receptors can also increase antigen presentation on macrophages and dendritic cells by 100- to 1,000-fold over antigens without carbohydrate residues. Thus, besides activating complement, Aβ conjugated to mannan will also promote phagocytosis and antigen presentation on macrophages and dendritic cells of the immune system, providing an added benefit from the conjugation of mannan to Aβ. Notably, under certain conditions, mannosylated antigens induced strong Th2-type anti-inflammatory responses (production of IL4/IL10 cytokines) with high levels of IgG1 antibodies 33343738.

Previously, we generated mannan-Aβ₂₈ conjugate and demonstrated that immunization of wild-type mice with this vaccine enhanced the production of IL4 (Th2-type) cytokine followed by generation of antibodies specific to the self-Aβ antigen 39. Here for the first time we tested the safety and efficacy of mannan-Aβ₂₈ conjugate in Tg2576 mouse model of AD. We demonstrated that, in the absence of any conventional adjuvant, mannan-Aβ₂₈ conjugate enhanced the production of Th2-type anti-Aβ antibodies inhibiting Aβ plaque formation. However, the mannan-peptide conjugate induced higher levels of microhemorrhages compared to that in the brains of age-matched control animals.

Anti-Aβ immunotherapy is one strategy for the inhibition/reduction of soluble and insoluble amyloid-β deposits that likely play a causal role in the onset and progression of AD 56. Several pre-clinical studies with mouse models of AD have demonstrated the ability of Aβ vaccination to prevent amyloid deposition in the brain. Thus, active immunization with Aβ 763, as well as passive immunization intraperitoneally 11, or direct to the brain application of anti-Aβ antibodies64, resulted in reduction of the amyloid burden in the brain. Importantly, active immunizations prevented cognitive decline 89, and passive immunizations were shown to reverse the memory loss in aged Tg2576 mice 65. While these and other studies did not report any adverse events in AD mouse models immunized with fibrillar Aβ₄₂, data from the AN-1792 vaccine trial suggest that the adverse reactions to Aβ₄₂-immunotherapy were not due to the humoral antibody response, but rather to the cell-mediated autoimmune response, possibly exacerbated by the reformulation of adjuvant, QS21 supplemented with polysorbate-80, which induced a Th1 type immune response in patients that received the AN1792 vaccine 131415166366676869. Thus, the goal of this pre-clinical study was to employ a molecular adjuvant, mannan, that induces a Th2-type humoral immune response specific to Aβ peptide, and test the efficacy of vaccination on AD-like pathology in aged Tg2576 mice.

Previously, mannan was shown to enhance both humoral and cellular immunity against various immunogens conjugated to mannan. Multiple mechanisms likely contribute to the adjuvant properties of mannan conjugates, including activation of complement, enhancing uptake and presentation of the conjugated antigen, as well as by providing a stronger signal to antigen-specific B cells by simultaneous triggering of B-cell receptors and CD21/CD35 molecules 2627283132333435707172737475. Notably, under certain conditions mannan was shown to induce predominantly Th2 polarized anti-inflammatory immune responses to a conjugated non-self peptides 33343738, a response which would presumably be beneficial to an anti-Aβ vaccine. We previously reported that Aβ₄₂ possesses B and T cell antigenic epitopes, both of which are contained within the Aβ₂₈ peptide in mice 44. In addition, our previous studies in wild-type mice using mannan conjugated to Aβ₂₈ peptide was able to induce potent and highly polarized Th2 phenotype anti-Aβ antibody responses 39. In the current study, we immunized anti-Aβ hyporesponsive Tg2576 mice with mannan-Aβ₂₈ conjugate prior to the onset of amyloid plaque pathology in the brains of Tg2576 mice 4376. Mice were immunized six times with low doses (10 μg per mouse) of mannan-Aβ₂₈ conjugate and the titer of anti-Aβ antibodies were assessed by ELISA. The antibodies induced by the mannan-Aβ₂₈ conjugate were predominantly of the IgG1 isotype and elevated titers were maintained for 11 months without further immunizations (Figure 1A, B). Thus, we demonstrated that our mannan-Aβ₂₈ immunoconjugate induced long-lasting and Th2-polarized anti-Aβ humoral immune responses in Tg2576 mice in the absence of a conventional adjuvant, such as alum or CFA. The humoral immune response induced by mannan-Aβ₂₈ was similar to that reported after multiple injections of 5 to 10 times higher doses of fibrillar Aβ₄₂ formulated in strong Th1 or Th2 conventional adjuvants 7844777879.

