Catalytic antibodies in the bone marrow and other organs of Th mice during spontaneous development of experimental autoimmune encephalomyelitis associated with cell differentiation.

Exact mechanisms of autoimmune disease development are still yet unknown. However, it is known that the development of autoimmune diseases is associated with defects in the immune system, namely, the violation of the bone marrow hematopoietic stem cells (HSCs) differentiation profiles. Different characteristics of autoimmune reaction development in experimental autoimmune encephalomyelitis (EAE) prone Th mice characterizing T-lymphocytes response were analyzed using standard approaches. Profiles of several HSCs differentiation of bone marrow (BFU-E, CFU-E, CFU-GM, CFU-GEMM, T- and B-lymphocytes) of Th male and female mice during spontaneous development of EAE were noticeably different. Patterns of total lymphocytes, B- and T-cells proliferation in several different organs (bone marrow, blood, spleen, thymus, and lymph nodes) were also remarkably different. In addition, there were in time noticeable differences in their changes for some organs of male and female mice. Characters of changes in the profiles of CD4 and CD8 cells proliferation in some organs not always coincide with those for total T lymphocytes. The changes in the differentiation profiles of HSCs and the level of lymphocytes proliferation in the bone marrow and other organs were associated with the increase in the concentration of antibodies against DNA, myelin basic protein, and myelin oligodendrocyte glycoprotein, and catalytic antibodies hydrolyzing these substrates. Despite some differences in changes in the analyzed parameters, in general, the spontaneous development of EAE in male and female mice occurs to some extent in a comparable way.

Antibody-Mediated Catalysis in Infection and Immunity.

The existence of catalytic antibodies has been known for decades. Natural antibodies capable of cleaving nucleic acid, protein, and polysaccharide substrates have been described. Although the discovery of catalytic antibodies initially aroused great interest because of their promise for the development of new catalysts, their enzymatic performance has been disappointing due to low reaction rates. However, in the areas of infection and immunity, where processes often occur over much longer times and involve high antibody concentrations, even low catalytic rates have the potential to influence biological outcomes. In this regard, the presence of catalytic antibodies recognizing host antigens has been associated with several autoimmune diseases. Furthermore, naturally occurring catalytic antibodies to microbial determinants have been correlated with resistance to infection. Recently, there has been substantial interest in harnessing the power of antibody-mediated catalysis against microbial antigens for host defense. Additional work is needed, however, to better understand the prevalence, function, and structural basis of catalytic activity in antibodies. Here we review the available information and suggest that antibody-mediated catalysis is a fertile area for study with broad applications in infection and immunity.

Evaluation of human pancreatic RNase as effector molecule in a therapeutic antibody platform.

Human antibody-ribonuclease (RNase) fusion proteins, referred to as immunoRNases, have been proposed as an alternative to heterologous immunotoxins, without their immunogenicity and unspecific toxicity issues. In this study, we investigated if human pancreatic RNase will be suitable as effector component in a therapeutic antibody development platform. We generated several fusion proteins consisting of tumor-specific human immunoglobulins (IgGs) and human pancreatic RNase. Transient mammalian cell production was efficient and IgG-RNases were purified to homogeneity. Antigen binding was comparable to the parental antibodies and RNase catalytic activity was retained even in the presence of 50-fold molar excess of human cytosolic RNase inhibitor (RI). Serum stability, cell binding and internalization of IgG-RNases were comparable to the parental IgGs. Despite these promising properties, none of the IgG-RNases revealed significant inhibition of tumor cell growth in vitro even when targeting different antigens putatively employing different endocytotic pathways. The introduction of different linkers containing endosomal protease cleavage sites into the IgG-RNase did not enhance cytotoxicity. Similarly, RI evasive human pancreatic RNase variants mediated only small inhibiting effects on tumor cell growth at high concentrations, potentially reflecting inefficient cytosolic translocation. Taken together, human pancreatic RNase and variants did not prove to be generally suitable as effector component for a therapeutic antibody drug development platform.

