Encapsulation in biodegradable microparticles enhances serum antibody response to parenterally-delivered beta-amyloid in mice

Abeta DNA vaccination for Alzheimer's disease: focus on disease prevention

Pre-clinical and clinical data suggest that the development of a safe and effective anti-amyloid-beta (Abeta) immunotherapy for Alzheimer's disease (AD) will require therapeutic levels of anti-Abeta antibodies, while avoiding proinflammatory adjuvants and autoreactive T cells which may increase the incidence of adverse events in the elderly population targeted to receive immunotherapy. The first active immunization clinical trial with AN1792 in AD patients was halted when a subset of patients developed meningoencephalitis. The first passive immunotherapy trial with bapineuzumab, a humanized monoclonal antibody against the end terminus of Abeta, also encountered some dose dependent adverse events during the Phase II portion of the study, vasogenic edema in 12 cases, which were significantly over represented in ApoE4 carriers. The proposed remedy is to treat future patients with lower doses, particularly in the ApoE4 carriers. Currently there are at least five ongoing anti-Abeta immunotherapy clinical trials. Three of the clinical trials use humanized monoclonal antibodies, which are expensive and require repeated dosing to maintain therapeutic levels of the antibodies in the patient. However in the event of an adverse response to the passive therapy antibody delivery can simply be halted, which may provide a resolution to the problem. Because at this point we cannot readily identify individuals in the preclinical or prodromal stages of AD pathogenesis, passive immunotherapy is reserved for those that already have clinical symptoms. Unfortunately those individuals have by that point accumulated substantial neuropathology in affected regions of the brain. Moreover, if Abeta pathology drives tau pathology as reported in several transgenic animal models, and once established if tau pathology can become self propagating, then early intervention with anti-Abeta immunotherapy may be critical for favorable clinical outcomes. On the other hand, active immunization has several significant advantages, including lower cost and the typical immunization protocol should be much less intrusive to the patient relative to passive therapy, in the advent of Abeta-antibody immune complex-induced adverse events the patients will have to receive immuno-supperssive therapy for an extended period until the anti Abeta antibody levels drop naturally as the effects of the vaccine decays over time. Obviously, improvements in vaccine design are needed to improve both the safety, as well as the efficacy of anti-Abeta immunotherapy. The focus of this review is on the advantages of DNA vaccination for anti-Abeta immunotherapy, and the major hurdles, such as immunosenescence, selection of appropriate molecular adjuvants, universal T cell epitopes, and possibly a polyepitope design based on utilizing existing memory T cells in the general population that were generated in response to childhood or seasonal vaccines, as well as various infections. Ultimately, we believe that the further refinement of our AD DNA epitope vaccines, possibly combined with a prime boost regime will facilitate translation to human clinical trials in either very early AD, or preferably in preclinical stage individuals identified by validated AD biomarkers.

Adjuvant activity of polymer microparticles and Montanide ISA 720 on immune responses to Plasmodium falciparum MSP2 long synthetic peptides in mice

The purpose of this work was to test the immunogenicity in C57BL mice of two synthetic peptides derived from the constant region of 3D7 and FC27 Plasmodium falciparum MSP2 dimorphic proteins, either microencapsulated into poly-lactide-co-glycolide acid microparticles (PLGA MP) or delivered with the human compatible adjuvant Montanide ISA 720 for comparison. Potent and prolonged antibody responses were obtained for both peptides by using PLGA MP formulations after subcutaneous or intradermal injections. As compared to the subcutaneous route of immunization, the intradermal route induced greater immune responses. Montanide adjuvant was effective in eliciting antibodies against the 3D7 peptide but not against the FC27 peptide. Peptide-specific cytophilic antibodies (IgG2a) were detected after boosting with homologous peptide for all vaccine formulations. MP formulations elicited a lower IgE secretion as compared to that observed for both Montanide formulated vaccines. Our results demonstrate the ability of the polymer microparticles to overcome the lack of immunogenicity of FC27 MSP2 peptide in C57BL mice and their potential to induce desirable immune responses against malaria.

Suppressed splenocyte proliferation following a xenogeneic skin graft due to implanted biomaterials

BACKGROUND

Immune system responses to antigens in the context of biomaterials are poorly understood. Biomaterial implantation results in an inflammatory reaction, which is anticipated to alter the adaptive immune response, in the case presented here, to a skin xenograft. Our earlier work showed unexpectedly low splenocyte proliferation following a xenogeneic cell implant in tandem with a biomaterial in the form of a microcapsule. Here we explore whether that effect was due to the cells or the biomaterial, and attempt to dissect the mechanism of immune deviation.

METHODS

We assessed the immune response of Balb/c mice to hamster skin grafts accompanied by one of three implants: encapsulated xenogeneic cells; free cells accompanied by the same encapsulation biomaterials; and the encapsulation biomaterials without cells. Cells were encapsulated in a hydroxyethyl methacrylate-methyl methacrylate copolymer then embedded in an agarose gel. Splenocyte proliferation upon re-challenge in vitro, antibody titer in serum, and Th1/2 polarization (by cytokines in splenocyte challenge supernatants and antibody isotypes in serum) were measured.