We examined the effect of mannan-Aβ₂₈ vaccination on the neuropathology in 18–18.5 months old mice, and showed a significant reduction in both the Aβ₄₀ and Aβ₄₂ burden, as well as in the number of ThS positive cored plaques in the parietal cortical and hippocampal regions (Figure 2) of the brains from mice immunized 11 months earlier. Of note, previously we demonstrated that Aβ load was significantly reduced in the brains of Tg2576 mice with a high concentration of serum anti-Aβ_1–11 antibody (>50 μg/ml), whereas moderate concentration (5–50 μg/ml) of this antibody resulted in a trend toward a reduction in Aβ deposits, however it did not reach significance 49. In the current study antibody specific to Aβ₂₈ even at a moderate concentration (Figure 1A) significantly reduced both Aβ₄₀ and Aβ₄₂ deposits. This difference in potency of anti-Aβ antibody may be due not only to the different antigen configurations, but also to the starting point of immunization. More specifically, immunization with mannan-Aβ₂₈ was started in mice without pre-existing pathology (preventive vaccination strategy), whereas in previous study 49 immunization was initiated in mice with established AD-like pathology (therapeutic vaccination strategy). Of note, we did not detect any CD3-positive T cells in the brains of mice immunized with mannan-Aβ₂₈ (data not shown). Thus, inhibiting Aβ deposition in immunized Tg2576 mice was not associated with any adverse events, except for the increase in microhemorrhages.

The first two case reports from the AN-1792 clinical trial both reported meningoencephalitis with lymphocyte infiltration in the brain 1516. Additionally, the third case report demonstrated increased CAA without clinical presentation of meningoencephalitis, however there was noticeable perivascular T cell infiltration 14. It is worth mentioning, that a high degree of CAA typically indicates that hemorrhages are present in the brain 8081. However, only the case report from an AD patient from the Barcelona cohort of the AN-1792 trial found fully developed hemorrhages 16. The data on anti-Aβ immunotherapy in experimental mouse models of AD are somewhat different. Normally, rodents do not develop Aβ-CAA, except several APP transgenic mice models, including aged Tg2576 mice developing vascular amyloid in addition to the significant parenchymal amyloid 8283. Importantly, several studies with aged APP/Tg mice reported cerebral vascular microhemorrhages after passive transfer of high doses of anti-Aβ antibodies 182084. Additionally, it was shown that 3D6 antibody specific to N-terminal region of amyloid, but not antibody against Aβ_16–23 (266) prevented or cleared vascular Aβ in a dose-dependent manner, but high concentration of this antibody was associated with microhemorrhages in focal perivascular sites 62. Recently, it was reported that active immunizations with a high dose of fibrillar Aβ₄₂ plus CFA/IFA also increased microhemorrhage in aged APP/Tg mice 22. However, only one study reported meningoencephalitis in an APP/Tg mouse model passively immunized with repeated injections of high doses of monoclonal anti-Aβ antibodies (1 mg within 16 days). Although only 1 out of 21 experimental mice were affected, the authors nonetheless suggested that an inflammatory mechanism might be triggered by antibody binding to cerebral CAA, which in turn may enhance activation of autoreactive T cells, or lead to local disruption of the BBB 85. Accordingly, in the current study we sought to investigate whether immunization with a mannan-Aβ₂₈ conjugate might induce infiltration of T cells or increase the incidence of microhemorrhages, and CAA. While an examination of the brains did not reveal meningoencephalitis induced by the presence of T lymphocytes (data not shown), we observed an increased incidence and the severity of microhemorrhages in Tg2576 mice vaccinated with mannan-Aβ₂₈ (Figure 4). CAA-associated microhemorrhage in aged APP/Tg mice, was ameliorated with deglycosylation of antibodies used for passive immunization 21, implicating the potential harmful effect of mannan as the trigger of adverse vascular events. Thus, we attempted to demonstrate CAA-associated microhemorrhages in vaccinated animals with anti-Aβ antibodies. We have started with examination the meningeal and cortical vascular Aβ burden, because similar to human vascular Aβ, in mice it is first detectable within leptomeninges, followed mostly by cortical, hippocampal and thalamic areas 8687. By 12 months of age, Aβ deposits in Tg2576 mice are present in the walls of leptomeningeal and cortical blood vessels, and at 15 months, the percentage load of Aβ-CAA in these areas is about 1.46% 88. As mice in our study approached 18 mo of age, the CAA score in neocortex appeared to be similar in all groups of experimental and control mice (Figure 5D). Of note, in this study we had not quantified the difference in the leptomeninges of experimental animals precisely, due to non-applicability of the standard percentage area measurements of Aβ made in parenchyma and normalized to brain region to the measurements of the meningeal location of vascular Aβ deposits.

Although the perivascular macrophages express high levels of mannose receptors 29, it is unlikely that mannan fused with Aβ₂₈ could cross the BBB and activate these cells. Of note, infiltration of perivascular macrophages has been detected predominantly in gray matter, with the corpus callosum having very few cells, although substantial microhemorrhages in our study were detected among other areas, both in gray matter and in corpus callosum. In addition, immunization with mannan-BSA did not elevate the level of hemorrhages compared with low profiles observed in non-immunized mice (Figure 4).

