Chilling Injury Induces Lipid Phase Changes in Membranes of Tomato Fruit

Wide-angle x-ray diffraction has provided evidence for lipid phase separations in microsomal membranes from chill-injured tomato (Lycopersicon esculentum Mill. cv Caruso) fruit. Mature-green fruit stored for 20 d at 5[deg]C had not begun to ripen and were essentially free of chilling injury symptoms. Within 4 d of being returned to 25[deg]C, however, the fruit displayed characteristic symptoms of chilling injury, including translucent water-soaked patches, surface pitting, and irregular pigmentation. Membrane damage measured as electrolyte leakage from pericarp discs intensified after the fruit were returned to ambient temperature. Wide-angle x-ray diffraction patterns recorded at 25[deg]C for microsomal membranes isolated from untreated, mature-green fruit indicated that the membrane bilayers were exclusively liquid-crystalline. Diffraction patterns for microsomal membranes from fruit stored for 20 d at 5[deg]C showed only trace amounts of gel phase lipid, but within 4 d of subsequent exposure of the fruit to ambient temperature, there was evidence for a pronounced lateral phase separation of lipids within the membranes that would render them leaky. Inas-much as the phase separations were detectable at 25[deg]C and became pronounced only subsequent to the chilling episode, they appear to be an indirect rather than direct effect of exposure to low temperature. The diffraction data thus support the notion that the lipid phase changes observed here are not directly induced by low temperature but rather reflect subsequent biochemical changes in the bilayers that may contribute to the development of chilling symptoms.

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