Stephanie Planque

Autoantibody-catalyzed Hydrolysis of Amyloid β Peptide

We describe IgM class human autoantibodies that hydrolyze amyloid β peptide 1–40 (Aβ40). A monoclonal IgM from a patient with Waldenströms macroglobulinemia hydrolyzed Aβ40 at the Lys-28—Gly-29 bond and Lys-16—Ala-17 bonds. The catalytic activity was inhibited stoichiometrically by an electrophilic serine protease inhibitor. Treatment with the catalytic IgM blocked the aggregation and toxicity of Aβ40 in neuronal cell cultures. IgMs purified from the sera of patients with Alzheimer disease (AD) hydrolyzed Aβ40 at rates superior to IgMs from age-matched humans without dementia. IgMs from non-elderly humans expressed the least catalytic activity. The reaction rate was sufficient to afford appreciable degradation at physiological Aβ and IgM concentrations found in peripheral circulation. Increased Aβ concentrations in the AD brain are thought to induce neurodegenerative effects. Peripheral administration of Aβ binding antibodies has been suggested as a potential treatment of AD. Our results suggest that catalytic IgM autoantibodies can help clear Aβ, and they open the possibility of using catalytic Abs for AD immunotherapy.

Catalytic antibodies to HIV: Physiological role and potential clinical utility

Immunoglobulins (Igs) in uninfected humans recognize residues 421-433 located in the B cell superantigenic site (SAg) of the HIV envelope protein gp120 and catalyze its hydrolysis by a serine protease-like mechanism. The catalytic activity is encoded by germline Ig variable (V) region genes, and is expressed at robust levels by IgMs and IgAs but poorly by IgGs. Mucosal IgAs are highly catalytic and neutralize HIV, suggesting that they constitute a first line of defense against HIV. Lupus patients produce the Igs at enhanced levels. Homology of the 421-433 region with an endogenous retroviral sequence and a bacterial protein may provide clues about the antigen driving anti-SAg synthesis in lupus patients and uninfected subjects. The potency and breadth of HIV neutralization revives hopes of clinical application of catalytic anti-421-433 Igs as immunotherapeutic and topical microbicide reagents. Adaptive improvement of anti-SAg catalytic Igs in HIV infected subjects is not customary. Further study of the properties of the naturally occurring anti-SAg catalytic Igs should provide valuable guidance in designing a prophylactic vaccine that amplifies protective catalytic immunity to HIV.

Catalytic antibodies to amyloid β peptide in defense against Alzheimer disease

Immunoglobulins (Igs) that bind amyloid beta peptide (Abeta) are under clinical trials for immunotherapy of Alzheimer disease (AD). We have identified IgMs and recombinant Ig fragments that hydrolyze Abeta. Hydrolysis of peripheral Abeta by the IgMs may induce increased Abeta release from the brain. The catalytic IgMs are increased in AD patients, presumably reflecting a protective autoimmune response. Reduced Abeta aggregation and neurotoxicity attributable to the catalytic function were evident. These findings provide a foundation for development of catalytic Igs for AD immunotherapy.

Exceptional Amyloid β Peptide Hydrolyzing Activity of Nonphysiological Immunoglobulin Variable Domain Scaffolds

Nucleophilic sites in the paired variable domains of the light and heavy chains (VL and VH domains) of Ig can catalyze peptide bond hydrolysis. Amyloid β (Aβ)-binding Igs are under consideration for immunotherapy of Alzheimer disease. We searched for Aβ-hydrolyzing human IgV domains (IgVs) in a library containing a majority of single chain Fv clones mimicking physiological VL-VH-combining sites and minority IgV populations with nonphysiological structures generated by cloning errors. Random screening and covalent selection of phage-displayed IgVs with an electrophilic Aβ analog identified rare IgVs that hydrolyzed Aβ mainly at His14-Gln15. Inhibition of IgV catalysis and irreversible binding by an electrophilic hapten suggested a nucleophilic catalytic mechanism. Structural analysis indicated that the catalytic IgVs are nonphysiological structures, a two domain heterodimeric VL (IgVL2-t) and single domain VL clones with aberrant polypeptide tags (IgVL-t′). The IgVs hydrolyzed Aβ at rates superior to naturally occurring Igs by 3-4 orders of magnitude. Forced pairing of the single domain VL with VH or VL domains resulted in reduced Aβ hydrolysis, suggesting catalysis by the unpaired VL domain.Ångstrom level amino acid displacements evident in molecular models of the two domain and unpaired VL domain clones explain alterations of catalytic activity. In view of their superior catalytic activity, the VL domain IgVs may help attain clearance of medically important antigens more efficiently than natural Igs.