Novel peptide inhibiting both TEM-1 ß-lactamase and penicillin-binding proteins.

9G4H9, a catalytic antibody displaying ß-lactamase-like activity, has been developed by the anti-idiotypic approach using ß-lactamase as the first antigen. Thus 9G4H9 represents the 'internal image' of ß-lactamase. We selected a cyclic peptide anchored to a bacteriophage M13 library using 9G4H9 as the target. Pep90 is a cyclic heptapeptide enclosed between two cysteine residues. We showed that Pep90 could inhibit both TEM-1 ß-lactamase (K(i) = 333 µm) and several penicillin-binding proteins (IC50 values ranging from 6-62 µm). We determined that the tryptophan residue of Pep90 is of crucial importance for its inhibitory activity. Using Pep90 as a scaffold, we generated a new class of peptidomimetics that retained inhibitory activity towards TEM-1 ß-lactamase.

Molecular analysis of multicatalytic monoclonal antibodies.

Recently, our first report demonstrated that Cucumber mosaic virus (CMV)-specific monoclonal antibodies (mAbs) possess DNase-like activity against DNA. In the present study, we show for the first time ever how one mAb (mAb-5) has polyreactive (protease, DNase, and RNase) catalytic activities (catAbs). Amino acid sequence analysis of the encoded variable-genes showed that the light chains of the hybridomas expressed the germline family genes V kappa 1A, bb1.1 and V kappa II, bd2, whose protease and DNase catalytic activities have been reported, while the heavy chain genes were expressed in several germline families (eight of V(H)1/J558, three of V(H)5/V(H)7183, and three of V(H)8/V(H)3609). Interestingly, these germline genes have been well studied in esterolytic antibodies. Here we present for the first time convincing evidence showing that highly purified mAb-5 catalyze both single- and double-stranded DNA and exhibit RNase and protease activity. The greatest therapeutic potential of catAbs could lie in selective prodrug activation. Furthermore, catAbs offer excellent or unique specificity for individual and defined antigenic targets. Therefore, the phenomenon of autoantibody catalysis can potentially be applied to isolate efficient catalytic domains directed against pathogenetically and clinically relevant autoimmune epitopes.

A human germ line antibody light chain with hydrolytic properties associated with multimerization status.

Antibodies with nucleophilic or catalytic properties often have these characteristics encoded in their germ line genes. Because hydrolytic activity has been reported to be associated with light chain V regions, we have begun an analysis of germ line light chain proteins that could be the basis for affinity maturation into hydrolytic or other reactive antibodies. We produced the germ line A18b light chain and characterized its hydrolytic, nucleophilic, and tertiary structural activities. This light chain was purified to >99% purity and found to hydrolyze aminomethylcoumarin-peptide and larger protein substrates and bind a fluorophosphonate probe. Mutation of putative catalytic residues only resulted in loss of activity of a tetrameric but not dimeric form of the light chain. These biochemical properties provide a framework for understanding the structure-function relationships of germ line antibodies.

Mutational and inhibitory analysis of a catalytic antibody. Implication for drug discovery.

Data on catalytic antibodies (abzymes) having critical roles in pathologies, for example in some auto-immune diseases accumulate at overwhelming pace. Nevertheless, the misunderstanding of how antibodies can mimic a catalytic activity may hamper the development of therapeutic tools. We thus investigated the structure function roles of residues of a catalytic antibody endowed with a beta-lactamase activity. The catalytic antibody 9G4H9 was generated using the internal image properties of anti-idiotypic antibodies. The single-chain fragment was cloned and produced in Escherichia coli. Based on the structure function knowledge of beta-lactamases pattern and on the tridimensional model of the scFv, five residues were selected for mutagenic analysis to learn about the contribution of putative residues in catalysis. Light chain mutants R24A, S26A, S28A, and E98A lost catalytic activity significantly. Mutant K27A retained catalytic activity but the estimated K(M) was affected. Kinetic outcomes support the argument that S26 and S28 function as nucleophile and E98 as general acid/base catalyst. We have selected a peptide Pep90 able to inhibit 9G4H9 catalytic activity. We also demonstrate the tryptophan and proline residues of Pep90 (YHFLWGP) are responsible for binding and inhibitory properties of Pep90 on 9G4H9. A three-dimensional model docked with Pep90 is therefore built in which critical residues of Pep90 are buried at the interface of CDR-L1 and CDR-L3 loops whereas other are exposed to the solvent.

