Evaluation of the Morpho-Physiological, Biochemical and Molecular Responses of Contrasting Medicago truncatula Lines under Water Deficit Stress (original) (raw)
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International Journal of Molecular Sciences, 2021
Water-deficit stresses such as drought and salinity are the most important factors limiting crop productivity. Hence, understanding the plant responses to these stresses is key for the improvement of their tolerance and yield. In this study M. truncatula plants were subjected to 250 mM NaCl as well as reduced irrigation (No-W) and 250 g/L polyethylene glycol (PEG)-6000 to induce salinity and drought stress, respectively, provoking a drop to −1.7 MPa in leaf water potential. The whole plant physiology and metabolism was explored by characterizing the stress responses at root, phloem sap and leaf organ level. PEG treatment led to some typical responses of plants to drought stress, but in addition to PEG uptake, an important impairment of nutrient uptake and a different regulation of carbon metabolism could be observed compared to No-W plants. No-W plants showed an important redistribution of antioxidants and assimilates to the root tissue, with a distinctive increase in root proline d...
Agronomy, 2019
Medicago sativa L. is a tetraploid perennial forage legume of great agronomical interest. The increasing need for its use under water-deficit conditions as well as low-input systems demands further improvement of its drought tolerance. On the other hand, Medicagoarborea L. is a perennial leguminous shrub, which is knownas a drought-tolerant species. In the present study, drought stress responses of the aforementioned medicago species, along with their hybrid, named Alborea, were comparatively assayed at the morphological, physiological, biochemical, and transcriptional levels. In particular, transcript abundance of representative genes that: (a) control ion transport, intracellular Na+/H+ antiporters(NHX1) and rare cold inducible2A (RCI2A); (b) have an osmotic function Δ1-pyrroline-5-carboxylate synthetase 1 (P5CS1); and (c) participate in signaling pathways and control cell growth and leaf function stress-induced mitogen-activated protein kinases kinases (SIMKK), Zinc Finger (ZFN),...
Physiological responses of the legume model Medicago truncatula cv. Jemalong to water deficit
Environmental and Experimental Botany, 2008
In Medicago truncatula Gaertn. cv. Jemalong plants some mechanisms involved in drought resistance were analysed in response to a progressive water deficit imposed by suppression of soil irrigation. Withholding water supply until the soil had reached one-half of its maximum water content had no significant effect on leaf RWC, gas exchanges or chlorophyll fluorescence parameters. Under severe drought conditions, the plants resistance to water shortage involved mainly drought avoidance mechanisms through a decrease in stomatal conductance. The consequent decrease in the internal CO 2 concentration (C i ) should have limited the net CO 2 fixation (A). Since A decreased slightly more than C i under severe water deficit, non-stomatal limitations of photosynthesis may have also occurred. Analysis of A/C i curves showed reduced carboxylation efficiency due to limitations in RuBP regeneration and Rubisco activity, confirming the presence of non-stomatal limitations of photosynthesis. Drought tolerance mechanisms involving osmotic adjustment and an increase in cell membrane integrity were also present. Altogether, these mechanisms allowed M. truncatula cv. Jemalong plants to still maintain a quite elevated level of net CO 2 fixation rate under severe water deficit conditions. These results may contribute to identify useful physiological traits for breeding programs concerning drought adaptation in legumes.
Physiological responses of the legume model< i> Medicago truncatula cv. Jemalong to water deficit
Environmental and …, 2008
In Medicago truncatula Gaertn. cv. Jemalong plants some mechanisms involved in drought resistance were analysed in response to a progressive water deficit imposed by suppression of soil irrigation. Withholding water supply until the soil had reached one-half of its maximum water content had no significant effect on leaf RWC, gas exchanges or chlorophyll fluorescence parameters. Under severe drought conditions, the plants resistance to water shortage involved mainly drought avoidance mechanisms through a decrease in stomatal conductance. The consequent decrease in the internal CO 2 concentration (C i ) should have limited the net CO 2 fixation (A). Since A decreased slightly more than C i under severe water deficit, non-stomatal limitations of photosynthesis may have also occurred. Analysis of A/C i curves showed reduced carboxylation efficiency due to limitations in RuBP regeneration and Rubisco activity, confirming the presence of non-stomatal limitations of photosynthesis. Drought tolerance mechanisms involving osmotic adjustment and an increase in cell membrane integrity were also present. Altogether, these mechanisms allowed M. truncatula cv. Jemalong plants to still maintain a quite elevated level of net CO 2 fixation rate under severe water deficit conditions. These results may contribute to identify useful physiological traits for breeding programs concerning drought adaptation in legumes.
