Reactive oxygen species damage intracellular targets and are implicated in cancer, genetic disease, mutagenesis, and aging. Catalases are among the key enzymatic defenses against one of the most physiologically abundant reactive oxygen species, hydrogen peroxide. The well-studied, heme-dependent catalases accelerate the rate of the dismutation of peroxide to molecular oxygen and water with near kinetic perfection. Many catalases also bind the cofactors NADPH and NADH tenaciously, but, surprisingly, NAD(P)H is not required for their dismutase activity. Although NAD(P)H protects bovine catalase against oxidative damage by its peroxide substrate, the catalytic role of the nicotinamide cofactor in the function of this enzyme has remained a biochemical mystery to date. Anions formed by heavy metal oxides are among the most highly reactive, natural oxidizing agents. Here, we show that a natural isolate of Staphylococcus epidermidis resistant to tellurite detoxifies this anion thanks to a novel activity of its catalase, and that a subset of both bacterial and mammalian catalases carry out the NAD(P)H-dependent reduction of soluble tellurite ion (TeO3 2−) to the less toxic, insoluble metal, tellurium (Te°), in vitro. An Escherichia coli mutant defective in the KatG catalase/peroxidase is sensitive to tellurite, and expression of the S. epidermidis catalase gene in a heterologous E. coli host confers increased resistance to tellurite as well as to hydrogen peroxide in vivo, arguing that S. epidermidis catalase provides a physiological line of defense against both of these strong oxidizing agents. Kinetic studies reveal that bovine catalase reduces tellurite with a low Michaelis-Menten constant, a result suggesting that tellurite is among the natural substrates of this enzyme. The reduction of tellurite by bovine catalase occurs at the expense of producing the highly reactive superoxide radical.
Endoglin (CD105) is a homodimeric cell surface component of the TGF-beta 1 receptor complex, which is expressed at high levels on vascular endothelium and at lower levels on activated monocytes. It is also the target gene for the dominantly inherited vascular disorder hereditary hemorrhagic telangiectasia type 1. To date, each family has a distinct endoglin mutation, most of which generate premature stop codons. The purpose of the current study was to identify monoclonal antibodies capable of binding to normal and mutated forms of the protein. We generated stable transfectants of full-length human endoglin in murine fibroblasts and engineered and expressed in bacteria several fragments of the extracellular domain. Relatively pure polypeptides were recovered with good yield from inclusion bodies and were tested by ELISA and Western blot; 11 monoclonal antibodies were shown to react specifically with the endoglin transfectants. Ten of these monoclonal antibodies reacted with the bacterial fragments, and their epitopes were assigned to 3 distinct regions of endoglin. Monoclonal antibodies P3D1, TEC4 and GRE reacted with the N-terminal region of 204 amino acids encoded by exons 1 to 5. Monoclonal antibodies P4A4, 44G4, E-9, MAEND3 and PN-E2 all bound to a region of 54 amino acids encoded mostly by exon 7. Monoclonal antibodies CLE4 and RMAC8 reacted with the C-terminal region of the extracellular domain, coded for by exons 8 to 12. Knowing the localization of these epitopes will facilitate the structural and functional analysis of normal and mutated forms of endoglin.
HIV-1 virions contain two reverse transcriptase polypeptides that have apparent molecular weights of 66 and 51 kDa. The 51 -kDa form lacks the carboxy-terminal sequences found in the 66-kDa form, and is believed to be a proteolytic digestion product. We have treated purified 66-kDa reverse transcriptase with viral and nonviral proteases. The digestion products were characterized by their ability to react with monoclonal antibodies known to recognize particular segments of the HIV-1 reverse transcriptase.The approximate location of the segments recognized by the monoclonal antibodies was determined by testing the ability of the antibodies to recognize a series of amino-and carboxy-terminaldeleted forms of HIV-1 reverse transcriptase.The segments recognized are not uniformly distributed along the primary amino acid sequence of HIV-1 reverse transcriptase.We suggest that these segments are probably on the surface of the properly folded form of reverse transcriptase.Of the tested proteases, only the viral protease was able to cleave the 66-kDa form to the 51-kDa form without producing additional cleavage products, suggesting that the viral protease cleaves the 66-kDa protein to the 51 -kDa form in virions.
The integrase of the human immunodeficiency virus type 1 (HIV-1) has been expressed in yeast in order to investigate its potential lethal effect mediated by DNA damage. To this end, we have constructed an expression plasmid containing the retroviral integrase gene under the control of the inducible promotor ADH2/GAPDH which is regulated by the glucose concentration of the medium. Haploid yeast strain W303-1A did not appear to be clearly sensitive to HIV-1 integrase expression. However, disruption of the RAD 52 gene, which is involved in the repair of double-strand DNA breaks, strongly increased the deleterious effects of the retroviral enzyme in this yeast strain. The diploid strain constructed with W303-1A and an isogenic strain of the opposite mating type also showed a strong sensitivity to the HIV-1 integrase. Under yeast culture conditions allowing moderate integrase synthesis, the deleterious effect was totally abolished by missense integrase mutations, which are known to abolish HIV-1 integrase activities in vitro. We conclude that the lethal phenotype due to HIV-1 integrase expression in yeast may be closely related to the HIV-1 integration reaction in infected human cells, and that yeast may be a useful tool to study the HIV-1 integration process and to screen drugs capable of inhibiting HIV-1 integration in vivo.
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