Abscisic Acid Raises the Permeability of Plant Cells to Water

Glinka, Z.; Reinhold, Leonora

doi:10.1104/pp.48.1.103

Cited by 116 publications

(43 citation statements)

References 6 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…and wilting has obvious economic potential, as already mentioned by Jones and Mansfield (1970). Although many compounds that reduce transpiration are already known, the finding that ABA increases root exudation (Tal and Imber 1971), chloride accumulation (Mizrahi and Richmond, unpublished data), and the permeability of plant tissues to water (Glinka and Reinhold 1971) suggests a more complex mode of action than merely that of an antitranspirant. In addition, commercial utilization of ABA to improve water balance of water-stressed plants seems advantageous in that ABA is an endogenous material with a high turnover (Milborrow 1969;Milborrow and Nodle 1970), thereby diminishing problems of residual toxicity and deleterious metabolic side effects.…”

Section: ·2 0·4 2·04·0mentioning

confidence: 91%

“…Cytokinins increase transpiration by effecting stomatal opening (Livne and Vaadia 1965;Meidner 1967;Luke and Freeman 1968), and abscisic acid (ABA) effects closure of stomata and consequent reduction of transpiration (Little and Eidt 1968;Mittelheuser and Van Steveninck 1969;Jones and Mansfield 1970;Mizrahi, Blumenfeld, and Richmond 1970), as well as enhancement of root exudation (Tal and Imber 1971). It was also reported recently that ABA increases the permeability of plant tissues to water (Glinka and Reinhold 1971). In addition, work on a wilty tomato mutant has shown that the impairment of the closure of its stomata may be corrected by treatment with ABA (Imber and Tal 1970).…”

Section: Introductionmentioning

confidence: 98%

See 1 more Smart Citation

Hormonal Modification of Plant Response to Water Stress

Mizrahi¹,

Richmond²

1972

Aust. Jnl. Of Bio. Sci.

View full text Add to dashboard Cite

Addition of either kinetin or abscisic acid (ABA) to the root medium of tobacco plants grown in culture solution greatly modified their response to different types of root stresses that were applied 48 hr after the addition of the hormones.All the stresses employed impaired the water balance of the plants as evidenced by a decline of shoot turgor. The stresses consisted of cessation in root aeration, reduction of root temperature, and decrease in the osmotic potential of the root media by addition of either N aCl or mannitol.Response of plants to a stress was estimated by measuring the water saturation deficit (W.S.D.) in the leaves 3 hr after the stress started. Pretreatment with kinetin resulted in an increased W.S.D. in the leaves whereas pretreatment with ABA, with the exception of the 3-hr saline stress, effected decreased W.S.D. in comparison with the appropriate controls.A possible explanation of this phenomenon and its practical applications are discussed.

show abstract

Section: ·2 0·4 2·04·0mentioning

confidence: 91%

Section: Introductionmentioning

confidence: 98%

Hormonal Modification of Plant Response to Water Stress

Mizrahi¹,

Richmond²

1972

Aust. Jnl. Of Bio. Sci.

View full text Add to dashboard Cite

show abstract

“…Exogenously applied as well as endogenously produced ABA hardened plants to exposure to low temperatures (18,19). ABA is known to cause stomatal closure (16,20) and has been reported to alter root permeability to water (5,(7)(8)(9)13). In experiments where ABA is added to the irrigation water (18), it is often unclear whether the hormone acts on the root or is transported to the shoot and directly effects the stomata.…”

Section: Introductionmentioning

confidence: 99%

Penetration of Soybean Root Systems by Abscisic Acid Isomers

Markhart¹

1982

Plant Physiol.