RESULTS

All skin grafts with encapsulation materials (even without cells) suppressed subsequent splenocyte proliferation at 10 days postimplant, although this effect disappeared by two months. In contrast, the antibody response was equal to or greater than that for a skin graft alone. Th1/2 polarization could not explain these observations because it did not correlate with the suppression of splenocyte proliferation.

CONCLUSIONS

Implanted biomaterials caused nonspecific, transient suppression of splenocyte responses to hamster cells following hamster skin grafts, which is potentially important in the context of tissue engineering.

A Virosomal Immunization Strategy against Cervical Cancer and Pre-Malignant Cervical Disease

In this study, we demonstrate that fusion-active virosomes, containing recombinant human papillomavirus type 16 (HPV16) E7 protein antigen, are capable of inducing a robust class I MHC-restricted cytotoxic T-lymphocyte (CTL) response against HPV-transformed tumour cells in a murine model system. Virosomes are reconstituted viral envelopes, which do not contain the genetic material of the native virus. During the reconstitution process, protein antigens can be encapsulated within the virosomes. In the present study, we used virosomes derived from influenza virus. These virosomes retain the cell binding and membrane fusion characteristics of native influenza virus, and have the capacity to deliver encapsulated antigens to the cytosol of antigen-presenting cells through fusion from within acidic endosomes. After immunization of mice with virosomes containing encapsulated HPV16 E7 protein, the animals developed a strong E7–specific CTL response as assessed by 51Cr release measurements and MHC tetramer staining of spleen cells. Immunization with E7–containing virosomes also resulted in E7-specific antibody responses.

In tumour challenge experiments, immunization of mice with E7-containing virosomes prevented tumour outgrowth in >70% of the animals. Thus, influenza-derived virosomes with encapsulated HPV E7 protein antigen act as an excellent vaccine delivery system for induction of cellular immunity against HPV-transformed cells and represent a promising immunotherapeutic vaccine for the treatment of (precursor lesions of) cervical cancer.

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.

Cellulose beads bound to cellulose binding domain-fused recombinant proteins; an adjuvant system for parenteral vaccination of fish

A recombinant form of the outer membrane protein (A-layer protein) associated with atypical Aeromonas salmonicida was expressed, fused to a cellulose binding domain (CBD) isolated from Clostridium cellulovorans. The resultant chimerical protein was bound to either Sigmacell 20((R)) or Orbicell cellulose particles. Common goldfish were injected intraperitoneally with the cellulose-protein complex and blood serum antibody levels produced against A-protein were examined weekly by means of ELISA. These titers were compared to those induced by immunization of goldfish with the same protein, with or without Freund's incomplete adjuvant, as well as to a standard bacterin-adjuvant system. Small Orbicell beads (1-10 microM) induced antibody levels that were equal to the titers produced by the adjuvanted protein and bacterin formulae. In comparison, the larger Sigmacell particles (10-20 microM) proved to be poor immunopotentiators. The long-term titer elicited from a single injection of A-protein bound to Orbicell beads was equivalent to that induced by two injections. All the vaccinated fish demonstrated memory to the A-layer protein after exposure to a pathogenic load of atypical A. salmonicida with Orbicell treated fish displaying the highest titer. No direct correlation was found between the presence of anti-A-protein antibodies and protection against infection. The paper describes a simple and safe method to increase the potential immunogenicity of soluble recombinant proteins by employing relatively inexpensive cellulose particles.

Intranasal immunotherapy for the treatment of Alzheimer's disease: Escherichia coli LT and LT(R192G) as mucosal adjuvants

Alzheimer's disease (AD) is the most common form of dementia worldwide, yet there is currently no effective treatment or cure. Extracellular deposition of amyloid-beta protein (Abeta) in brain is a key neuropathological characteristic of AD. In 1999, Schenk et al. first reported that an injected Abeta vaccine given to PDAPP mice, an AD mouse model displaying Abeta deposition in brain, led to the lowering of Abeta levels in brain. In 2000, we demonstrated that intranasal (i.n.) immunization with human synthetic Abeta1-40 peptide for 7 months led to a 50-60% reduction in cerebral Abeta burden in PDAPP mice; serum Abeta antibody titers were low (approximately 26 microg/ml). More recently, we have optimized our i.n. Abeta immunization protocol in wild-type (WT) mice. When low doses Escherichia coli heat-labile enterotoxin (LT) were given as a mucosal adjuvant with Abeta i.n., there was a dramatic 12-fold increase in Abeta antibody titers in WT B6D2F1 mice treated two times per week for 8 weeks compared to those of mice receiving i.n. Abeta without adjuvant. A non-toxic form of LT, designated LT(R192G), showed even better adjuvanticity; anti-Abeta antibody titers were 16-fold higher than those seen in mice given i.n. Abeta without adjuvant. In both cases, the serum Abeta antibodies recognized epitopes within Abeta1-15 and were of the immunoglobulin (Ig) isotypes IgG2b, IgG1, IgG2a and low levels of IgA. This new and improved Abeta vaccine protocol is now being tested in AD mouse models with the expectation that higher Abeta antibody titers may be more effective in reducing cerebral Abeta levels.