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The combined effects of high temperature and carbon monoxide on heat stress response

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In this study, we have examined the effects of exposure to high temperature, carbon monoxide or a combination of both conditions in a model system, the rat and in industrial workers. In the rat liver, HSP70 mRNA and HSP70 synthesis were measured by dot hybridization and western blot. The results showed that after a heat stress HSP70 mRNA and its product, HSP70 increased significantly and there was a synergism in the combined effects of high temperature and carbon monoxide exposure on the induction of HSP70 mRNA and HSP70 synthesis. Heat played a major role in this induction. The presence of antibodies to human HSP27, HSP60, HSP70, HSC73, HSP89 α and β in workers exposed to heat, carbon monoxide was also measured by western blot using purified HSPs as antigens. Plasma free amino acids were measured in the same group of workers. The incidence of antibodies to HSP27 and HSP70 was significantly higher in the workers working in an environment with extreme heat, and high carbon monoxide emission than in a control group. The carbon monoxide exposed group showed the highest incidence of antibodies to HSPs. Although our previous results indicated that workers had an insufficient protein intake, plasma free amino acids tended to increase, especially in methionine and tryptophan two kinds of amino acids which are absent from the main stress protein, HSP70. These results suggest that the major problems that these workers may face are how to facilitate the use of plasma free amino acids and reduce the inhibition of synthesis of normal proteins when they are exposed to occupational harmful factors. These results also add new information on the measurement of HSPs as a potential biomonitor to assess whether organisms are experiencing metabolic stress within their environment.

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Authors and Affiliations

  1. Institute of Occupational Medicine, Tongji Medical University, 430030, Wuhan

    Wu Yang, Xu Dai-gen & Zhang Guo-gao

  2. Laboratory of Cellular and Developmental Genetics, Laval University, G1K7P4, Quebec, Canada

    Tanguay Robert M., Wu Yang & Xu Dai-gen

  3. Department of Anatomy & Neurobiology, Dalhousie University, B3H4H7, Halifax, N. S., Canada

    Currie R. William

  4. Department of Biochemistry, Tongji Medical University, 430030, Wuhan

    Wu Tang-chun, He Han-zhen & Qu Shen

  5. Daye Steel Company, 435001, Huangshi, Hubei

    Feng Jia-de

Authors
  1. Wu Tang-chun
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  2. He Han-zhen
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  3. Tanguay Robert M.
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  4. Wu Yang
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  5. Xu Dai-gen
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  6. Currie R. William
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  7. Qu Shen
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  8. Feng Jia-de
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  9. Zhang Guo-gao
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Additional information

This work was supported by the National Natural Scientific Foundation of China, the Daye Steel Company and a joint exchange program between the National Natural Scientific Foundation of China and the Medical Research Council of Canada to Zhang Guogao and Robert M. Tanguay.

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Tang-chun, W., Han-zhen, H., Tanguay, R.M. et al. The combined effects of high temperature and carbon monoxide on heat stress response. Journal of Tongji Medical University 15, 178–183 (1995). https://doi.org/10.1007/BF02888231

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  • DOI: https://doi.org/10.1007/BF02888231

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