View full text Add to dashboard Cite

The penetration of soybean (Glycine max L. cv. Ransom) root systems by exogenously applied isomers of abscisic acid was monitored by measuring the concentration of the chemical in the xylem exudate of root systems exposed to a three bar hydrostatic pressure difference. The cis-trans isomer penetrated more readily than the trans-trans isomer, however, up to 6 hours was needed to reach steady-state values. Exogenous abscisic acid also decreased volume flux through the root system and increased total carbon dioxide efflux from the vessel containing the root system.Recent evidence indicates an important role of ABA2 in plant resistance to environmental stress (13, 19). Exogenously applied as well as endogenously produced ABA hardened plants to exposure to low temperatures (18,19). ABA is known to cause stomatal closure (16,20) and has been reported to alter root permeability to water (5,(7)(8)(9)13). In experiments where ABA is added to the irrigation water (18), it is often unclear whether the hormone acts on the root or is transported to the shoot and directly effects the stomata.Despite the potential importance of exogenously applied plant growth regulators, there is a paucity of information on the uptake and transport of hormones to sites of action. The experiments presented here investigate the penetration of soybean root systems by ABA geometric isomers. This information is essential to understanding the mechanism of action of ABA and to the future use of exogenous ABA to ameleorate plant damage due to environmental stress. Additionally, a convenient accurate method of general use for measuring the transport of these compounds through root systems is described. MATERIALS AND METHODSSoybean (Glycine max L. cv. Ransom) plants were grown hydroponically in 3-L plastic pots containing half-strength Hoagland solution for 20 to 40 days in controlled environment chambers at the Duke University Phytotron as described previously (14 Twenty 1d aliquots were analyzed directly with an Altex Model 310 high performance liquid chromatograph with a UV (254 nm) detector for the presence of ABA. Separation of the two geometric isomers was achieved with a solvent system of methanol:H20: acetic acid (40:60: 1), a LiChrosorb RP-18 column, and a flow rate of 1 ml/min. Standard curves of peak height versus concentration were linear between 10-6 and l0-4 M and were used to determine exudate ABA concentration. The ABA concentration of the ambient solution was also monitored during the experiment. The exudate ABA concentration expressed as a fraction of the ambient concentration was used as a relative measure of the penetration of the isomers.Exudation Rates. Exudation rates were measured as the volume of exudate flowing from the cut stem per unit time. Rates are expressed on a whole root basis.Respiration. Root respiration was monitored by measuring the CO2 concentration of the gas passing through the pressure vessel with an IR gas analyzer operated in the absolute mode. Rates were expressed as a percent of the rate at the time...

show abstract

“…Water uptake during the imbibition period (up to about 8 h after sowing) is not influenced by ABA. It thus seems unlikely that ABA acts in germination by impairing the water permeability of membranes (8). It rather appears appropriate to discuss the action of ABA in terms of the water potential equation (Iw = IP + I, + I').…”

mentioning

confidence: 99%

Control of Seed Germination by Abscisic Acid

Schöpfer¹,

Bajracharya²,

Plachy³

1979

Plant Physiol.

View full text Add to dashboard Cite

The germination process of mustard seeds (Simapis alba L.) has been characterized by the time courses of water uptake, rupturing of the seed coat (12 hours after sowing), onset of axis growth (18 hours after sowing), and the point of no return, where the seeds lose the ability to survive redesiccation (12 to 24 hours after sowing, depending on embryo part). Abscisic acid (ABA) reversibly arrests embryo development at the brink of radicle growth initiation, inhibiting the water uptake which accompanies embryo growth. Seeds which have been kept dormant by ABA for several days will, after removal of the hormone, rapidly take up water and continue the germination process. Seeds which have been preincubated in water lose the sensitivity to be arrested by ABA after about 12 hours after sowing. This escape from ABA-mediated dormancy is not due to an inactivation of the hormone but to a loss of competence to respond to ABA during the course of germination. The sensitivity to ABA can be restored in these seeds by redrying. It is concluded that a primary action of ABA in inhibiting seed germination is the control of water uptake of the embryo tissues rather than the control of DNA, RNA, or protein syntheses.When a quiescent, nondormant seed (13) is supplied with water and 02 at favorable temperatures the embryo rapidly takes up water and continues its temporarily suspended development. After building up a certain threshold hydrostatic pressure the seed coat is ruptured and visible protrusion of the elongating radicle indicates the onset of elongation of the embryonic axis. Some time later the release from quiescence becomes irreversible, ie. the embryo will no longer survive redesiccation. The developmental period from the increase of metabolic activity after imbibition up to this point of no return, logically separating the embryo from the seedling stage, can be referred to as germination. At 25 C germination lasts not more than about 1 day in many seeds.The dormancy hormone ABA can inhibit continuation of embryo development during germination and related developmental processes (e.g. the growth of Lemna turions or tree buds, 19, 20).Exogenously applied ABA is rapidly taken up by the embryo even through the intact seed coat (3,16 It has been shown that fundamental processes such as cell division and the synthesis of DNA, RNA, and protein become inhibited in plant systems treated with ABA (6,10, 11,19,21). In barley aleurone tissue and cotton embryos exogenous ABA prevents the formation of enzymes which are involved in mobilizing storage materials during germination (5, 12). Although the molecular nature of the physiological block, by which ABA prevents the completion of germination, is still unknown, it is generally believed that ABA functions by interfering with mRNA synthesis, processing, or translation (e.g. 5-7, 10, 11, 24). In a previous study with mustard (1) we have observed that seedling development is surprisingly insensitive to ABA if the hormone is applied after germination. In particular it has been e...

show abstract

Abscisic Acid Raises the Permeability of Plant Cells to Water

Cited by 116 publications

References 6 publications

Hormonal Modification of Plant Response to Water Stress

Hormonal Modification of Plant Response to Water Stress

Penetration of Soybean Root Systems by Abscisic Acid Isomers

Control of Seed Germination by Abscisic Acid

Contact Info

Product

Resources

About