Anti toxic effect of broccoli extract on stannous dichloride toxicity / Efeito antitóxico do extrato de brócolis na toxicidade do dicloreto de estanho

PURPOSE: Since Technetium-99m (99mTc) has favorable physical and chemical characteristics, it is widely used radioisotope in Nuclear Medicine. However, stannous dichloride (SnCl2) has been widely used as a reducing agent in labeling procedure of pharmaceutical with radionuclide, it has been realized that SnCl2 have genotoxic and cytotoxic effects on biological systems. In previous studies, it has been shown that some herbal extract can reduce genotoxic and cytotoxic effects of SnCl2. In the present study, it is aimed to evaluate the effect of the broccoli extract on the survival of E. coli ATCC 25922 strain against to toxic effects of SnCl2. METHODS: Broccoli was extracted with methanol extraction. HPLC and TLC analysis of broccoli extract were performed. Then antitoxicity and dose response assays were performed on bacterial strain. RESULTS: The broccoli extract had dose dependent protective effect against SnCl2 toxic effect on E. coli. CONCLUSIONS: The consumption of broccoli may alter the stannous dichloride toxicity. Broccoli extract may use as a new protective strategies against the toxic effect of SnCl2 on patients who were taken 99mTc radiopharmaceuticals.

OBJETIVO: Em face de suas características físico-químicas, o Tecnécio-99m (99mTc) é um radiofármaco amplamente utilizado na Medicina Nuclear. Todavia, o dicloreto de estanho (SnCl2) tem sido largamente aplicado como um agente redutor no procedimento farmacêutico de marcação com radionuclídeos. Constatou-se que o SnCl2 apresenta efeitos genotóxicos e citotóxicos nos sistemas biológicos. Em estudos prévios, foi demonstrado que alguns extratos de ervas podem reduzir tais efeitos. O estudo atual objetivou avaliar os efeitos do extrato de brócolis na sobrevida da cepa E. coli ATCC 25922, exposta ao efeito tóxico do SnCl2. MÉTODOS: O extrato de brócolis foi obtido mediante extração com metanol. Analises com HPLC e TLC foram efetuadas. Avaliou-se a antitoxicidade e realizou-se um ensaio dose-resposta para uma cepa de bactérias. RESULTADOS: O extrato de brócolis mostrou um efeito protetor dose dependente para os efeitos tóxicos do SnCl2 sobre a E. coli. CONCLUSÕES: O consumo de brócolis pode alterar a toxicidade do dicloreto de estanho. O extrato de brócolis pode ser utilizado como uma nova estratégia para proteção de pacientes contra os efeitos tóxicos do SnCl2, nos quais foi administrado o radiofármaco Tecnécio-99m.

Participação de enzimas de reparo por excisão de bases na restauração de lesões induzidas pela associação da radiação ultravioleta A e cloreto estanoso em Escherichia coli / Participation of repair enzyme for base excision in lesions restoration induced by the combination of A ultraviolet radiation and stannous chloride in Escherichia coli

O cloreto estanoso (SnCI2) e a radiação ultravioleta A (UVA) são agentes que lesam diversas estruturas celulares, inclusive o DNA, principalmente pela geração de espécies reativas de oxigênio. O objetivo deste trabalho foi estudar a mutagênese e o reparo das lesões produzidas pela combinação do UVA, na condição de pré-iluminação, com o SnCI2. Avaliou-se a ação de enzimas do reparo por excisão de bases (BER), em Escherichia coli (E. coli), por eletroforese em gel alcalino de agarose e sobrevivência bacteriana. Também se estudou a indução do sistema SoxRS pelo cromoteste, e a mutagênese pelo teste de Ames. De acordo com os resultados: i)o UVA induziu quebras no DNA das cepas testadas e os mutantes fpg-nfo e fpg apresentaram maior retardo no reparo das lesões; ii) o SnCI2 induziu mais quebras que o UVA e os mutantes nfo e fpg mostraram maior dificuldade em reparar as lesões; iii) o UVA+SnCI2 provocou mais quebras que o SnCI2 e os mutantes nfo e fpg também apresentaram maior lentidão no reparo das lesões; iv) o UVA não inativou as cepas testadas; v) as cepas nfo e fpg foram as mais sensíveis ao SnCI2; vi) o UVA+SnCI2 provocou maior letalidade em todas as cepas testadas, em relação ao SnCI2, e os mutantes nfo e fpg também foram os mais sensíveis ao tratamento com ambos os agentes; vii) a transformação dos mutantes nfo com o plasmídio pBW21 (nfo+) e dos mutantes fpg com o plasmídio pFPG (fpg+) aumentou a sobrevivência das cepas aos tratamentos com SnCI2 e UVA+SnCI2; viii) o SnCI2 induziu o sistema SoxRS; ix) o SnCI2, UVA e UVA+SnCI2 não induziram mutagênese; x) o reparo das lesões parece ser preferencialmente realizado pelas proteínas Fpg e Nfo.

