Accumulation of dehydrin-like proteins in the mitochondria of cereals in response to cold, freezing, drought and ABA treatment

Background

Dehydrins are known as Group II late embryogenesis abundant proteins. Their high hydrophilicity and thermostability suggest that they may be structure stabilizers with detergent and chaperone-like properties. They are localised in the nucleus, cytoplasm, and plasma membrane. We have recently found putative dehydrins in the mitochondria of some cereals in response to cold. It is not known whether dehydrin-like proteins accumulate in plant mitochondria in response to stimuli other than cold stress.

Results

We have found five putative dehydrins in the mitochondria of winter wheat, rye and maize seedlings. Two of these polypeptides had the same molecular masses in all three species (63 and 52 kD) and were thermostable. Drought, freezing, cold, and exogenous ABA treatment led to higher accumulation of dehydrin-like protein (dlp) 63 kD in the rye and wheat mitochondria. Protein 52 kD was induced by cold adaptation and ABA. Some accumulation of these proteins in the maize mitochondria was found after cold exposition only. The other three proteins appeared to be heat-sensitive and were either slightly induced or not induced at all by all treatments used.

Conclusions

We have found that, not only cold, but also drought, freezing and exogenous ABA treatment result in accumulation of the thermostable dehydrins in plant mitochondria. Most cryotolerant species such as wheat and rye accumulate more heat-stable dehydrins than cryosensitive species such as maize. It has been supposed that their function is to stabilize proteins in the membrane or in the matrix. Heat-sensitive putative dehydrins probably are not involved in the stress reaction and adaptation of plants.     

Mitochondrial energy-dissipating systems (alternative oxidase,uncoupling proteins,and external NADH dehydrogenase) are involved in development of frost-resistance of winter wheat seedlings

Gene expression, protein synthesis, and activities of alternative oxidase (AOX), uncoupling proteins (UCP), adenine nucleotide translocator (ANT), and non-coupled NAD(P)H dehydrogenases (NDex, NDPex, and NDin) were studied in shoots of etiolated winter wheat (Triticum aestivum L.) seedlings after exposure to hardening low positive (2°C for 7 days) and freezing (?2°C for 2 days) temperatures. The cold hardening efficiently increased frost-resistance of the seedlings and decreased the generation of reactive oxygen species (ROS) during further cold shock. Functioning of mitochondrial energy-dissipating systems can represent a mechanism responsible for the decrease in ROS under these conditions. These systems are different in their response to the action of the hardening low positive and freezing temperatures. The functioning of the first system causes induction of AOX and UCP synthesis associated with an increase in electron transfer via AOX in the mitochondrial respiratory chain and also with an increase in the sensitivity of mitochondrial non-phosphorylating respiration to linoleic and palmitic acids. The increase in electron transfer via AOX upon exposure of seedlings to hardening freezing temperature is associated with retention of a high activity of NDex. It seems that NDex but not the NDPex and NDin can play an important role in maintaining the functional state of mitochondria in heterotrophic tissues of plants under the influence of freezing temperatures. The involvement of the mitochondrial energy-dissipating systems and their possible physiological role in the adaptation of winter crops to cold and frost are discussed.     

Functioning of a CSP310 stress protein is related to the shunting of electron transfer along the respiratory chain of winter wheat mitochondria

Using three-day-old winter-wheat (Triticum aestivum L.) and six-day-old pea (Pisum sativum L.) seedlings as examples, we studied the effects of inhibitors of the electron transfer chain of plant mitochondria on the uncoupling between oxidation and phosphorylation brought about by the CSP310 stress protein. This uncoupling was inhibited by cyanide and by antibodies against CSP310, but not inhibited by antimycin A. It was shown that, in plant mitochondria, the CSP310 stress protein is involved in the electron transfer via shunting the major cytochrome pathway. In this case, the electron transfer bypasses complex II, ubiquinone, and complex III of the mitochondrial respiratory chain and is realized in the following succession: complex I-CSP310-cytochrome c-complex IV. This electron-transfer pathway was found in winter grass mitochondria during the low-temperature stress and resulted in thermogenesis. It was concluded that CSP310 is a thermogenic system, which is activated in winter grass mitochondria during the low-temperature stress.     

Mechanisms and functions of nonphosphorylating electron transport in respiratory chain of plant mitochondria

Data are raeviewed on mitochondrial systems whose functioning in plants diminishes the efficiency of oxidative phosphorylation. The involvement in this process of alternative oxidase, thermogenin-like uncoupling proteins, a 310 kD stress protein, free fatty acids, and the ADP/ATP antiporter is considered. The role of these systems is discussed with regard to thermogenesis, controlled production of reactive oxygen species, and regulation of bioenergetics and metabolism.     

Complex I of winter wheat mitochondria respiratory chain is the most sensitive to uncoupling action of plant stress-related uncoupling protein CSP 310

The influence of stress uncoupling protein CSP 310 on functional stability of different mitochondrial respiratory chain complexes was analysed using various substrates of the tricarboxylic acid cycle. Complex I was the most sensitive to CSP 310 uncoupling action whilst other complexes were more stabile. It is proposed that the key point of CSP 310 uncoupling action is complex I of plant mitochondrial respiratory chain.     

Peroxidase as a Component of the Signaling Pathway in Potato Cells during Ring Rot Infection

Changes in the activity of peroxidase, a component of the NADPH oxidase signaling pathway, in potato cells were studied. This activity increased sharply during ring rot pathogenesis. Two mechanisms of peroxidase activation were distinguished. One of them was the enzyme de novo synthesis; it was characteristic of the potato cultivar susceptible to the pathogen. Another mechanism characteristic of the resistant cultivar included not only the enzyme synthesis but also the activation of preexisting enzyme molecules. Bacterial infection and exopolysaccharides secreted by the pathogen induced changes in the pattern of intra- and extracellular peroxidases of the susceptible cultivar. No changes were noted in the peroxidase patterns of the resistant cultivar. A sharp activation of the extracellular peroxidase of R _f 15 occurred in the infected or exopolysaccharide-treated cells of the resistant cultivar.     

The Induction of Saccharomyces cerevisiae Hsp104 Synthesis by Heat Shock Is Controlled by Mitochondria

Heat shock protein Hsp104 of Saccharomyces cerevisiae functions as a protector of cells against heat stress. When yeast are grown in media containing nonfermentable carbon sources, the constitutive level of this protein increases, which suggests an association between the expression of Hsp104 and yeast energy metabolism. In this work, it is shown that distortions in the function of mitochondria appearing as a result of mutation petite or after exposure of cells to the mitochondrial inhibitor sodium azide reduce the induction of Hsp104 synthesis during heat shock. Since the addition of sodium azide suppressed the formation of induced thermotolerance in the parent type and in mutant hsp104,the expression of gene HSP104 and other stress genes during heat shock is apparently regulated by mitochondria.