Elena S. Odintsova

Metal dependent hydrolysis of β-casein by sIgA antibodies from human milk.

We present the first evidence that electrophoretically and immunologically homogeneous sIgAs purified from milk of healthy human mothers by chromatography on Protein A‐Sepharose and FPLC gel filtration contain intrinsically bound metal ions (Ca > Mg ≥ Al > Fe ≈ Zn ≥ Ni ≥ Cu ≥ Mn), the removal of which by a dialysis against ethylenediamine tetraacetic acid (EDTA) leads to a significant decrease in the β‐casein‐hydrolyzing activity of these antibodies (Abs). An affinity chromatography of total sIgAs on benzamidine‐Sepharose interacting with canonical serine proteases separates a small metalloprotease sIgA fraction (6.8 ± 2.4%) from the main part of these Abs with a serine protease‐like β‐casein‐hydrolyzing activity. The relative activity of this metalloprotease sIgA fraction containing intrinsically bound metal ions increases ∼1.2–1.9‐fold after addition of external metal ions (Mg2+ > Fe2+ > Cu2+ ≥ Ca2+ ≥ Mn2+) but decreases by 85 ± 7% after the removal of the intrinsically bound metals. The metalloprotease sIgA fraction free of intrinsic metal ions demonstrates a high β‐casein‐hydrolyzing activity in the presence of individual external metal ions (Fe2+ > Ca2+ > Co2+ ≥ Ni2+) and especially several combinations of metals: Co2+ + Ca2+ < Mg2+ + Ca2+ < Ca2+ + Zn2+ < Fe2+ + Zn2+ < Fe2+ + Co2+ < Fe2+ + Ca2+. The patterns of hydrolysis of a 22‐mer oligopeptide corresponding to one of sIgA‐dependent specific cleavage sites in β‐casein depend significantly on the metal used. Metal‐dependent sIgAs demonstrate an extreme diversity in their affinity for casein‐Sepharose and chelating Sepharose, and interact with Sepharoses bearing immobilized monoclonal mouse IgGs against λ‐ and κ‐type light chains of human Abs. Possible ways of the production of metalloprotease abzymes (Abz) by human immune system are discussed. Copyright

Antibodies to HIV integrase catalyze site-specific degradation of their antigen

HIV-1 integrase (IN) catalyzes integration of a DNA copy of the viral genome into the host genome. In contrast to canonical proteases (trypsin, chymotrypsin and proteinase K), IgGs and IgMs isolated from HIV-infected patients by affinity chromatography on immobilized IN specifically hydrolyzed only IN but not many other tested intact globular proteins. The sites of IN cleavage determined by MALDI mass spectrometry were localized mainly within seven known immunodominant regions of IN. Thin layer chromatography analysis has shown that the abzymes (Abzs) could also cleave 17 to 22-mer oligopeptides (OPs) corresponding to the immunodominant regions of IN sequence with a much higher rate than non-specific long peptides or three- and tetrapeptides of various sequence. Therefore, a prolonged incubation of IN with AIDS IgGs and IgMs having high catalytic activity usually produces many OPs of different length. Since anti-IN IgGs and IgMs can efficiently hydrolyze IN, a positive role of the Abzs in counteracting the infection is possible.

Anti-integrase abzymes from the sera of HIV-infected patients specifically hydrolyze integrase but nonspecifically cleave short oligopeptides