Antibodies as defensive enzymes

Antibodies (Abs) and enzymes are structural and functional relatives. Abs with promiscuous peptidase activity are ubiquitous in healthy humans, evidently derived from germline variable domain immunoglobulin genes encoding the serine protease-like nucleophilic function. Exogenous and endogenous electrophilic antigens can bind the nucleophilic sites covalently, and recent evidence suggests that immunization with such antigens can induce proteolytic antibodies. Previously, Ab catalytic activities have been linked to pathogenic autoimmune reactions, but recent studies indicate that proteolytic Abs may also serve beneficial functions. An example is the rapid and selective cleavage of the HIV-1 coat protein gp120 by IgMs found in uninfected humans. The selectivity of this reaction appears to derive from recognition of gp120 as a superantigen. A second example is the cleavage of amyloid β-peptide by IgM and IgG from aged humans, a phenomenon that may represent a specific proteolytic response to a neurotoxic endogenous peptide implicated in the pathogenesis of Alzheimer’s disease.

VIPase autoantibodies in Fas-defective mice and patients with autoimmune disease

The immunoregulatory neuropeptide vasoactive intestinal peptide (VIP) was cleaved by purified IgG from Fas‐defective C3H/gld mice, lupus patients, and autoimmune thyroiditis patients. No VIPase activity was detected in IgG from control mice and humans. Kinetic analyses of VIPase IgG preparations suggested low‐affinity recognition of VIP. Yet the VIPase activity was VIP selective, judged by lack of correlation with other protease activities expressed by the IgG and by noninterference of unrelated peptides in the activity. Recombinant Fv constructs selected from a human lupus phage show library displayed VIPase activity, confirming that the active site is located in the V domains. Inhibition of the VIPase activity by di‐isopropylfluorophosphate suggested a serine protease‐like mechanism of catalysis. Irreversible binding of a biotinyated phosphonate diester by the IgG and Fv preparations was observed, consistent with the presence of activated nucleophiles similar to those in enzymes capable of covalent catalysis. These observations show that VIP is a target for specific catalytic autoantibodies in autoimmune disease.

Prospects for immunotherapeutic proteolytic antibodies

Monoclonal antibodies are suitable for therapeutic applications by virtue of their excellent target binding characteristics (specificity, affinity) and long half-life in vivo. Catalytic antibodies (CAbs) potentially represent a new generation of therapeutics with enhanced antigen inactivation capability. Here, we describe prospects for development of therapeutic CAbs to the envelope protein gp120 of HIV. The strategy consists of exploiting the natural tendency of the immune system to synthesize germline-encoded, serine protease-like CAbs. Lupus patients were found to develop antibodies to a conserved component of the CD4 binding site of gp120, potentially offering a means to obtain human antibodies expressing broad reactivity with various HIV strains. Covalently reactive antigen analogs (CRAs) capable of selective recognition of nucleophilic Abs were synthesized and applied to isolate Fv and L chain catalysts from lupus phage repertoires. CRA binding by the recombinant Ab fragments was statistically correlated with catalytic cleavage of model peptide substrates. A peptidyl CRA composed of residues 421-431 with a phosphonate diester moiety at its C terminus was validated as a reagent that combines noncovalent and covalent binding interactions in recognition of a gp120ase L chain. A general challenge in the field is the apparent instability of the catalytic conformation of the Abs. In reference to therapy of HIV infection, assurance is required that the Abs recognize the native conformation of gp120 expressed as a trimer on the virus surface.

