Characterization of epitopes of human monoclonal antibodies against cytomegalovirus glycoprotein B for neutralization and antibody-dependent phagocytosis.

As congenital cytomegalovirus (CMV) infections are the leading non-genetic cause of sensorineural hearing loss and significant neurological disabilities in children, the development of CMV vaccines should be given the highest public health priority. Although MF59-adjuvanted glycoprotein B (gB) vaccine (gB/MF59) is safe and immunogenic, its efficacy in terms of protection from natural infection was around 50 % in clinical trials. Although gB/MF59 induced high antibody titers, anti-gB antibodies contributed little to the neutralization of infection. Recent studies have found that non-neutralizing functions, including antibody-dependent phagocytosis of virions and virus-infected cells, are likely to play important roles in pathogenesis and vaccine design. Previously, we isolated human monoclonal antibodies (MAbs) that reacted with the trimeric form of gB ectodomain and found that preferential epitopes for neutralization were present on Domains (Doms) I and II of gB, while there were abundant non-neutralizing antibodies targeting Dom IV. In this study, we analyzed the phagocytosis activities of these MAbs and found the following: 1) MAbs effective for phagocytosis of the virions targeted Doms I and II, 2) the MAbs effective for phagocytosis of the virions and those of virus-infected cells were generally distinct, and 3) the antibody-dependent phagocytosis showed little correlation with neutralizing activities. Taking account of the frequency and levels of neutralization and phagocytosis, incorporation of the epitopes on Doms I and II into developing vaccines is considered desirable for the prevention of viremia.

A novel monoclonal antibody cross-reactive with both human and mouse α9 integrin useful for therapy against rheumatoid arthritis.

This study introduces a novel monoclonal anti-α9 integrin antibody (MA9-413) with human variable regions, isolated by phage display technology. MA9-413 specifically binds to both human and mouse α9 integrin by recognizing a conserved loop region designated as L1 (amino acids 104-122 of human α9 integrin). MA9-413 inhibits human and mouse α9 integrin-dependent cell adhesion to ligands and suppresses synovial inflammation and osteoclast activation in a mouse model of arthritis. This is the first monoclonal anti-α9 integrin antibody that can react with and functionally inhibit both human and mouse α9 integrin. MA9-413 allows data acquisition both in animal and human pharmacological studies without resorting to surrogate antibodies. Since MA9-413 showed certain therapeutic effects in the mouse arthritis model, it can be considered as a useful therapy against rheumatoid arthritis and other α9 integrin-associated diseases.

Analysis of relationships between polymorphisms in the genes encoding the pentameric complex and neutralization of clinical cytomegalovirus isolates.

INTRODUCTION: As congenital cytomegalovirus (CMV) infection is one of the major causes of birth defects and developmental abnormalities, it is essential to develop vaccines and therapeutic antibodies against CMV. Clinical trials demonstrated that the subunit vaccine based on glycoprotein B, which had been believed to be the major target for neutralization, did not induce sufficient protective immunity. On the other hand, it has been reported that the immunization of animals with the Pentamer, the pentameric complex of gH/gL/UL128/UL130/UL131A, induced strong neutralizing antibodies. Here, we sought to clarify whether any polymorphic alterations present in the Pentamer of clinical isolates affect neutralization by anti-Pentamer antibodies. METHODS: Sequences of the genes encoding the Pentamer components of 25 Japanese clinical isolates were determined. Neutralization of infection by two seropositive sera and by anti-Pentamer serum was measured using a CMV reporter cell line based on ARPE-19. RESULTS: Polymorphisms of the amino acid sequence of UL128, UL130, and UL131A ORFs were limited and clustered into two major groups. The identified alterations, except UL128 I140T, were mapped outside of the reported regions recognized by neutralizing antibodies. Anti-Pentamer serum neutralized infection with all isolates to a similar degree and had no correlation with the polymorphic groups. CONCLUSIONS: Our findings indicate that Pentamer antigens prepared from Merlin Fix strain induce antibodies that neutralize infection with all isolates to a similar level and that anti-Pentamer antibodies neutralize CMV infection better than do human sera, suggesting that vaccines and therapeutic antibodies based on Pentamer as an antigen have some promise.

Novel Antibody for the Treatment of Transthyretin Amyloidosis.

Familial amyloidotic polyneuropathy (FAP) is a systemic amyloidosis mainly caused by amyloidogenic transthyretin (ATTR). This incurable disease causes death ∼10 years after onset. Although it has been widely accepted that conformational change of the monomeric form of transthyretin (TTR) is very important for amyloid formation and deposition in the organs, no effective therapy targeting this step is available. In this study, we generated a mouse monoclonal antibody, T24, that recognized the cryptic epitope of conformationally changed TTR. T24 inhibited TTR accumulation in FAP model rats, which expressed human ATTR V30M in various tissues and exhibited non-fibrillar deposits of ATTR in the gastrointestinal tracts. Additionally, humanized T24 (RT24) inhibited TTR fibrillation and promoted macrophage phagocytosis of aggregated TTR. This antibody did not recognize normal serum TTR functioning properly in the blood. These results demonstrate that RT24 would be an effective novel therapeutic antibody for FAP.

Antibody therapy for familial amyloidotic polyneuropathy.

