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Journal of Experimental Biology, Vol 201, Issue 2 227-236, Copyright © 1998 by Company of Biologists

JOURNAL ARTICLES

Freezing survival by isolated Malpighian tubules of the New Zealand alpine weta Hemideina maori

DS Neufeld and LP Leader
Department of Physiology, University of Otago, Dunedin, New Zealand. dneufeld@u.arizona.edu

The ability of isolated Malpighian tubules from a freeze-tolerant insect, the New Zealand alpine weta (Hemideina maori), to withstand freezing was assessed by measuring post-freeze membrane potentials and rates of fluid secretion. The hemolymph of cold-acclimated Hemideina maori was found to contain relatively high concentrations of the cryoprotectants trehalose (>300 mmol l-1) and proline (41 mmol l-1). Survival of isolated Malpighian tubules was correspondingly high when a high concentration of trehalose was present in the bathing saline. Tubules allowed to recover for 20 min from a 1 h freeze to -5 degrees C in saline containing 400 mmol l-1 trehalose had a basolateral membrane potential of -53 mV compared with a potential of -63 mV in tubules not exposed to a freeze/thaw cycle. Fluid secretion in tubules that had experienced a freeze/thaw cycle in saline containing 400 mmol l-1 trehalose was 9.9+/-2.6 nl h-1 compared with 18.7+/-5.0 nl h-1 (means +/- s.e.m., N=18) in tubules that had not been frozen. Tubules frozen in saline containing a lower concentration of trehalose (200 mmol l-1) or in glucose (400 mmol l-1) showed a similar ability to survive freezing to -5 degrees C. In contrast, freezing for 1 h at -5 degrees C in saline containing 400 mmol l-1 sucrose produced a 57 % decrease in membrane potential and an 88 % decrease in secretion rate. Tubules held in saline lacking high concentrations of sugars showed no survival after freezing to -5 degrees C for 1 h. When frozen to -15 degrees C, tubules appeared to survive best in saline with the highest trehalose concentration (400 mmol l-1). Freezing damage was not simply the result of exposure to cold, since tubules chilled (unfrozen) to -5 degrees C for 1 h were not compromised even when the bathing saline lacked a high sugar concentration. Exposure of tubules to a combination of low temperature and high osmolality mimicked damage caused by actual freezing: the membrane potential showed a 60 % recovery when the test was performed in saline containing trehalose, but showed no recovery in saline containing sucrose.
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