Antigen-specific proteolysis by hybrid antibodies containing promiscuous proteolytic light chains paired with an antigen-binding heavy chain.

The antigen recognition site of antibodies consists of the heavy and light chain variable domains (V(L) and V(H) domains). V(L) domains catalyze peptide bond hydrolysis independent of V(H) domains (Mei, S., Mody, B., Eklund, S. H., and Paul, S. (1991) J. Biol. Chem. 266, 15571-15574). V(H) domains bind antigens noncovalently independent of V(L) domains (Ward, E. S., Güssow, D., Griffiths, A. D., Jones, P. T., and Winter, G. (1989) Nature 341, 544-546). We describe specific hydrolysis of fusion proteins of the hepatitis C virus E2 protein with glutathione S-transferase (GST-E2) or FLAG peptide (FLAG-E2) by antibodies containing the V(H) domain of an anti-E2 IgG paired with promiscuously catalytic V(L) domains. The hybrid IgG hydrolyzed the E2 fusion proteins more rapidly than the unpaired light chain. An active site-directed inhibitor of serine proteases inhibited the proteolytic activity of the hybrid IgG, indicating a serine protease mechanism. The hybrid IgG displayed noncovalent E2 binding in enzyme-linked immunosorbent assay tests. Immunoblotting studies suggested hydrolysis of FLAG-E2 at a bond within E2 located approximately 11 kDa from the N terminus. GST-E2 was hydrolyzed by the hybrid IgG at bonds in the GST tag. The differing cleavage pattern of FLAG-E2 and GST-E2 can be explained by the split-site model of catalysis, in which conformational differences in the E2 fusion protein substrates position alternate peptide bonds in register with the antibody catalytic subsite despite a common noncovalent binding mechanism. These studies provide proof-of-principle that the catalytic activity of a light chain can be rendered antigen-specific by pairing with a noncovalently binding heavy chain subunit.

Improving GPX activity of selenium-containing human single-chain Fv antibody by site-directed mutation based on the structural analysis.

Glutathione peroxidase (GPX) is one of the important members of the antioxidant enzyme family. It can catalyze the reduction of hydroperoxides with glutathione to protect cells against oxidative damage. In previous studies, we have prepared the human catalytic antibody Se-scFv-B3 (selenium-containing single-chain Fv fragment of clone B3) with GPX activity by incorporating a catalytic group Sec (selenocysteine) into the binding site using chemical mutation; however, its activity was not very satisfying. In order to try to improve its GPX activity, structural analysis of the scFv-B3 was carried out. A three-dimensional (3D) structure of scFv-B3 was constructed by means of homology modeling and binding site analysis was carried out. Computer-aided docking and energy minimization (EM) calculations of the antibody-GSH (glutathione) complex were also performed. From these simulations, Ala44 and Ala180 in the candidate binding sites were chosen to be mutated to serines respectively, which can be subsequently converted into the catalytic Sec group. The two mutated protein and wild type of the scFv were all expressed in soluble form in Escherichia coli Rosetta and purified by Ni(2+)-immobilized metal affinity chromatography (IMAC), then transformed to selenium-containing catalytic antibody with GPX activity by chemical modification of the reactive serine residues. The GPX activity of the mutated catalytic antibody Se-scFv-B3-A180S was significantly increased compared to the original Se-scFv-B3.

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.

Design of a serine protease-like catalytic triad on an antibody light chain displayed on the yeast cell surface.