Journal of Proteome Research, 2015
Legume crops present important agronomical and environmental advantages mainly due to their capacity to reduce atmospheric N 2 to ammonium via symbiotic nitrogen fixation (SNF). This process is very sensitive to abiotic stresses such as drought, but the mechanism underlying this response is not fully understood. The goal of the current work is to compare the drought response of two legumes with high economic impact and research importance, Medicago truncatula and Glycine max, by characterizing their root nodule proteomes. Our results show that, although M. truncatula exhibits lower water potential values under drought conditions compared to G. max, SNF declined analogously in the two legumes. Both of their nodule proteomes are very similar, and comparable down-regulation responses in the diverse protein functional groups were identified (mainly proteins related to the metabolism of carbon, nitrogen, and sulfur). We suggest lipoxygenases and protein turnover as newly recognized players in SNF regulation. Partial drought conditions applied to a split-root system resulted in the local down-regulation of the entire proteome of drought-stressed nodules in both legumes. The high degree of similarity between both legume proteomes suggests that the vast amount of research conducted on M. truncatula could be applied to economically important legume crops, such as soybean.
In the conditions of changing climate, plants are continuously subject to several biotic and abiotic stresses. Among these stresses, drought is one of the most severe abiotic stress which threats crops production and yield. Crops demonstrate various morphological, physiological, biochemical and molecular responses under water stress. This review describes some aspects of drought induced changes in morphological, physiological, biochemical and molecular changes in plants. Drought triggers a wide variety of plant responses, ranging from cellular metabolism to changes in growth development including roots, shoots and final yield. Moreover, understanding the biochemical and molecular responses to drought is essential for perception of plant resistance mechanisms to water-limited conditions. The sections of this review deal with plant responses including root growth, transpiration, photosynthesis, phenotypical flexibility, accumulation of solutes and expression of some genes and proteins for improving the tolerance to the drought stress.
Crop and Pasture Science, 2013
The response patterns during water deficit stress and subsequent recovery of two forage species, Medicago truncatula and Sulla carnosa, were studied. After germination and pre-treatment, seedlings were individually cultivated for two months under two irrigation modes: 100% and 33% of field capacity. Measured parameters were plant growth, water relations, leaf osmotic potential, lipid peroxidation, and leaf inorganic (Na + and K + ) and organic (proline and soluble sugars) solute contents, as well as delta-1-pyrroline-5-carboxylate synthase (P5CS) and proline dehydrogenase (PDH) activities. Our results showed that under control conditions, and in contrast to roots, no significant differences were observed in shoot biomass production between the two species. However, when subjected to water-deficit stress, M. truncatula appeared to be more tolerant than S. carnosa (reduction by 50 and 70%, respectively). In the two studied species, water-deficit stress led to an increase in root/shoot ratio and leaf proline and soluble sugar contents, and a decrease in leaf osmotic potential. Enzymatic assay revealed that in the two species, P5CS activity was stimulated whereas that of PDH was inhibited under stress conditions. Despite greater accumulation of proline, sugar, and potassium in leaves of S. carnosa, M. truncatula was more tolerant to water deficit. This was essentially due to its capacity to control tissue hydration and water-use efficiency, in addition to its greater ability to protect membrane integrity. Following stress relief, M. truncatula and S. carnosa showed partial re-establishment of growth capacity.