Strategies for the selection of catalytic antibodies against organophosphorus nerve agents.

Among the strategies aimed at biocompatible means for organophosphorus nerve agents neutralization, immunoglobulins have attracted attention in the 1990's and 2000's both for their ability to immobilize the toxicants, but also for their ability to be turned into enzymatically active antibodies known as catalytic antibodies or abzymes (antibodies--enzymes). We will present here a critical review of the successive strategies used for the selection of these nerve agent-hydrolyzing abzymes, based on hapten design, namely antibodies raised against a wide variety of transition state analogs, and eventually the strategies based on anti-idiotypic antibodies and reactibodies.

Antibody-mediated catalysis: induction and therapeutic relevance.

Abzymes are immunoglobulins endowed with enzymatic activities. The catalytic activity of an abzyme resides in the variable domain of the antibody, which is constituted by the close spatial arrangement of amino acid residues involved in catalysis. The origin of abzymes is conferred by the innate diversity of the immunoglobulin gene repertoire. Under deregulated immune conditions, as in autoimmune diseases, the generation of abzymes to self-antigens could be deleterious. Technical advancement in the ability to generate monoclonal antibodies has been exploited in the generation of abzymes with defined specificities and activities. Therapeutic applications of abzymes are being investigated with the generation of monoclonal abzymes against several pathogenesis-associated antigens. Here, we review the different contexts in which abzymes are generated, and we discuss the relevance of monoclonal abzymes for the treatment of human diseases.

Beneficial catalytic immunity to abeta peptide.

We review attempts to treat Alzheimer disease with antibodies that bind amyloid beta peptide (Abeta) and the feasibility of developing catalytic antibodies for this purpose. Naturally occurring immunoglobulin M (IgM) class antibodies that hydrolyze Abeta and inhibit Abeta aggregation were identified. The production of these antibodies increases as a function of age, ostensibly reflecting an attempt by the immune system to protect against the deleterious effect of Abeta accumulation in old age. A search for catalytic antibodies in a library of human immunoglobulins variable (IgV) domains yielded catalysts that hydrolyzed Abeta specifically at exceptionally rapid rates. The catalytic IgVs contained the light-chain variable domains within scaffolds that are structurally reminiscent of phylogenetically ancient antibodies. Inclusion of the heavy-chain variable domain in the IgV constructs resulted in reduced catalysis. We present our view that catalytic antibodies are likely to emerge as more efficacious and safer immunotherapy reagents compared to traditional Abeta-binding antibodies.

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 beta 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.

Structure-and-mechanism-based design and discovery of therapeutics for cocaine overdose and addiction.

(-)-Cocaine is a widely abused drug and there is currently no available anti-cocaine therapeutic. Promising agents, such as anti-cocaine catalytic antibodies and high-activity mutants of human butyrylcholinesterase (BChE), for therapeutic treatment of cocaine overdose have been developed through structure-and-mechanism-based design and discovery. In particular, a unique computational design strategy based on the modeling and simulation of the rate-determining transition state has been developed and used to design and discover desirable high-activity mutants of BChE. One of the discovered high-activity mutants of BChE has a approximately 456-fold improved catalytic efficiency against (-)-cocaine. The encouraging outcome of the structure-and-mechanism-based design and discovery effort demonstrates that the unique computational design approach based on transition state modeling and simulation is promising for rational enzyme redesign and drug discovery. The general approach of the structure-and-mechanism-based design and discovery may be used to design high-activity mutants of any enzyme or catalytic antibody.

Catalytic features and eradication ability of antibody light-chain UA15-L against Helicobacter pylori.

