Bental M, Pick U, Avron M, Degani H
Department of Isotope Research, Weizmann Institute of Science, Rehovot, Israel.
Eur J Biochem. 1990 Feb 22;188(1):111-6. doi: 10.1111/j.1432-1033.1990.tb15377.x.
A technique for the entrapment of the unicellular algae Dunaliella salina in agarose beads and their perfusion during NMR measurements is presented. The trapped cells maintained their ability to proliferate under normal growth conditions, and remained viable and stable under steady-state conditions for long periods during NMR measurements. Following osmotic shock in the dark, prominent changes were observed in the intracellular level of ATP and polyphosphates, but little to no changes in the intracellular pH or orthoposphate content. When cells were subjected to hyperosmotic shock, the ATP level decreased. The content of NMR-visible polyphosphates decreased as well, presumably due to the production of longer, NMR-invisible structures. Following hypoosmotic shock, the ATP content increased and longer polyphosphates were broken down to shorter, more mobile polymers.
本文介绍了一种将单细胞藻类杜氏盐藻包埋在琼脂糖珠中并在核磁共振测量期间进行灌注的技术。被包埋的细胞在正常生长条件下保持增殖能力,并在核磁共振测量的稳态条件下长时间保持活力和稳定。在黑暗中进行渗透压休克后,观察到细胞内ATP和多聚磷酸盐水平有显著变化,但细胞内pH值或正磷酸盐含量几乎没有变化。当细胞受到高渗休克时,ATP水平下降。核磁共振可见的多聚磷酸盐含量也下降,可能是由于产生了更长的、核磁共振不可见的结构。低渗休克后,ATP含量增加,更长的多聚磷酸盐被分解为更短、更易移动的聚合物。