Although it is believed that altered conformations exposing cryptic regions are intermediary and critical steps in the mechanism of transthyretin (TTR) amyloid formation, no effective therapy targeting this step is available. In this study, to establish the antibody therapy for familial amyloidotic polyneuropathy (FAP), we generated a monoclonal anti-TTR antibody, which specifically reacts with surface epitopes of TTR (MAb ATTR) and evaluated its binding affinity and specificity for TTR amyloid fibrils. MAb ATTR showed specific binding affinity for TTR amyloid fibrils, but not for native form of TTR. Moreover, MAb ATTR indeed showed the high consistency with Congo red positive areas in tissue specimens from FAP ATTR V30M patients, indicating that MAb ATTR showed binding affinity and specificity for TTR amyloid fibrils in vitro and in vivo. MAb ATTR may have a potential to suppress TTR amyloid deposition and become a candidate for the antibody therapy for FAP.

Effective induction of cell death on adult T-cell leukaemia cells by HLA-DRbeta-specific small antibody fragment isolated from human antibody phage library.

By a biopanning method using cell sorter, we quickly isolated an antibody phage clone (S1T-A3) specific to human T-lymphotropic virus type 1-carrying T-cell line S1T from a human single chain Fv (scFv) antibody phage library. This scFv antibody bound to HTLV-1-carrying T-cell lines including MT-2, MT-4 and M8166 other than S1T, but not to non-HTLV-1-carrying T-cell lymphomas such as Jurkat and MOLT4 cells. Interestingly, this antibody induced the cell death on S1T cells very quickly (< 30 min). We tried to identify the target molecules by western blotting and mass spectrometric analysis, revealing that the target antigen was HLA class II DR. The cell death was induced only in dimmer form of scFv (diabody) and at 15-fold lower concentration than that of a fusion protein of scFv and human IgG Fc [(scFv)(2)-Fc] or anti HLA-DR mouse whole antibody L243. Thus, S1T-A3 diabody is a small antibody fragment with agonistic activity to induce cell death through HLA-DR. This is the first report elucidating that diabody specific to HLA-DR is effective to induce the cell death in T-cell malignancy especially adult T-cell leukaemic cell line.

Regulation of T cell response by blocking the ICOS signal with the B7RP-1-specific small antibody fragment isolated from human antibody phage library.

A costimulatory signal is required for the full activation of T cells, in addition to the antigen-specific signal via the T cell receptor. The inducible costimulator, ICOS is one of the costimulatory molecules that play an essential role in this process, particularly in the expansion or the development of effector T cells. As blocking of the interaction between ICOS and its ligand, B7RP-1, suppresses the T cell response, it can be applied to the treatment of allograft rejection or autoimmune diseases. Here, we isolated four scFv clones that were specific to human B7RP-1 by biopanning a human antibody phage library. We found that three of these clones inhibited the interaction between ICOS-Fc and B7RP-1-Fc. These inhibitory clones not only recognized B7RP-1 molecules expressed on B cells, as assessed by FACS, but also exhibited inhibitory activity in a proliferation assay of T cells stimulated with anti-CD3 mAb and B7RP-1-Fc. Finally, the suppression effect of the scFv on the allogenic immune response was examined using a mixed lymphocyte reaction assay, which demonstrated a successful inhibition of the allogenic reaction, in spite of the high dose needed for complete inhibition (360 nM).

Ig L-chain shuffling for affinity maturation of phage library-derived human anti-human MCP-1 antibody blocking its chemotactic activity.

Monocyte chemotactic protein-1 (MCP-1, CC-chemokine ligand 2; CCL2) is involved in the development of various forms of chronic inflammations. Employing the naive human single-chain Fv displaying phage library, we established seven MCP-1-specific scFvs. The MC8 and MC32 clones exhibited blocking activity for the MCP-1-induced chemotaxis of THP-1 cells, in spite of their monovalency. The analysis of V gene usage showed that all clones bore the identical Vh1 gene, IGHV1-24*01, with variable DJ joining sequences, while their Vl usage was relatively varied, suggesting the preferential contribution of the Vh gene. Based on these findings, to minimize the deteriorative influences on the MCP-1 specificity of MC32, we aimed to achieve the affinity maturation of MC32 using MC32 L-chain shuffling library and select MC32 variants. Most MC32 variants increased their affinity by reducing the k(off) value with no influence of the antigen specificity. MC32 variants #22 or #56 showed approximately 15-fold higher affinity than MC32, indicating that the L-chain shuffling library is useful if the Vh is dominantly involved in the determination of the antigen specificity.

Successful treatment of collagen-induced arthritis in non-human primates by chimeric anti-osteopontin antibody.

The presence of thrombin-cleaved form of osteopontin well correlated with various inflammatory disease activities in not only rodents, but also humans. We previously demonstrated that the blocking of the interaction of a cryptic epitope within osteopontin, which is exposed by thrombin cleavage, with its integrins by specific antibody recognizing cryptic epitope of mouse osteopontin, could significantly inhibits the development of arthritis in mice. We generated a murine monoclonal antibody, 2K1, specifically recognizing a cryptic epitope of human osteopontin, SVVYGLR. We constructed a chimeric antibody, C2K1 in which variable region of 2K1 was fused with human IgG1 constant region. In the present study, we investigated whether the therapeutic administration of C2K1 could ameliorate the established collagen-induced arthritis in cynomolgus monkey. Thus, C2K1 was injected after the onset of arthritis. The inhibition of joint swelling by C2K1 became evident at 4 to 5 weeks after initiation of arthritis, when blood level of C2K1 was peaked. Joint swelling reappeared along with the sharp decline of C2K1 blood levels at 6 weeks. Importantly, destruction of bone and cartilage in joints was still significantly prevented at 10 weeks when blood level of C2K1 was quite low if any and anti-C2K1 antibody emerged. These results demonstrate that neutralizing antibody against the cryptic epitope of osteopontin can be a future therapeutic choice for patients with rheumatoid arthritis.