We have successfully developed a catalytic antibody capable of degrading the active site of the urease of Helicobacter pylori and eradicating the bacterial infection in a mouse stomach. This monoclonal antibody UA15 was generated using a designed recombinant protein UreB, which contained the crucial region of the H. pylori urease beta-subunit active site, for immunization. The light chain of this antibody (UA15-L) by itself showed a proteolytic activity to substantially degrade both UreB and the intact urease. Oral administration of UA15-L also significantly reduced the number of H. pylori in a mouse stomach. This is the first example of a monoclonal catalytic antibody capable of functioning in vivo, and such an antibody may have a therapeutic utility in the future.

Catalytic antibodies and their applications.

Catalytic antibodies (CAbs) occur naturally in healthy individuals where they may form part of the innate immune system, but are preferentially found in those with autoimmune disease. CAbs can also be artificially engineered or elicited by immunizations. Their mechanisms of action include nucleophilic catalysis, induction of conformational strain, coordination with metal ions, and stabilization of transition states. Recent applications of CAbs with clinical significance include the conversion of cocaine to a non-psychoactive form, the degradation of nicotine, activation of prodrugs for targeted chemotherapy, protection from ultraviolet radiation, inhibition of HIV infectivity, and the destruction of aggregates of beta-amyloid implicated in Alzheimer's disease. Artificial CAbs are likely to find increasing applications in research, clinical medicine, diagnostics and manufacturing.

A humanized aldolase antibody for selective chemotherapy and adaptor immunotherapy.

Mouse monoclonal antibody 38C2 is the prototype of a new class of catalytic antibodies that were generated by reactive immunization. Through a reactive lysine, 38C2 catalyzes aldol and retro-aldol reactions using the enamine mechanism of natural aldolases. In addition to its remarkable versatility and efficacy in synthetic organic chemistry, 38C2 has been used for the selective activation of prodrugs in vitro and in vivo and thereby emerged as a promising tool for selective chemotherapy. Adding another application with relevance for cancer therapy, designated adaptor immunotherapy, we have recently shown that 38C2 can be chemically programmed to target tumors by formation of a covalent bond of defined stoichiometry with a beta-diketone derivative of an integrin alpha(v)beta(3) targeting RGD peptidomimetic. However, a major limitation for the transition from preclinical to clinical evaluation is the human anti-mouse antibody immune response that mouse 38C2 is likely to elicit in a majority of patients after single administration. Here, we report the humanization of mouse 38C2 based on rational design guided by molecular modeling. In essence, the catalytic center of mouse 38C2, which encompasses a deep hydrophobic pocket with a reactive lysine residue at the bottom, was grafted into a human antibody framework. Humanized 38C2 IgG1 was found to bind to beta-diketone haptens with conserved affinities and revealed strong catalytic activity with identical k(cat) and slightly higher K(M) values compared to the parental mouse antibody. Furthermore, humanized 38C2 IgG1 revealed efficiency in prodrug activation and chemical programming comparable to the parental mouse antibody.

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.

Selective chemotherapeutic strategies using catalytic antibodies: a common pro-moiety for antibody-directed abzyme prodrug therapy.

Prodrug activation by catalytic antibodies (abzymes) conjugated with anti-tumor antibodies, called antibody-directed abzyme prodrug therapy (ADAPT), has been proposed as a strategy for site-specific drug delivery systems for anti-tumor drugs. The delivery of abzymes is achieved by making a bi-specific antibody with a monovalent catalytic antibody and a monovalent binding antibody. To achieve ADAPT, we focused on specific requirements for prodrugs and catalytic antibodies, the stability of the prodrugs against natural enzymes, and the applicability of abzymes for a wide range of prodrugs. Attention was paid to the design of a pro-moiety rather than a parent drug. As a common pro-moiety, we chose vitamin B(6), because the bulky vitamin B(6) esters are relatively stable against hydrolytic enzymes in serum. We have generated catalytic antibodies by immunization of a vitamin B(6) phosphonate transition state analog. The elicited antibodies were found to hydrolyze several anti-cancer and anti-inflammatory prodrugs with the vitamin B(6) pro-moiety. Finally, we evaluated antibody-catalyzed prodrug activation by examining the growth inhibition of human cervical cancer (HeLa) cells with the vitamin B(6) ester of butyric acid. These results suggest that the pro-moiety of vitamin B(6) ester is stable enough to resist natural enzymes in serum and is removed by the tailored catalytic antibodies. The combination of catalytic antibodies and prodrugs masked with vitamin B(6) would allow hydrophobic and highly toxic drugs to be used.