Lc-WT, the wild-type light chain of antibody, and Lc-Triad, its double mutant with E1D and T27aS designing for the construction of catalytic triad within Asp1, Ser27a, and original His93 residues, were displayed on the cell surface of the protease-deficient yeast strain BJ2168. When each cell suspension was reacted with BODIPY FL casein and seven kinds of peptide-MCA substrates, respectively, a remarkable difference in hydrolytic activities toward Suc-GPLGP-MCA (succinyl-Gly-Pro-Leu-Gly-Pro-MCA), a substrate toward collagenase-like peptidase, was observed between the constructs: Lc-Triad-displaying cells showed higher catalytic activity than Lc-WT-displaying cells. The difference disappeared in the presence of the serine protease inhibitor diisopropylfluorophosphate, suggesting that the three amino acid residues, Ser27a, His93, and Asp1, functioned as a catalytic triad responsible for the proteolytic activity in a similar way to the anti-vasoactive intestinal peptide (VIP) antibody light chain. A serine protease-like catalytic triad (Ser, His, and Asp) is considered to be directly involved in the catalytic mechanism of the anti-VIP antibody light chain, which moderately catalyzes the hydrolysis of VIP. These results suggest the possibility of new approach for the creation of tailor-made proteases beyond limitations of the traditional immunization approach.

A catalytic antibody heavy chain HpU-2 degrading its epitope peptide and H. pylori urease.

The HpU-2 monoclonal antibody (mAb) raised against Helicobacter pylori urease mainly recognized the alpha-subunit of the urease. On the other hand, the heavy chain of HpU-2 mAb (HpU-2-H) isolated from the parent mAb recognized both the alpha- and beta-subunit, in which the beta-subunit was recognized more strongly than the beta-subunit. HpU-2-H cleaved a peptide, SVELIDIGGNRRIFGFNALVD, which is the epitope sequence recognized by HpU-2 mAb, showing a double-phase reaction profile at 25 degrees C in a phosphate buffer. After an induction time of 24h, the cleavage of the peptide was initiated by HpU-2-H at a high rate and it was completed at 80 h of incubation. By mass spectroscopy, two main fragmented peptides, SVELIDIGGNRR and SVELIDIGGNRRIFG, were identified. In addition, many small peptide fragments were produced by successive cleavage of the fragmented peptides. Cleavage tests for H. pylori urease by HpU-2-H revealed that the beta-subunit of the urease was cleaved first and completely decomposed at 20 h of incubation. Cleavage of the alpha-subunit started after the complete decomposition of the beta-subunit. These cleavage results were in good agreement with the immunological features of HpU-2-H. The irrelevant proteins, BSA and HSA, were hardly cleaved by HpU-2-H.

Toward selective covalent inactivation of pathogenic antibodies: a phosphate diester analog of vasoactive intestinal peptide that inactivates catalytic autoantibodies.

We report the selective inactivation of proteolytic antibodies (Abs) to an autoantigen, the neuropeptide vasoactive intestinal peptide (VIP), by a covalently reactive analog (CRA) of VIP containing an electrophilic phosphonate diester at the Lys(20) residue. The VIP-CRA was bound irreversibly by a monoclonal Ab that catalyzes the hydrolysis of VIP. The reaction with the VIP-CRA proceeded more rapidly than with a hapten CRA devoid of the VIP sequence. The covalent binding occurred preferentially at the light chain subunit of the Ab. Covalent VIP-CRA binding was inhibited by VIP devoid of the phosphonate diester group. These results indicate the importance of noncovalent VIP recognition in guiding Ab nucleophilic attack on the phosphonate group. Consistent with the covalent binding data, the VIP-CRA inhibited catalysis by the recombinant light chain of this Ab with potency greater than the hapten-CRA. Catalytic hydrolysis of VIP by a polyclonal VIPase autoantibody preparation that cleaves multiple peptide bonds located between residues 7 and 22 essentially was inhibited completely by the VIP-CRA, suggesting that the electrophilic phosphonate at Lys(20) enjoys sufficient conformational freedom to react covalently with Abs that cleave different peptide bonds in VIP. These results suggest a novel route to antigen-specific covalent targeting of pathogenic Abs.

