Rajaram Hema, Apte Shree Kumar
Molecular Biology Division, Bhabha Atomic Research Centre, Trombay, Mumbai 400 085, India.
Microbiology (Reading). 2008 Jan;154(Pt 1):317-325. doi: 10.1099/mic.0.2007/011064-0.
Heat stress caused rapid and severe inhibition of photosynthesis and nitrate reduction in nitrate-supplemented cultures of the cyanobacterium Anabaena sp. strain L-31, compared to nitrogen-fixing cultures. Anabaena strains harbour two hsp60 family genes, groEL and cpn60, respectively encoding the 59 kDa GroEL and 61 kDa Cpn60 chaperonin proteins. Of these two Hsp60 chaperonins, GroEL was strongly induced during heat stress, irrespective of the nitrogen status of the cultures, but Cpn60 was rapidly repressed and degraded in heat-stressed nitrate or ammonium-supplemented cultures. The recovery of photosynthesis, nitrate assimilation and growth in heat-stressed, nitrate-supplemented cultures were preceded by resynthesis and restoration of cellular Cpn60 levels. Glutamine synthetase activity, although adversely affected by prolonged heat stress, was not dependent on either the nitrogen status or Cpn60 levels during heat stress. Overexpression of the Cpn60 protein in the closely related Anabaena sp. strain PCC7120 conferred significant protection from heat stress to growth, photosynthesis and nitrate reduction in the recombinant strain. The data favour a role for Cpn60 in carbon and nitrogen assimilation in Anabaena.
与固氮培养物相比,热胁迫导致蓝藻鱼腥藻L-31菌株在添加硝酸盐的培养物中光合作用和硝酸盐还原受到快速且严重的抑制。鱼腥藻菌株分别含有两个hsp60家族基因groEL和cpn60,它们分别编码59 kDa的GroEL和61 kDa的Cpn60伴侣蛋白。在这两种Hsp60伴侣蛋白中,无论培养物的氮状态如何,GroEL在热胁迫期间都会被强烈诱导,但Cpn60在热胁迫的添加硝酸盐或铵的培养物中会迅速被抑制并降解。在热胁迫的添加硝酸盐的培养物中,光合作用、硝酸盐同化和生长的恢复先于细胞Cpn60水平的重新合成和恢复。谷氨酰胺合成酶活性虽然受到长时间热胁迫的不利影响,但在热胁迫期间不依赖于氮状态或Cpn60水平。在密切相关的鱼腥藻菌株PCC7120中过表达Cpn60蛋白,使重组菌株在生长、光合作用和硝酸盐还原方面免受热胁迫的显著影响。这些数据支持Cpn60在鱼腥藻碳氮同化中发挥作用。