Chilling injury and nucleotide changes in young cotton plants

Regulation of inositol 1,2,4,5,6-pentakisphosphate and inositol hexakisphosphate levels in Gossypium hirsutum by IPK1

The IPK1 genes, which code for 2-kinases that can synthesize Ins(1,2,4,5,6)P₅ from Ins(1,4,5,6)P₄, are expressed throughout cotton plants, resulting in the highest Ins(1,2,4,5,6)P₅ concentrations in young leaves and flower buds. Cotton leaves contain large amounts of Ins(1,2,4,5,6)P₅ and InsP₆ compared to plants not in the Malvaceae family. The inositol polyphosphate pathway has been linked to stress tolerance in numerous plant species. Accordingly, we sought to determine why cotton and other Malvaceae have such high levels of these inositol phosphates. We have quantified the levels of InsP₅ and InsP₆ in different tissues of cotton plants and determined the expression of IPK1 (inositol 1,3,4,5,6-pentakisphosphate 2-kinase gene) in vegetative and reproductive tissues. Gossypium hirsutum was found to contain four IPK1 genes that were grouped into two pair (AB, CD) where each pair consists of very similar sequences that were measured together. More IPK1AB is expressed in leaves than in roots, whereas more IPK1CD is expressed in roots than in leaves. Leaves and flower buds have more InsP₅ and InsP₆ than stems and roots. Leaves and roots contain more InsP₅ than InsP₆, whereas flower buds and stems contain more InsP₆ than InsP₅. Dark-grown seedlings contain more InsP₅ and InsP₆ than those grown under lights, and the ratio of InsP₅ to InsP₆ is greater in the light-grown seedlings. During 35 days of the life cycle of the third true leaf, InsP₅ and InsP₆ gradually decreased by more than 50%. Silencing IPK1AB and IPK1CD with Cotton Leaf Crumple Virus-induced gene silencing (VIGS) resulted in plants with an intense viral phenotype, reduced IPK1AB expression and lowered amounts of InsP₅. The results are consistent with Ins(1,2,4,5,6)P₅ synthesis from Ins(1,4,5,6)P₄ by IPK1. This study detailed the central role of IPK1 in cotton inositol polyphosphate metabolism, which has potential to be harnessed to improve the resistance of plants to different kinds of stress.

Effects of mild night chilling on respiration of expanding cotton leaves

Utilizing expanding leaves of cotton (Gossypium hirsutum L. cv. Coker 312), the hypothesis that suboptimal night temperatures above those for putative phase transitions of mitochondrial lipids caused greater substrate control of night respiration and increased the control that respiration exerted on ATP-dependent metabolism was tested. Night respiratory CO(2) evolution rates for 5-7-day-old leaves growing at 30/19 degrees (day/night) nearly equaled those of leaves exposed to 28 degrees C nights, while leaves exposed to 15 degrees C nights had rates that were 42% of those at 28 degrees C. No restriction of respiration by carbohydrate supply was detected for leaves grown at either cool night temperature or when warm-grown plants were transferred to cool night conditions. Pyruvate utilization was more sensitive to mild chilling than glycolysis. Growth at 30/19 or 30/15 degrees C resulted in higher nocturnal ATP:ADP and energy charge for expanding leaves than growth at 30/28 degrees C, suggesting a lessening of respiratory control of ATP-dependent metabolism with long-term night chilling. However, cool night exposure resulted in reductions in total phosphorylated adenylates, and the low ATP content, most notably occurring during 15 degrees C nights, may have restricted some metabolic activity. The cause of these low ATP levels and their possible effects on cotton metabolism during chilling remain to be elucidated.

Role of carbohydrates in diurnal chilling sensitivity of tomato seedlings

Tomato seedlings (Lycopersicon esculentum Mill.) chilled starting at different times during the light/dark cycle were most chilling-sensitive at the end of the dark period (AI King, MS Reid, BD Patterson 1982 Plant Physiol 70: 211-214). Low-temperature tolerance was regained with as little as 10 minutes of light exposure. Low light intensities were less effective than high light intensities in reducing sensitivity, and the length of exposure to light directly influenced sensitivity. Seedlings kept at low night temperatures prior to chilling were also less injured following chilling. Light also restored chilling tolerance to seedlings whose roots were removed. Supplying cut shoots with sucrose, glucose, or fructose reduced chilling sensitivity and largely eliminated the diurnal difference in sensitivity. Endogenous carbohydrate content was correlated with changes in chilling sensitivity; starch and sugar content fell markedly during the dark period. Increased concentrations of sugars were detected 15 minutes after the start of the light period. This evidence all suggests that changes in chilling sensitivity over the diurnal period are regulated by the light cycle. It also suggests that increased sensitivity at the end of the dark period could be due to carbohydrate depletion, and that chilling tolerance following light exposure is likely due to carbohydrate accumulation or closely related events.

Photosynthetic apparatus in chilling-sensitive plants : IV. Changes in ATP and protein levels in cold and dark stored and illuminated tomato leaves in relation to Hill reaction activity

Changes in the levels of both ATP and protein in relation to Hill reaction activity following cold and dark storage and illumination of leaves of Lycopersicon esculentum Mill. were studied. Loss of Hill reaction activity observed during cold and dark storage of leaves for 3-4 days was accompanied by about 50% decrease of both ATP and protein levels while the content of chlorophyll was not affected Illumination of cold and dark stored leaves (8000 lx for 2 h) resulted in almost a complete restoration of both ATP and protein levels as well as Hill reaction activity. The latter process proceeded, however with different kinetics than the former ones. The rate of Hill reaction activity increase very rapidly from the beginning of illumination while the ATP level diminished during the first hour of illumination. In addition there was a lag in the increases in protein content. By about two hours of illumination all these processes reached the maximum values. Following illumination of leaf dises stored in the cold and dark in the presence of either cycloheximide or DCMU, both ATP and proteins levels as well as Hill reaction activity were greatly diminished. These data seem to suggest that the lack of reactivation of Hill reaction activity in the presence of these two inhibitors is due to inhibition of ATP synthesis required primarily for manganese reincorporation into the thylakoid membrane and theraby restoration of Hill reaction activity (Kaniuga, Zabek and Sochanowicz, Planta 1978b). Contribution of cytoplasmic protein synthesis in this process appears to be of secondary importance, although the inactivation and reactivation of electron transport are accompanied by a large loss (as high as 50%) and the restoration of the initial protein content in leaves following illumination.