Immunological Origin and Functional Properties of Catalytic Autoantibodies to Amyloid β Peptide

ObjectivesObjectives The objectives of this study are to (1) evaluate the ability of the immune system to synthesize specific antibodies that catalyze the degradation of amyloid β peptide (Aβ) and to (2) evaluate the prospect of developing a catalytic IVIG (CIVIG) formulation for therapy of Alzheimer’s disease (AD).ConclusionsPolyclonal autoantibodies from humans without dementia hydrolyzed Aβ specifically. The catalytic activity improved as a function of age. Patients with AD produced catalytic antibodies at increased levels. IgM-class antibodies expressed the activity at levels superior to IgGs. Production of catalytic autoantibodies appears to be an innate immunity function with adaptive improvements occurring upon Aβ overexpression, which suggests a beneficial function of the catalytic activity. The catalytic autoantibodies impeded Aβ aggregation, dissolved preformed Aβ aggregates, and inhibited Aβ cytotoxicity in tissue culture. Recombinant catalytic antibodies from a human library have been identified, validating the phenomenon of antibody-catalyzed Aβ cleavage. As a single catalyst molecule inactivates multiple Aβ molecules, catalytic antibodies may clear Aβ efficiently. IVIG did not cleave Aβ, indicating the importance of purification procedures that maintain catalytic site integrity. Traditional Aβ-binding antibodies form immune complexes that can induce inflammatory reaction and vascular dysfunction. Catalysts do not form stable immune complexes, minimizing these risks. Criteria appropriate for developing a CIVIG formulation with potential therapeutic utility are discussed, including isolation of the Aβ-specific catalytic subsets present in IgM and IgG from human blood.

Cross-clade HIV-1 neutralization by an antibody fragment from a lupus phage display library.

A single-chain fragment containing antibody V domains (scFv) isolated from a lupus antibody library displayed the ability to bind gp120 and the conserved gp120 determinant composed of residues 421-436. The scFv neutralized R5 and X4-dependent HIV-1 strains from clades B, C, and D. The lupus repertoire may be useful as a source of neutralizing antibodies to HIV.

Neutralization of genetically diverse Hiv-1 strains by Iga antibodies to the gp120–cd4-binding site from long-term survivors of Hiv infection

Objective:To identify an HIV epitope suitable for vaccine development. Design:Diverse HIV-1 strains express few structurally constant regions on their surface vulnerable to neutralizing antibodies. The mostly conserved CD4-binding site (CD4BS) of gp120 is essential for host cell binding and infection by the virus. Antibodies that recognize the CD4BS are rare, and one component of the CD4BS, the 421–433 peptide region, expresses B-cell superantigenic character, a property predicted to impair the anti-CD4BS adaptive immune response. Methods:IgA samples purified from the plasma of patients with HIV infection were analyzed for the ability to bind synthetic mimetics containing the 416–433 gp120 region and full-length gp120. Infection of peripheral blood mononuclear cells by clinical HIV isolates was measured by p24 ELISA. Results:IgA preparations from three patients with subtype B infection for 19–21 years neutralized heterologous, coreceptor CCR5-dependent subtype A, B, C, D, and AE strains with exceptional potency. The IgAs displayed specific binding of a synthetic 416–433 peptide mimetic dependent on recognition of the CD4-binding residues located in this region. Immunoadsorption, affinity chromatography, and mutation procedures indicated that HIV neutralization occurred by IgA recognition of the CD4BS. Conclusion:These observations identify the 421–433 peptide region as a vulnerable HIV site to which survivors of infection can produce powerful neutralizing antibodies. This indicates that the human immune system can bypass restrictions on the adaptive B cell response to the CD4BS, opening the route to targeting the 421–433 region for attaining control of HIV infection.