Anticocaine catalytic antibodies.

Cocaine mediates its reinforcing and toxic actions through a "loss of function" effect at multiple receptors. The difficulties inherent in blocking a pleiotropic blocker pose a great obstacle for the classical receptor-antagonist approach and have contributed to the failure (to date) to devise specific treatments for cocaine overdose and addiction. As an alternative, we have embarked on an investigation of catalytic antibodies, a programmable class of artificial enzyme, as "peripheral blockers" -- agents designed to bind and degrade cocaine in the circulation before it partitions into the central nervous system to exert reinforcing or toxic effects. We synthesized transition-state analogs of cocaine's hydrolysis at its benzoyl ester, immunized mice, prepared hybridomas and developed the first anticocaine catalytic antibodies with the capacity to degrade cocaine to nonreinforcing, nontoxic products. We subsequently identified several families of anticocaine catalytic antibodies and found that the most potent antibody possessed sufficient activity to block cocaine-induced reinforcement, organ dysfunction and sudden death in rodent models of addiction, toxicity and overdose, respectively. With the potential to promote cessation of use, prolong abstinence and provide a treatment for acute overdose, the artificial enzyme approach comprehensively responds to the problem of cocaine.

Exploiting antibodies as catalysts: potential therapeutic applications.

In this review, we explore recent developments in the generation of catalytic antibodies and their potential in therapy.

Catalytic antibody therapy against the insecticide carbaryl.

Catalytic antibodies have been studied widely, but little is known about their applicability as therapeutic reagents in vivo. Here we report that carbaryl, a widely used broad-spectrum carbamate insecticide that is toxic to animals and humans, is hydrolyzed by polyclonal catalytic antibodies induced in vivo by a phosphate immunogen. To test the efficacy of the in vivo-induced polyclonal antibodies, we immunized mice with the phosphate immunogen and assayed their sensitivity to carbaryl by determining the ED(50) value, the dose that produces lowest-grade tremors in 50% of animals. We found that the ED(50) for immunized mice was 43% higher than that for nonimmunized mice and that this increase in ED(50) probably resulted from the hydrolysis of carbaryl by the catalytic antibodies in vivo. Our results suggest that polyclonal catalytic antibodies can be used as therapeutic reagents in vivo.

Cocaine catalytic antibodies: the primary importance of linker effects.

Current treatments for cocaine addiction are not effective. The development of a catalytic monoclonal antibody (mAb) provides a strategy for not only binding, but also degrading cocaine, which offers a broad-based therapy. Hapten design is the central element for programming antibody catalysis. The characteristics of the linker used in classic transition-state analogue phosphonate haptens were shown to be important for obtaining mAbs that hydrolyze the benzoate ester of cocaine.

The therapeutic potential for catalytic antibodies: from a concept to a promise.

More than ten years have now elapsed since the first reports confirmed that antibodies not only label antigenic targets but can also perform catalytic functions. Much of the initial research in this area focussed on exploring the scope and utility of these biocatalysts both as enzyme mimics and as programmable protein catalysts. However, their potential in the biomedical field has also been probed. This review details the present perspective of catalytic antibodies as new tools for immunotherapy and specifically focuses on their application to prodrug activation and drug inactivation.

Catalytic antibodies as magic bullets.

A reagent capable of detecting and selectively destroying tumor cells while leaving healthy cells intact would be a powerful tool for cancer therapy. This concept of the magic bullet has been approached by a number of strategies. Here we present a recent approach based on catalytic antibodies.