Drought stress‐induced changes in the composition and physical state of phospholipids in wheat

Vı́gh, László; Huitema, Hans J.; Woltjes, J.; Vanhasselt, Pr

doi:10.1111/j.1399-3054.1986.tb01268.x

Cited by 32 publications

(16 citation statements)

References 24 publications

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“…This finding coincided with a weakening of nuclear membranes by drought damaged phospholipids of wheat [22]. Environmental factors, such as high temperatures above 32˝C were found to promote ageing as well as disordered membrane structures [23].…”

Section: Early Beginning Of Cellular Disorganization In June 2015mentioning

confidence: 84%

Acclimation Changes of Flavonoids in Needles of Conifers during Heat and Drought Stress 2015

Feucht

Schmid

Treutter

2016

Climate

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Abstract:The long-term harsh climate conditions in 2015 distorted already from June up to November in all study trees of Tsuga and Taxus the intracellular organization of the needles. Intimately involved in these repressive processes were the flavanols, a small subgroup of the flavonoids. They were not only deposited in vacuoles of conifer needles but also in the nuclei and chromosomes. Among the many flavonoids the small group of catechin derivatives and polymers named flavanols can exclusively be stained blue with DMACA (dimethylaminocinnamaldehyde). From mid-July onward, the vacuolar flavanols of the epidermal cell layers were gradually diminished as evidenced by decreasing blue staining of nuclei and vacuoles. Subsequently, in August also the large spongy mesophyll cells showed the flavanols decreasing progressively. Apparently, the antioxidant flavanols operate as oxygen radical scavengers. (ROS) were used up during the harsh environmental stress conditions. Both, Tsuga and Taxus reacted in this way. However, it is quite surprising that in all study trees the palisade cells did not contain such vacuolar flavanols. Only these cells were in June the first to show a loss of chlorophyll from chloroplasts as well as an efflux of flavanols from the nuclei. Conversely, from September onward another group of phenols, the yellow-staining flavanols were newly formed in the palisade cells and later on also in the mesophyll cells. Obviously, they were assembled finally to stabilize finally the fragile cell sites. Summing up, the present study shows by cytological studies that the climatic conditions in 2015 produced the worst disturbance of subcellular structures observed since 2000 when our studies on nuclear phenols in needles of conifers were initiated.

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Section: Early Beginning Of Cellular Disorganization In June 2015mentioning

confidence: 84%

Acclimation Changes of Flavonoids in Needles of Conifers during Heat and Drought Stress 2015

Feucht

Schmid

Treutter

2016

Climate

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“…Evidently, more than dehydration is occurring as spores are exposed to slowly drying soil which prepares them for freezing. Perhaps metabolic processes which result in the maintenance of the fluidity of membranes, such as increased unsaturation of fatty acids (Levitt, 1980, p. 196), increase in phospholipids (Vigh et al, 1986;Borochov et al, 1987;Lynch & Steponkus, 1987), the maintenance of permeability to water (Mazur, 1969;Levitt, 1980, p. 126), and lipid-sugar interactions (Caflfrey, Fonseca & Leopold, 1988) occur as the soil slowly dries, but not in osmotically active cryoprotectants.…”

Section: Preservation Of Spores In Cryoprotective Solutionsmentioning

confidence: 99%

Cryopreservation of spores of vesicular–arbuscular mycorrhizal fungi*

Douds

Schenck

1990

New Phytologist

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SUMMARYStorage of spores of vesicular-arbuscular (VA) mycorrhizal fungi in soil at 5 °C is a common way of preserving these fungi. This method was satisfactory for Glomus intraradix Schenck & Smith but not for Gigaspora margarita Becker & Hall, Glomus mosseae (Nicol. & Gerd.) Gerdemann & Trappe, and Acaulospora longula Spain & Schenck. Preservation of spores at -60 to -70°C was examined. Cryoprotectants such as DMSO, glycerol, mannitol, and sucrose were ineffective using the freeze-damage sensitive species G. margarita. Incubation for 47 h in 0-75 to l-O M trehalose conferred a measure of freeze damage protection to the spores such tbat germination rates of previously frozen spores of G. margarita were one tenth to one sixth of controls. The best method of cryoprotection and cryopreservation was found to be slow drying of pot culture soil and freezing the spores in situ. This procedure was satisfactory for tbe five genera of VA mycorrhizal fungi evaluated.

