Effect of Light and Chilling Temperatures on Chilling-sensitive and Chilling-resistant Plants. Pretreatment of Cucumber and Spinach Thylakoids in Vivo and in Vitro.

The effects of chilling temperatures, in light or dark, on the isolated thylakoids and leaf discs of cucumber (Cucumis sativa L. "Marketer") and spinach (Spinacia oleracea L. "Bloomsdale") were studied. The pretreatment of isolated thylakoids and leaf discs at 4 C in the dark did not affect the phenazine methosulfate-dependent phosphorylation, proton uptake, osmotic response to sucrose, Ca(2+)-dependent ATPase activity, or chlorophyll content. Exposure of cucumber cotyledon discs and isolated thylakoids of cucumber and spinach to 4 C in light resulted in a rapid inactivation of the thylakoids. The sequence of activities or components lost during inactivation (starting with the most sensitive) are: phenazine methosulfate-dependent cyclic phosphorylation, proton uptake, osmotic response to sucrose, Ca(2+)-dependent ATPase activity, and chlorophyll. The rate of loss of proton uptake, osmotic response to sucrose, Ca(2+)-dependent ATPase activity and chlorophyll is similar for isolated cucumber and spinach thylakoids, whereas spinach thylakoids are more resistant to the loss of phenazine methosulfate-dependent phosphorylation. The thylakoids of spinach leaf discs were unaffected by exposure to 4 C in light. The results question whether the extreme resistance of spinach thylakoids treated in vivo is solely a function of the chloroplast thylakoid membranes and establish the validity of using in vitro results to make inferences about cucumber thylakoids treated in vivo at 4 C in light.

Alterations in Chloroplast Thylakoids during an in Vitro Freeze-Thaw Cycle.

Plastocyanin and chloroplast coupling factor 1 (CF(1)) are released from spinach (Spinacia oleracea L.) thylakoids during a slow freezethaw cycle. CF(1) addition increases the proton uptake of thylakoids previously frozen in sucrose concentrations of 15 mm to 100 mm. Addition of CF(1) and plastocyanin restores the proton uptake of thylakoids frozen in 100 mm sucrose. Plastocyanin and CF(1) release is a manifestation, not the cause, of freeze-thaw damage.Frozen-thawed thylakoids appear to exhibit two levels of response to sucrose as measured by light-dependent proton uptake. Different levels of protection afforded by sucrose may be due, in part, to quantitative differences in CF(1) release. The results suggest at least three freeze-induced lesions in light-dependent proton uptake by thylakoids: plastocyanin release, CF(1) release, and disruption of the semi-permeability of thylakoids.

Alterations in Chloroplast Thylakoids during Cold Acclimation.

Freeze-fracture electron microscopy reveals a decreased particle concentration on the inner fracture face of acclimated thylakoids, suggestive of some alteration(s) in the hydrophobic region. Sonic oscillation causes a reversal of the altered particle concentration in acclimated thylakoids and suggests that increases in unsaturation of fatty acids can, at most, account for only part of the altered particle concentration. The particles on the inner fracture face of acclimated thylakoids are of one size group (+/- 140 A) as compared to two size groups (+/- 100 A and +/- 165 A) for nonacclimated thylakoids. The paracrystalline array might be associated with the acclimated state of thylakoids. Nonacclimated thylakoids require 50 mm sucrose for maximum protection of light-dependent proton uptake, while acclimated thylakoids require 25 mm sucrose, and the protection afforded acclimated thylakoids during a freeze-thaw cycle is greater. Sucrose is required for alterations in acclimated thylakoids to be manifested. Apparently increased hardiness is not only associated with changes in cellular environment but also alterations in membranes.

Identification of chloroplast coupling factor by freeze-etching and negative-staining techniques.

Identification of chloroplast coupling factor particles, by the freeze-etching and negative-staining techniques, was made utilizing chloroplast thylakoids isolated from spinach leaves. Complete removal of particles, comparable in diameter to purified coupling factor particles, from the outer surface of freeze-etched thylakoids was achieved by treatment with 0.8% silicotungstate. Reappearance of particles, comparable in diameter to purified coupling factor particles, on the outer surface of freeze-etched thylakoids was demonstrated by combining silicotungstate-treated thylakoids with purified chloroplast coupling factor. Negative-staining results were in agreement with the freeze-etch data. The results demonstrate that the chloroplast coupling factor particles are exposed on the outer surface.