Swelling and Contraction of Mitochondria from Cold-hardened and Nonhardened Wheat and Rye Seedlings

Pomeroy, M. Keith

doi:10.1104/pp.57.4.469

Cited by 12 publications

(2 citation statements)

References 19 publications

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“…Several investigators have suggested that cold hardening may in fact be related to an increase in membrane flexibility, at low temperatures (14,19). Membranes are relatively fragile components of cells, and may be injured by a variety of stress conditions (14).…”

Section: Resultsmentioning

confidence: 99%

Effect of Abscisic Acid on Root Hydraulic Conductivity

Markhart¹,

Fiscus²,

Naylor³

et al. 1979

Plant Physiol.

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Reports of the effects of abscisic acid (ABA) on ion and water fluxes have been contradictory. Some of the confusion seems due to the interaction of ion and water transport across membranes. In these experiments root systems were subjected to hydrostatic pressures up to 5.0 bars to enable measurement of root conductance that was independent of measurement of osmotic potentials or ion fluxes.ABA between 5 x 10-I molar and 2 x 10' molar resulted in a decrease in the conductance of the soybean root systems as compared with the controls. ABA treatment also eliminated the discontinuity in the Arrhenius plot of total flow versus reciprocal temperature at constant pressure. The results suggest that ABA acts at the membrane that is rate-limiting to water flow directly, or by altering metabolism that in turn affects the membrane.The dramatic increase in ABA content in stressed plants (20,23) (12) found that ABA stimulated ion uptake in Phaseolus roots, whereas Erlandsson and co-workers (4) observed a decrease in "Rb uptake in sunflower roots.Cram and Pitman (3) reported that ABA did not change the hydraulic conductivity of maize or barley roots, but Glinka and Reinhold (9, 10) reported that ABA increased both the diffusional permeability and hydraulic conductivity of roots to water flow under a pressure of 0.8 bar. Most recently, ABA was reported to have no effect on osmotically driven water flow in excised sunflower roots (4). Pitman and Wellfare (18) found dramatic decreases in barley root exudation rates treated with ABA, but concluded that this was due to an inhibition of active salt transport and not hydraulic conductivity. ' Research supported by National Science Foundation Grants PCM76-11 142-AO1-2 to Dr. P. J. Kramer and DEB77-15845 These contradictions could be due to the difficulty in evaluating a complex transport system as a root. The standing osmotic gradient (I) and the removal of ions from the ascending xylem water (13) make determination of the osmotic driving force for water flow difficult. At low hydrostatic pressures the interaction between osmotic and hydrostatic driving forces makes it impossible to assess whether a change in flow rate is due to a change in hydraulic conductivity or ion movement (6). The analytical technique of Fiscus (6) provides a method of measuring the hydraulic conductance (L)5 of a root system independent of ion transport.The experiments reported here use applied hydrostatic pressures to determine the effect of ABA on water flux through root systems, to determine if changes in flux are due to changes in L and to determine the nature of the changes ABA induces in the ratelimiting barrier to water flux. MATERIALS AND METHODSCulture conditions and basic experimental procedures have been previously described (15). Soybean plants were grown in a half-strength Hoagland nutrient solution under a 14-h photoperiod and a thermoperiod of 28/23 C. Root systems of decapitated plants were sealed in a 10.3-liter pressure chamber filled with fresh nutrient solution. Hydrostatic pres...

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Section: Resultsmentioning

confidence: 99%

Effect of Abscisic Acid on Root Hydraulic Conductivity

Markhart¹,

Fiscus²,

Naylor³

et al. 1979

Plant Physiol.

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“…Under certain conditions, it is believed that proton pumping can be exclusively linked to cation transport, forming a cycle whereby continual exchange of protons for cations such as Na + , K + and Ca 2+ outcompetes ATP synthesis for the electrochemical gradient established via substrate oxidation (Bernardi ; Pastore et al ). Analyses of isolated mitochondria incubated in saline conditions showed that certain ions accumulate within the mitochondrion at concentrations far higher than by diffusion alone (Lorimer & Miller ; Pomeroy ). Furthermore, ion accumulation is dependent upon the presence of respiratory substrates, but is not dependent upon ATP hydrolysis.…”

Section: Introductionmentioning

confidence: 99%

Analysis of the sodium chloride‐dependent respiratory kinetics of wheat mitochondria reveals differential effects on phosphorylating and non‐phosphorylating electron transport pathways

Jacoby

Che-Othman

Millar

et al. 2015

Plant Cell & Environment

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A number of previous studies have documented the gross response of mitochondrial respiration to salinity treatment, but it is unclear how NaCl directly affects the kinetics of plant phosphorylating and non-phosphorylating electron transport pathways. This study investigates the direct effects of NaCl upon different respiratory pathways in wheat, by measuring rates of isolated mitochondrial oxygen consumption across different substrate oxidation pathways in saline media. We also profile the abundance of respiratory proteins by using targeted selected reaction monitoring (SRM) mass spectrometry of mitochondria isolated from control and salt-treated wheat plants. We show that all pathways of electron transport were inhibited by NaCl concentrations above 400 mM; however electron transfer chains showed divergent responses to NaCl concentrations between 0 and 200 mM. Stimulation of oxygen consumption was measured in response to NaCl in scenarios where exogenous NADH was provided as substrate and electron flow was coupled to the generation of a proton gradient across the inner membrane. Protein abundance measurements show that several enzymes with activities less affected by NaCl are induced by salinity, whereas enzymes with activities inhibited by NaCl are depleted. These data deepen our understanding of how plant respiration responds to NaCl, offering new mechanistic explanations for the divergent salinity responses of whole-plant respiratory rate in the literature.

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Membrane Transport Systems of Plant Mitochondria

Hanson¹

1985

Higher Plant Cell Respiration

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Swelling and Contraction of Mitochondria from Cold-hardened and Nonhardened Wheat and Rye Seedlings

Cited by 12 publications

References 19 publications

Effect of Abscisic Acid on Root Hydraulic Conductivity

Effect of Abscisic Acid on Root Hydraulic Conductivity

Analysis of the sodium chloride‐dependent respiratory kinetics of wheat mitochondria reveals differential effects on phosphorylating and non‐phosphorylating electron transport pathways

Membrane Transport Systems of Plant Mitochondria

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