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“…The primary focus of these studies is the behavior of membranes during drought stress, particularly the changes in composition of phospholipids as regulatory to the physical properties of the membrane, and the functioning of enzymes. There are several reports on the similarities between desiccation and freezing tolerance, in that exposure to desiccation stress improves tolerance for freezing (16,29).Sucrose levels have been found to increase during both cold hardening (1,24) and desiccation stress (2). After an initial attention to sucrose as a depressant of the freezing point, researchers lost interest because the elevated sucrose levels could not account for the considerable freezing tolerance found in coldhardened plants.…”

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confidence: 99%

mentioning

confidence: 99%

Desiccation Tolerance of Papaver dubium L. Pollen during Its Development in the Anther

Hoekstra

Roekel²

1988

Plant Physiol.

111

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Developing pollen of Papaver dubium L. becomes functional and desiccation tolerant at approximately 2 to 1 days prior to anthesis, coincident with degradation of starch and a doubling of the amount of sucrose, the primary soluble carbohydrate present. When anthers were taken from flower buds at 3 days before anthesis, pollen dehisced upon exposure to the ambient air. This dried pollen did not fluoresce with the vital stain fluorescein diacetate, had increased leakage of K , and did not swell properly in a germination medium. In contrast, pollen became functional and desiccation resistant when these young anthers were first incubated in a water-saturated atmosphere for 30 hours. Phospholipid composition revealed no major differences over the last 3 days of development. When this immature pollen was liberated mechanically and allowed to mature in humid air, starch degraded and sucrose content nearly doubled, and the grains became largely functional and dehydration tolerant. Large unilamellar vesicles were prepared from isolated phospholipids to study dehydration-induced fusion and leakage. When dried in the presence of increasing concentrations of sucrose, vesicle integrity was progressively retained. These data indicate that pollen maturation during the last 3 days of development occurred independently from the parent plant. Sucrose may play an essential role in the acquired tolerance to severe dehydration.Pollen and seeds are plant organs that are generally much more tolerant to dehydration, than are leaves and roots. Basic knowledge about this difference in drought tolerance is very limited, although acquisition of partial tolerance to desiccation has been extensively studied (for a review see Ref. 2). The primary focus of these studies is the behavior of membranes during drought stress, particularly the changes in composition of phospholipids as regulatory to the physical properties of the membrane, and the functioning of enzymes. There are several reports on the similarities between desiccation and freezing tolerance, in that exposure to desiccation stress improves tolerance for freezing (16,29).Sucrose levels have been found to increase during both cold hardening (1,24) and desiccation stress (2). After an initial attention to sucrose as a depressant of the freezing point, researchers lost interest because the elevated sucrose levels could not account for the considerable freezing tolerance found in coldhardened plants. However, isolated thylakoid membranes are protected from the adverse effects of freezing, desiccation and heat stress much better by raffinose and sucrose than by equimolal concentrations of glucose (24).In anhydrobiotic microscopic animals such as nematodes (20) and Artemia cysts (5), adapted to survive extreme desiccation, trehalose, the nonreducing disaccharide of glucose, is related to acquired tolerance to severe desiccation. Trehalose has been detected in a wide variety of anhydrobiotic organisms (7), but its presence in pollen of higher plants has not been reported (26). The st...

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Drought stress‐induced changes in the composition and physical state of phospholipids in wheat

Cited by 32 publications

References 24 publications

Acclimation Changes of Flavonoids in Needles of Conifers during Heat and Drought Stress 2015

Acclimation Changes of Flavonoids in Needles of Conifers during Heat and Drought Stress 2015

Cryopreservation of spores of vesicular–arbuscular mycorrhizal fungi*

Desiccation Tolerance of Papaver dubium L. Pollen during Its Development in the Anther

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