DNA-hydrolyzing activity of IgG autoantibodies from sera of patients with various types of lymphoproliferative diseases was investigated. The association of DNA-hydrolyzing activity with the antibody (Ab) fraction has been proved by newly developed affinity-capture assay. Study of abzyme incidence in blood tumors and systemic lupus erythematosis (SLE) revealed linkage of anti-DNA Ab catalysts to mature B-cell tumors, and increased probability of DNA-abzymes formation on the background of autoimmune manifestations. These data suggest possible similarity between mechanisms of abzyme formation in SLE and B-cell lymphomas. A new mechanism of formation of DNA-specific catalytic Abs has been proposed based on the increased crossreactivity of polyclonal DNA-abzymes to DNA-depleted nuclear matrix proteins. The possibility of the abzyme production as Ab to the energetically destabilized ground state of the antigen has been discussed. Preliminary results were obtained that indicate the complement-independent cytotoxicity of anti-DNA autoantibodies isolated from blood of patients with SLE and chronic lymphocytic leukemia.
The cytotoxicity of DNA-specific autoantibodies from sera of patients with systemic lupus erythematosis (SLE) and with lymphoproliferative diseases, and from blood of healthy donors was examined on tumor-cell lines L929 and HL-60. DNA-binding IgG fractions from SLE and chronic lymphocytic leukemia (CLL) sera were cytotoxic at concentrations of up to 10(-10) M. No detectable changes in cell viability were observed after incubation with antibodies devoid of DNA-binding activity and DNA-specific antibodies isolated from blood of healthy donors and patients with T-cell lymphoma, B-cell lymphosarcoma, and acute B-cell leukemia. There was good correlation between the cytotoxic activity and DNA-hydrolyzing activity of anti-DNA antibodies. The cytotoxic effect of DNA-binding antibodies presumably was complement-independent, because it was attributed only to the Fab fragment. The cytotoxic effect was completely inhibited by preincubation with double-stranded DNA (dsDNA). Both the cytotoxic effect and the DNA-hydrolyzing activity of anti-DNA antibodies were significantly increased in the antibody fraction that displayed cross-reactivity with nuclear matrix proteins. Possible mechanisms for the formation and pathogenicity of cytotoxic anti-DNA antibodies are discussed in this article.
The dynamic of supercoiled DNA (scDNA) transformations is the key point for understanding the numerous processes taking place in the living cell [1]. DNA topology changes are vital in replication, transcription, recombination, chromosome condensation, and segregation. From the topological point of view DNA can be represented as a closed ribbon [2][3][4]. A study of the dynamic aspects of the DNA topology is closely associated with a design of an adequate mathematical description of the DNA polymeric molecule and methods for monitoring its properties [5][6][7][8]. The main topological changes of scDNA are catalyzed by DNA-topoisomerases I and II, which induce single and double nicks in DNA strains, respectively. These correspond to changes in the linking number (Lk) of the polymer substrate by 1 or 2. From the chemical point of view, the substrates and products of DNA topoisomerization are identical and catalytic events result in only slight topological changes. The product of the previous turnover acts as a substrate at the next stage, so an ensemble of topoisomers exists at each step of the reaction. This fact stipulates a description of scDNA biocatalytic A catalytic turnover of supercoiled DNA (scDNA) transformation mediated by topoisomerases leads to changes in the linking number (Lk) of the polymeric substrate by 1 or 2 per cycle. As a substrate of the topoisomerization reaction it is chemically identical to its product; even a single catalytic event results in the quantum leap in the scDNA topology. Non-intrusive continuous assay to measure the kinetics of the scDNA topoisomerization was performed. The development of such a technique was hindered because of multiple DNA species of intermediate topology present in the reaction mixture. The interrelation of DNA topology, its hydrodynamics, and optical anisotropy enable us to use the flow linear dichroism technique (FLD) for continuous monitoring of the scDNA topoisomerization reaction. This approach permits us to study the kinetics of DNA transformation catalyzed by eukaryotic topoisomerases I and II, as well as mechanistic characteristics of these enzymes and their interactions with anticancer drugs. Moreover, FLD assay can be applied to any enzymatic reaction that involves scDNA as a substrate. It also provides a new way of screening drugs dynamically and is likely to be potent in various biomedical applications.
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