In contrast to canonical proteases, total immunoglobulin G (IgG) and immunoglobulin M (IgM) antibodies (Abs) from HIV‐infected patients hydrolyze effectively only HIV integrase (IN), reverse transcriptase (RT), human casein, and serum albumin. Anti‐IN IgG and IgM isolated by chromatography on IN‐Sepharose hydrolyze specifically only IN but not many other tested proteins. Total Abs from HIV‐infected patients hydrolyze not only globular proteins but also different specific and nonspecific tri‐, tetra‐, and 20‐ to 25‐mer oligopeptides (OPs) with a higher rate than anti‐IN Abs isolated using IN‐Sepharose. A similar situation was observed for IgG from patients with multiple sclerosis and HIV‐infected patients, which after purification on myelin basic protein (MBP)–Sepharose and RT‐Sepharose specifically hydrolyze only MBP and RT, respectively. The active sites of all anti‐protein abzymes are localized on their light chains, whereas the heavy chain is responsible for the affinity of protein substrates. Interactions of intact globular proteins with both light and heavy chains of abzymes provide the specificity of protein hydrolysis. The affinity of anti‐IN and anti‐MBP abzymes for intact IN and MBP is approximately 102‐ to 105‐fold higher than for short and long specific and nonspecific OPs. The data suggest that all OPs interact mainly with the light chain of different Abs, which possesses a lower affinity for substrates, and therefore, depending on the OP sequences, their hydrolysis may be less specific or completely nonspecific. The data indicate that the relative activity of Abs not fractionated on specific protein sorbents in the hydrolysis of specific and nonspecific OPs can correspond to an average proteolytic activity of light chains of polyclonal Abs directed against many different proteins. Copyright

DNA‐hydrolysing activity of IgG antibodies from the sera of patients with diseases caused by different bacterial infections

DNase autoantibodies (Abs) can be found in the blood of patients with several autoimmune diseases, while the blood of healthy donors or patients with diseases with insignificant disturbances of the immune status does not contain the DNase Abs. Here we have analysed for the first time the DNase activity in the patients with diseases caused by several bacterial infections. Several rigid criteria have been applied to show that the DNase activity is an intrinsic property of IgGs from the sera of patients with bacterial diseases but not from healthy donors. The relative activity of IgGs has been shown to vary extensively between the diseases analysed and from patient to patient, but most of the preparations had detectable levels of the DNase activity. On average, the catalytic activities were significantly lower than in patients with autoimmune pathologies and increased in the following order: streptococcal infection (erysipelas) < urogenital chlamydiosis associated with arthritis (Reiter’s disease) < meningococcal meningitis < shigellosis < suppurative surgical infections caused by Staphylococcus aureus < suppurative surgical infections caused by epidermal staphylococci < urogenital ureaplasmosis associated with reactive arthritis. While intact IgGs possessed this catalytic activity, separated light chains of polyclonal Abs appeared to be even more active in the hydrolysis of DNA.

Catalytic antibodies from HIV-infected patients specifically hydrolyzing viral integrase suppress the enzyme catalytic activities.

Human immunodeficiency virus type 1 integrase (IN) catalyzes integration of a DNA copy of the viral genome into the host genome. It was shown previously that IN preincubation with various oligodeoxynucleotides (ODNs) induces formation of dimers and oligomers of different gyration radii; only specific ODNs stimulate the formation of catalytically active dimers. Here we have shown that preincubation of IN with specific and nonspecific ODNs leads to a significant and comparable decrease in its hydrolysis by chymotrypsin, while nonspecific ODNs protect the enzyme from the hydrolysis by trypsin worse than specific ODNs; all ODNs had little effect on the IN hydrolysis by proteinase K. In contrast to canonical proteweases, IgGs from HIV‐infected patients specifically hydrolyze only IN. While d(pT)n markedly decreased the IgG‐dependent hydrolysis of IN, d(pA)n and d(pA)n•d(pT)n demonstrated no detectable protective effect. The best protection from the hydrolysis by IgGs was observed for specific single‐ and especially double‐stranded ODNs. Although IN was considerably protected by specific ODNs, proteolytic IgGs and IgMs significantly suppressed both 3′‐processing and integration reaction catalyzed by IN. Since anti‐IN IgGs and IgMs can efficiently hydrolyze IN, a positive role of abzymes in counteracting the infection cannot be excluded. Copyright

Systemic lupus erythematosus: molecular cloning and analysis of recombinant DNase monoclonal κ light chain NGK-1