Crystallization of a carbamatase catalytic antibody Fab fragment and its complex with a transition-state analogue.

Catalytic antibodies showing carbamatase activity have significant potential in antibody-directed prodrug therapy against tumours. The Fab fragment of an IgG1 mouse monoclonal carbamatase catalytic antibody JC1 raised against a transition-state analogue, ethyl N-(3,5-dicarboxyphenyl)-P-[N-[5'-(2",5"-dioxo-1"-pyrrolidinyl)oxy-1',5'-dioxopentyl]-4-aminophenylmethyl]phosphonamidate, was obtained by digestion of the whole antibody with papain and was purified by two-step ion-exchange chromatography. Using hanging-drop vapour-diffusion crystallization techniques, three different crystal forms of the Fab fragment were obtained in the presence and absence of the transition-state analogue. All crystals diffract X-rays to between 3.5 and 3.2 A resolution. The two crystal forms grown in the presence of the transition-state analogue contain up to four or eight copies of the Fab in the asymmetric unit and diffract to 3.5 and 3.2 A, respectively. The crystal of the Fab alone is most likely to contain only two copies of the Fab in the asymmetric unit and diffracts to beyond 3.5 A. Determination of the structure will provide insights into the active-site arrangement of this antibody and will help to increase our understanding of the molecular mechanisms by which the immune system can evolve catalytic function.

Targeted destruction of the HIV-1 coat protein gp41 by a catalytic antibody light chain.

Generation of antibodies with the ability to destroy targeted viral coat proteins or tumor antigens is an important aim in current research aimed at developing superior catalytic antibodies. To this end, we raised a monoclonal antibody against a discrete sequence of the envelope gp41, RGPDRPEGIEEEGGERDRD, which is a highly conserved sequence in many human immunodeficiency virus (HIV)-1 strains. The light chain subunit of this antibody catalytically decomposed the targeted peptide antigen. The degradation of the immunized peptide antigen by the light chain was initiated by the hydrolytic scission of the peptide bond between Glu12-Gly13, followed by the successive cleavage reactions of the additional peptic bonds into small peptides and amino acids. The decomposition by the light chain obeyed Michaelis-Menten kinetics (k(cat)/K(m) = 2. 8 x 10(5) M(-1) min(-1)). A characteristic feature of the reaction was a slow initial degradation step, followed by an increase in the rate of catalysis. Removal of the light chain by immunoadsorption at either stage of the reaction resulted in recession of catalysis. The light chain also cleaved recombinant gp41 molecule, but did not degrade proteins unrelated in the sequence to the peptide immunogen (bovine and human serum albumins).

Expression of Fab fragment of catalytic antibody 6D9 in an Escherichia coli in vitro coupled transcription/translation system.

The heavy chain (Hc) and light chain (Lc) genes of the Fab fragment of a catalytic antibody 6D9 were simultaneously expressed in an Escherichia coli in vitro transcription/translation system without a reducing agent. The intermolecular disulfide bond between the Hc and Lc was found formed, suggesting a correct formation of the Fab fragment in the in vitro system. In enzyme-linked immunosorbent assay, the Fab fragment synthesized in vitro exhibited an antigen-binding activity. Addition of reduced glutathione, oxidized glutathione, protein disulfide-isomerase and molecular chaperones, GroEL and GroES, increased the solubility and the antigen-binding activity of the Fab fragment greatly. The in vitro synthesized Fab was purified by means of a hexa-histidine tag attached to the C-terminus of the Hc. Catalytic assay of the purified Fab fragment showed that the His-tagged Fab fragment synthesized in vitro had a catalytic activity comparable to that produced in vivo.

[Phenomenon of DNA-abzyme cross-reactivity and its significance for the mechanisms of cytotoxicity and apoptosis]. / Fenomen kross-reaktivnosti dnk-abzimov i ego znachenie dlia mekhanizmov tsitotoksichnosti i apoptoza.