Notably, titers of the anti-mannan antibodies in mannan-BSA group were higher than that in mice vaccinated with mannan-Aβ₂₈ (Figure 1C). Although these data indicate that anti-mannan antibodies did not contribute directly to the adverse cerebral vascular events, it is possible that they may contribute to an increase in BBB permeability, thereby increasing access of anti-Aβ antibody to perivascular and parenchymal spaces in mice vaccinated with mannan-Aβ₂₈. Importantly, we previously demonstrated that mannan-Aβ₂₈ or Aβ₂₈ alone did not induce microhemorrhage in the brains of wild-type mice 39.

Thus, we hypothesize that a potential cause for the incidences of microhemorrhage detected in Tg2576 mice immunized with mannan-Aβ₂₈ may be anti-Aβ antibody binding to Aβ in cerebral vasculature. If so, one potential culprit in the microhemorrhage may be the activation of the complement cascade by antibody-Aβ immune complexes at sites of CAA 8990. Our data demonstrating that C1q and C3b are found in the cortical brain sections of mice immunized with mannan-Aβ₂₈, but not control animals (Figure 6A) indicate that binding of antibody-Aβ to Aβ deposits in the cerebral vasculature may in fact induce microhemorrhages. Of note, we demonstrated that the level of decoration of ThS-stained vascular fibrillar Aβ with complement components C1q (Figure 6B) and C3b (data not shown) was highest in the meninges of mice immunized with mannan-Aβ₂₈. In this group, β-amyloid deposits had altered morphology suggestive of ongoing clearance, and were heavily decorated with C1q component of complement. On the contrary, very small or practically absent C1q profiles were co-localized with substantial and unaltered Aβ load of the meninges of BSA-mannan-immunized or non-immunized groups, respectively (Figure 6B). Importantly, recently it was shown that microhemorrhages in PDAPP mice passively immunized with the 3D6 antibody, being dose-responsive, co-localized with the vascular amyloid accumulations having altered Aβ morphology 62.

It is noteworthy that the microhemorrhages triggered by anti-Aβ antibodies may play an important role in reduction of AD-like pathology, which we observed in aged Tg2576 mice vaccinated with mannan-Aβ₂₈. This seems plausible, since only low concentrations of free anti-Aβ antibodies were detected in the sera of vaccinated mice after 11 months without further boosting with the mannan-Aβ₂₈, and mannan-BSA did not induce microhemorrhages. Although we observed less total glial activation in the brains of mice vaccinated with mannan-Aβ₂₈than in the brains of control animals (Figure 3), it is possible that areas affected by microhemorrhages may have higher CD45 and GFAP immunoreactivity. Future studies of the underlying mechanisms responsible for the antibody-induced microhemorrhages in mice may be useful for avoiding these potentially adverse events in AD patients receiving anti-Aβ immunotherapy.

Our novel vaccine candidate based on Aβ₂₈ conjugated to mannan, as the molecular adjuvant, induced production of anti-Aβ antibodies in Tg2576 mice, which have been shown to be hyporesponsive to immunization with Aβ self antigen, in the absence of conventional adjuvant. As expected, the mannan-Aβ₂₈ conjugate induced the generation of Th2-type anti-Aβ antibodies, which significantly attenuated amyloid deposition in old Tg2576 mice. However, there were increased levels of cerebral microhemorrhage in mannan-Aβ₂₈ immunized mice, which did not appear to be due to the anti-mannan antibody response induced by the immunoconjugate, because mice immunized with mannan-BSA generated higher titers of anti-mannan antibodies than mice immunized with mannan-Aβ₂₈ and they did not show elevated levels of microhemorrhage. Whether the anti-mannan antibodies increased the permeability of the BBB thus allowing elevated levels of anti-Aβ antibodies entry into cerebral perivascular and parenchymal spaces contributed to the increased incidence of microhemorrhages remains to be investigated in future studies.

The authors declare that they have no competing interests.

IP helped perform the immunizations of mice, brain collection and preparation of sections, immunohistochemical and histochemical analysis of brain sections and drafted the manuscript. AG participated in the design of the study, carried out blood collection, performed dot blot analysis for characterization of anti-Aβ antibody and helped to draft the manuscript. MM participated in the design of study and performed the statistical analysis. GM performed the quantification of staining using NIH image 1.59b5 software, conducted the ThS staining of brain sections. NM carried out ELISA for determination of anti-Aβ and anti-mannan antibody. RA helped to immunize mice and to prepare brain sections. VV analysed the activation of C1q and C3b in the brains of mice. AK helped to analyze antibody responses and to prepare figures. AL carried out the generation of mannan-Aβ₂₈ and mannan-BSA conjugates and helped in the penultimate version of the manuscript. MGA conceived the study, helped in the design of the experiments and assisted in the preparation of the text and the figures in the manuscript. DHC conceived the study, designed and coordinated the experiments and helped in the drafting and editing of the manuscript. He was responsible for the final version of the manuscript. All authors read and approved the final manuscript.