Because DNase antibodies are cytotoxic, enter the nucleus and cause DNA fragmentation inducing cell death by apoptosis, they can play an important role in the pathogenesis of different autoimmune pathologies and especially systemic lupus erythematosus (SLE). The interesting goal of catalytic antibodies research is not only to study a possible biological role of such antibodies, but also to develop in future new human and animal therapies that use the advantages offered by abzymes. An immunoglobulin κ light chain library from SLE patients was cloned into a phagemid vector. Phage particles displaying recombinant monoclonal antibody light chains (MLChs) capable of binding DNA were isolated by affinity chromatography on DNA-cellulose. Sixteen of the 46 MLChs efficiently hydrolyzed DNA; one MLCh (approximately 27-28kDa) was expressed in Escherichia coli and purified by metal chelating and gel filtration. MLCh NGK-1 was electrophoretically homogeneous and demonstrated a positive answer with mouse IgGs against light chains of human antibodies after western blotting. SDS-PAGE in a gel containing DNA demonstrated that the MLCh hydrolyzes DNA and is not contaminated by canonical DNases. The DNase MLCh was activated by several metal ions. The protein sequence of the DNase MLCh has homology with mammalian DNases I and shares with them several identical or similar (with the same side chain functionality) important amino acid residues, which are necessary for DNA hydrolysis and binding of Mg(2+) and Ca(2+) ions. The affinity of DNA for this first example of a MLCh (K(M) = 0.3 microM) was 150- to 200-fold higher than for human DNase I.

Why specific anti-integrase antibodies from HIV-infected patients can efficiently hydrolyze 21-mer oligopeptide corresponding to antigenic determinant of human myelin basic protein.

Human immunodeficiency virus‐infected patients possess anti‐integrase (IN) catalytic IgGs and IgMs (abzymes), which, unlike canonical proteases, specifically hydrolyze only intact globular IN. Anti‐myelin MBP abzymes from patients with multiple sclerosis and systemic lupus erythematosus efficiently hydrolyze only intact MBP. Anti‐MBP and anti‐IN abzymes do not hydrolyze several other tested control globular proteins. Here, we show that anti‐IN abzymes efficiently hydrolyze a 21‐mer oligopeptide (OP21) corresponding to one antigenic determinant (AGD) of MBP, whereas anti‐MBP abzymes extremely poorly cleave oligopeptides corresponding to AGDs of IN. All sites of IgG‐mediated and IgM‐mediated proteolysis of OP21 by anti‐IN abzymes were found for the first time by a combination of reverse phase and thin layer chromatography and mass spectrometry. Several clustered sites of OP21 cleavage were revealed and compared with the cleavage sites within the complete IN. Several fragments of OP21 had good homology with many fragments of the IN sequence. The active sites of anti‐IN abzymes are known to be located on their light chains, whereas heavy chains are responsible for the affinity for protein substrates. Interactions of intact IN with both light and heavy chains of the abzymes provide high affinity for IN and the specificity of its hydrolysis. Our data suggest that OP21 interacts mainly with the light chains of polyclonal anti‐IN abzymes, which possess lower affinity and specificity for substrate. The hydrolysis of the non‐cognate OP21 oligopeptide may be also less specific than the hydrolysis of the globular IN because in contrast to previously described serine protease‐like abzymes against different proteins, anti‐IN abzymes possess serine, thiol, acidic, and metal‐dependent protease activities. Copyright

Specific anti-integrase abzymes from HIV-infected patients: a comparison of the cleavage sites of intact globular HIV integrase and two 20-mer oligopeptides corresponding to its antigenic determinants.

HIV‐infected patients possess anti‐integrase (IN) IgGs and IgMs that, after isolation by chromatography on IN‐Sepharose, unlike canonical proteases, specifically hydrolyze only IN but not many other tested proteins. Hydrolysis of intact globular IN first leads to formation of many long fragments of protein, while its long incubation with anti‐IN antibodies, especially in the case of abzymes (Abzs) with a high proteolytic activity, results in the formation of short and very short oligopeptides (OPs). To identify all sites of IgG‐mediated proteolysis corresponding to known AGDs of integrase, we have used a combination of reverse‐phase chromatography, matrix‐assisted laser desorption/ionization spectrometry, and thin‐layer chromatography to analyze the cleavage products of two 20‐mer OPs corresponding to these AGDs. Both OPs contained 9–10 mainly clustered major, medium, and minor sites of cleavage. The main superficial cleavage sites of the AGDs in the intact IN and sites of partial or deep hydrolysis of the peptides analyzed do not coincide. The active sites of anti‐IN Abzs are localized on their light chains, whereas the heavy chains are responsible for the affinity of protein substrates. Interactions of intact globular proteins with both light and heavy chains of Abzs provide high specificity of IN hydrolysis. The affinity of anti‐IN Abzs for intact integrase was ~1000‐fold higher than for the OPs. The data suggest that both OPs interact mainly with the light chains of different monoclonal Abzs of the total pool of IgGs, which possesses lower affinity for substrates; and therefore, depending on the oligopeptide sequences, their hydrolysis may be less specific and remarkably different in comparison with the cleavage of intact globular IN. Copyright