The physiological role of DNA-abzymes and their involvement in pathogenesis of different autoimmune disorders is still unknown. At the same time, a variety of properties and features of DNA-hydrolyzing autoantibodies have been studied. Here, the phenomenon of the cross-reactivity of DNA-abzymes with the nuclear matrix proteins was studied. The possible value of the phenomenon for the cytotoxic activity of DNA-hydrolyzing autoantibodies was debated as well. A new hypothesis is put forward regarding the DNA-abzymes formation based on the phenomenon of the cross-reactivity of polyclonal DNA-abzymes with nuclear matrix proteins free of native DNA. Preliminary results suggest that there are mechanisms of cytotoxicity mediated by DNA-abzymes and independent from the system of complement and cytotoxic T-lymphocytes.

Nucleophilic proteolytic antibodies.

Proteolytic antibodies appear to utilize catalytic mechanisms akin to nonantibody serine proteases, assessed from mutagenesis and protease-inhibitor studies. The catalytic efficiency derives substantially from the ability to recognize the ground state with high affinity. Because the proteolytic activity is germline-encoded, catalysts with specificity for virtually any target polypeptide could potentially be developed by applying appropriate immunogens and selection strategies. Analysis of transition-state stabilizing interactions suggests that chemical reactivity of active-site serine residues is an important contributor to catalysis. A prototype antigen analog capable of reacting covalently with nucleophilic serine residues permitted enrichment of the catalysts from a phage-displayed lupus light-chain library. Further mechanistic developments in understanding proteolytic antibodies may lead to the isolation of catalysts suitable for passive immunotherapy of major diseases, and elicitation of catalytic immunity as a component of prophylactic vaccination.

Evolution of shape complementarity and catalytic efficiency from a primordial antibody template.

The crystal structure of an efficient Diels-Alder antibody catalyst at 1.9 angstrom resolution reveals almost perfect shape complementarity with its transition state analog. Comparison with highly related progesterone and Diels-Alderase antibodies that arose from the same primordial germ line template shows the relatively subtle mutational steps that were able to evolve both structural complementarity and catalytic efficiency.

Innate antibody catalysis.

Catalysis by antibodies is often assumed to require immunization with artificial haptens, which are proposed to stimulate adaptive immune processes and enable the development of catalytic sites with the ability to bind the transition state. Contrary to this assumption, we describe here a serine protease-like catalytic triad in an antibody light chain raised by immunization with vasoactive intestinal peptide (VIP), the structure and function of which is inherited via a germline V(L) gene. The serine protease mechanism was evident from loss of the catalytic activity by site directed mutagenesis at a framework region residue Asp1 (present study) and at two complementarity determining region residues Ser27a and His 93 (Gao, Q-S., Sun, M., Rees, A., Paul, S., 1995. Site-directed mutagenesis of proteolytic antibody light chain. J. Mol. Biol. 253, 658-664). All three catalytic residues (Ser27a, His93, Asp1) are also present in the germline counterpart of the mature V(L) gene, but the mature and germline sequences differ by four amino acids remote from the catalytic site. Reversion mutations were introduced at these amino acids in the mature light chain (His27 d:Asp, Thr28e:Ser, Ile34:Asn, Gln96:Trp; Kabat numbering, germline encoded residues shown second), generating the germline configuration of the protein. The germline light chain expressed peptidase activity, determined by assaying the cleavage of VIP and a synthetic protease substrate, Pro-Phe-Arg-Methylcoumarinamide. Differences between the kinetic constants for the mature and germline light chains were marginal. Diisopropylfluorophosphate, a serine protease inhibitor, blocked the peptidase activity of the germline light chain, suggesting the presence of the catalytic triad in a functional state. Like the mature light chain, the germline protein preferentially cleaves peptide bonds on the C-terminal side of basic residues. We conclude that the catalytic activity of certain antibodies is an innate function, originating over the course of phylogenetic evolution of the V(L) genes, as opposed to somatic processes.