Stannous chloride (SnCI2) and ultraviolet radiation A (UVA) are able to induce lesions in different cellular structures, including DNA, manly through ROS generation. The aim of this work was to study the mutagenesis and repair of lesions induced by the association of UVA (pre treatment) with SnCI2. It was evaluated the action of base excision repair (BER) enzymes in Escherichia coli (E. coli) by alkaline gel electrophoresis and bacterial survival. It was also evaluated the SoxRS system induction by chromotest and mutagenesis through the Ames test. According to the results: i) UVA induced DNA strand breaks in all strains and fpg-nfo and fpg mutants showed greater delay in the repair of lesions; ii) SnCI2 induced more breaks than UVA and nfo and fpg mutants showed more difficult to repair the damage; iii) UVA + SnCI2 caused more breaks than the SnCI2 and nfo and fpg mutants also showed a slowest repair of injuries; iv) UVA did not inactivate any bacterial strains tested; v) nfo and fpg strains were more sensitive to SnCI2; vi) UVA + SnCI2 caused higher mortality in all strains tested, when compared to SnCI2, and, again, nfo and fpg mutants were the most sensitives to the treatment with both agents; vii) the transformation of nfo mutant with the plasmid pBW21 (nfo+) and fpg mutants with plasmid pFPG (fpg+) increased the survival of the strains to SnCI2 and UVA + SnCI2 treatments; viii) SnCI2 was able to induce SoxRS system; ix) SnCI2, UVA + SnCI2 and UVA did not induce mutagenesis; x) damage repair seems to be preferentially performed by Fpg and Nfo proteins.

Biological effects of an aqueous extract of Salix alba on the survival of Escherichia coli AB1157 cultures submitted to the action of stannous chloride

Stannous chloride (SnC12) is used in nuclear medicine as a reducing agent to obtain technetium-99m-radiopharmaceuticals. It have been reported that natural products might reduce the genotoxic and cytotoxic effects related to SnC12. This work evaluated the biological effects of an aqueous extract of Salix alba on the survival of Escherichia coli (E. coli) AB1157 (wild type) cultures submitted to the action of SnC12. E. coli AB1157 cultures (exponential growth phase) were collected by centrifugation, washed and resuspended in 0.9 percentNaCl. Samples were incubated in water bath shaker with: (a) SnC12 (25mg/ml), (b)Salix alba extract(11.6mg/ml) and (c)SnC12(25mg/ml) + Salix alba extract (11.6mg/ml). Incubation with 0.9 percent NaCl was also carried out (control). At 60 min intervals, aliquots were withdrawn, diluted, spread onto Petri dishes with solid LB medium and incubated overnight. The colonies formed were counted and the survival fractions calculated. The extract was not able to protect the E. coli cultures against the lesive action of SnC12. The extract also did not interfere with the survival of the cultures. It suggested that the substances present in the Salix alba aqueous extract did not interfere strongly with cellular metabolism and did not alter the survival fractions of E. coli AB 1157. It is speculated that this extract cannot interfere with the generation of free radicals, the possible main agent responsible for SnC12 lesive action.

Low productivity of ribonucleotide reductase in Saccharomyces cerevisiae increases sensitivity to stannous chloride

Ribonucleotide reductase (RNR) of the yeast Saccharomyces cerevisiae is a tetrameric protein complex, consisting of two large and two small subunits. The small subunits Y2 and Y4 form a heterodimer and are encoded by yeast genes RNR2 and RNR4, respectively. Loss of Y4 in yeast mutant rnr4delta can be compensated for by up-regulated expression of Y2, and the formation of a small subunit Y2Y2 homodimer that allows for a partially functional RNR. However, rnr4delta mutants exhibit slower growth than wild-type (WT) cells and are sensitive to many mutagens, amongst them UVC and photo-activated mono- and bi-functional psoralens. Cells of the haploid rnr4delta mutant also show a 3- to 4-fold higher sensitivity to the oxidative stress-inducing chemical stannous chloride than those of the isogenic WT. Both strains acquired increased resistance to SnCl2 with age of culture, i.e., 24-h cultures were more sensitive than cells grown for 2, 3, 4, and 5 days in liquid culture. However, the sensitivity factor of three to four (WT/mutant) did not change significantly. Cultures of the rnr4delta mutant in stationary phase of growth always showed higher frequency of budding cells (budding index around 0.5) than those of the corresponding WT (budding index <0.1), pointing to a delay of mitosis/cytokinesis.

Stannous chloride participates in the generation of reactive oxygen species

A genotoxic potentiality to stannous salts has been reported. The relevance of these data is due to the wide application of this metal in our society. The biological effect of these salts might depend on the physicochemical conditions and the route of their administration. There are situations in which stannous salts can be directly administered to human beings endovenously and there is not doubt about their absorption into the body. The disparate and largely unexplained differences suggest that stannous salts as a simple poisoning and/or a remarkable genotoxic agent might be a fertile field for additional investigation. Reactive oxygen species scavengers and metal ion chelators can abolish, at least in part, the effect of stannous salts. This suggests that the generation of free radicals by the reducing agent is involved in the biological effect induced by this metal.