Features of Hydrolysis of Specific and Nonspecific Globular Proteins and Oligopeptides by Antibodies against Viral Integrase from Blood of HIV-Infected Patients

It was shown previously that, as differentiated from canonical proteases, abzymes against myelin basic protein (MBP) from blood of patients with multiple sclerosis and systemic lupus erythematosus effectively cleaved only MBP, while antibodies (ABs) against integrase (IN) from blood of HIV-infected patients specifically hydrolyzed only IN. In this work, all sites of effective hydrolysis by anti-IN antibodies (IgG and IgM) of 25-mer oligopeptide (OP25) corresponding to MBP were identified using reversed-phase and thin-layer chromatographies and MALDI mass spectrometry. It was found that amino acid sequences of OP25 and other oligopeptides hydrolyzed by anti-MBP abzymes were partially homologous to some fragments of the full sequence of IN. Sequences of IN oligopeptides cleavable by anti-IN abzymes were homologous to some fragments of MBP, but anti-MBP abzymes could not effectively hydrolyze OPs corresponding to IN. The common features of the cleavage sites of OP25 and other oligopeptides hydrolyzed by anti-MBP and anti-IN abzymes were revealed. The literature data on hydrolysis of specific and nonspecific proteins and oligopeptides by abzymes against different protein antigens were analyzed. Overall, the literature data suggest that short OPs, including OP25, mainly interact with light chains of polyclonal ABs, which had lower affinity and specificity to the substrate than intact ABs. However, it seems that anti-IN ABs are the only one example of abzymes capable of hydrolyzing various oligopeptides with high efficiency (within some hours but not days). Possible reasons for the efficient hydrolysis of foreign oligopeptides by anti-IN abzymes from HIV-infected patients are discussed.

Antibodies against H3 and H4 histones from the sera of HIV-infected patients catalyze site-specific degradation of these histones

Histones and their posttranslational modified forms play pivotal roles in chromatin functioning and gene transcription. Also, histones are harmful when they enter the intercellular space; their administration to animals results in systemic inflammatory and toxic responses. Autoantibodies having enzymatic activities (abzymes) are the specific feature of several autoimmune and viral diseases. Electrophoretically homogeneous IgGs containing no canonical proteases were purified from sera of HIV‐infected patients by using several affinity chromatographies. In contrast to known canonical proteases, Abs from HIV‐infected patients hydrolyzed exclusively only histones but no other control globular proteins. The H3 and H4 histone cleavage sites by antihistone IgGs were determined by matrix‐assisted laser desorption/ionization mass spectrometry for the first time. Two clusters of H3 hydrolysis contain major (↕) and minor (*) cleavage sites: 18‐K*Q*LA↕TK*A↕AR*KS↕A*P‐30 and 34‐G*VK*KPHR*YRPGTVA*L*R‐50. H4 histone has only 1 cluster of cleavage sites containing additionally moderate (↓) cleavage sites: 15‐A↕KR↕HR↕KVLR↓D*NIQ↓GIT*K‐31. Sites of these histones cleavage correspond mainly to their known epitopes. It was surprising that most of the cleavage sites of histones are involved in the interaction with DNA of nucleosome core. Because histones act as damage‐associated molecules, abzymes against H3 and H4 can play important role in pathogenesis of AIDs and probably other viral and immune diseases.