Your search keyword '"Vadez V"' showing total 19 results

1. Transpiration efficiency variations in the pearl millet reference collection PMiGAP.

Author

Grégoire L, Kholova J, Srivastava R, Hash CT, Vigouroux Y, and Vadez V

Subjects

Droughts, Water metabolism, Biomass, Plant Breeding methods, Genetic Variation, Pennisetum genetics, Pennisetum physiology, Pennisetum growth & development, Plant Transpiration physiology, Genotype

Abstract

Transpiration efficiency (TE), the biomass produced per unit of water transpired, is a key trait for crop performance under limited water. As water becomes scarce, increasing TE would contribute to increase crop drought tolerance. This study is a first step to explore pearl millet genotypic variability for TE on a large and representative diversity panel. We analyzed TE on 537 pearl millet genotypes, including inbred lines, test-cross hybrids, and hybrids bred for different agroecological zones. Three lysimeter trials were conducted in 2012, 2013 and 2015, to assess TE both under well-watered and terminal-water stress conditions. We recorded grain yield to assess its relationship with TE. Up to two-fold variation for TE was observed over the accessions used. Mean TE varied between inbred and testcross hybrids, across years and was slightly higher under water stress. TE also differed among hybrids developed for three agroecological zones, being higher in hybrids bred for the wetter zone, underlining the importance of selecting germplasm according to the target area. Environmental conditions triggered large Genotype x Environment (GxE) interactions, although TE showed some high heritability. Transpiration efficiency was the second contributor to grain yield after harvest index, highlighting the importance of integrating it into pearl millet breeding programs. Future research on TE in pearl millet should focus (i) on investigating the causes of its plasticity i.e. the GxE interaction (ii) on studying its genetic basis and its association with other important physiological traits., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Grégoire et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

2. Transpiration efficiency: insights from comparisons of C4 cereal species.

Author

Vadez V, Choudhary S, Kholová J, Hash CT, Srivastava R, Kumar AA, Prandavada A, and Anjaiah M

Subjects

Edible Grain, Plant Breeding, Vapor Pressure, Pennisetum, Plant Transpiration

Abstract

We have previously reported that there is a tight link between high transpiration efficiency (TE; shoot biomass per unit water transpired) and restriction of transpiration under high vapor pressure deficit (VPD). In this study, we examine other factors affecting TE among major C4 cereals, namely species' differences, soil type, and source-sink relationships. We found that TE in maize (10 genotypes) was higher overall than in pearl millet (10 genotypes), and somewhat higher than in sorghum (16 genotypes). Overall, transpiration efficiency was higher in high-clay than in sandy soil under high VPD, but the effect was species-dependent with maize showing large variations in TE and yield across different soil types whilst pearl millet showed no variation in TE. This suggested that species fitness was specific to soil type. Removal of cobs drastically decreased TE in maize under high VPD, but removal of panicles did not have the same effect in pearl millet, suggesting that source-sink balance also drove variations in TE. We interpret the differences in TE between species as being accounted for by differences in the capacity to restrict transpiration under high VPD, with breeding history possibly having favored the source-sink balance in maize. This suggests that there is also scope to increase TE in pearl millet and sorghum through breeding. With regards to soil conditions, our results indicate that it appears to be critical to consider hydraulic characteristics and the root system together in order to better understand stomatal regulation and restriction of transpiration under high VPD. Finally, our results highlight the importance of sink strength in regulating transpiration/photosynthesis, and hence in influencing TE., (© The Author(s) 2021. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2021

3. Transpiration difference under high evaporative demand in chickpea (Cicer arietinum L.) may be explained by differences in the water transport pathway in the root cylinder.

Author

Sivasakthi K, Tharanya M, Zaman-Allah M, Kholová J, Thirunalasundari T, and Vadez V

Subjects

Droughts, Vapor Pressure, Cicer physiology, Plant Roots physiology, Plant Transpiration physiology, Water metabolism

Abstract

Terminal drought substantially reduces chickpea yield. Reducing water use at vegetative stage by reducing transpiration under high vapor pressure deficit (VPD), i.e. under dry/hot conditions, contributes to drought adaptation. We hypothesized that this trait could relate to differences in a genotype's dependence on root water transport pathways and hydraulics. Transpiration rate responses in conservative and profligate chickpea genotypes were evaluated under increasing VPD in the presence/absence of apoplastic and cell-to-cell transport inhibitors. Conservative genotypes ICC 4958 and ICC 8058 restricted transpiration under high VPD compared to the profligate genotypes ICC 14799 and ICC 867. Profligate genotypes were more affected by aquaporin inhibition of the cell-to-cell pathway than conservative genotypes, as measured by the root hydraulic conductance and transpiration under high VPD. Aquaporin inhibitor treatment also led to a larger reduction in root hydraulic conductivity in profligate than in conservative genotypes. In contrast, blockage of the apoplastic pathway in roots decreased transpiration more in conservative than in profligate genotypes. Interestingly, conservative genotypes had high early vigour, whereas profligate genotypes had low early vigour. In conclusion, profligate genotypes depend more on the cell-to-cell pathway, which might explain their higher root hydraulic conductivity, whereas water-saving by restricting transpiration led to higher dependence on the apoplastic pathway. This opens the possibility to screen for conservative or profligate chickpea phenotypes using inhibitors, itself opening to the search of the genetic basis of these differences., (© 2020 German Society for Plant Sciences and The Royal Botanical Society of the Netherlands.)

Published

2020

4. Molecular cloning and expression analysis of Aquaporin genes in pearl millet [Pennisetum glaucum (L) R. Br.] genotypes contrasting in their transpiration response to high vapour pressure deficits.

Author

Reddy PS, Tharanya M, Sivasakthi K, Srikanth M, Hash CT, Kholova J, Sharma KK, and Vadez V

Subjects

Amino Acid Sequence, Aquaporins chemistry, Aquaporins metabolism, Base Sequence, Circadian Rhythm, Cloning, Molecular, Gene Expression Profiling, Genotype, Pennisetum genetics, Phylogeny, Plant Leaves physiology, Plant Proteins chemistry, Plant Proteins metabolism, Plant Roots physiology, Sequence Alignment, Vapor Pressure, Aquaporins genetics, Pennisetum physiology, Plant Proteins genetics, Plant Transpiration

Abstract

Pearl millet is a crop of the semi-arid tropics having high degree of genetic diversity and variable tolerance to drought stress. To investigate drought tolerance mechanism that possibly accounts for differences in drought tolerance, four recombinant inbred lines from a high resolution cross (HRC) were selected for variability in their transpiration rate (Tr) response to vapour pressure deficit (VPD) conditions. The differential Tr response of the genotypes to increased VPD conditions was used to classify the genotypes as sensitive or insensitive to high VPD. Aquaporin (AQP) genes PgPIP1;1, PgPIP1;2, PgPIP2;1, PgPIP2;3, PgPIP2;6, PgTIP1;1 and PgTIP2;2 were cloned. Phylogenetic analysis revealed that the cloned PgAQPs were evolutionarily closer to maize AQPs than to rice. PgAQP genes, including PgPIP1;1 and PgPIP2;6 in root tissue showed a significant expression pattern with higher expression in VPD-insensitive genotypes than VPD-sensitive genotypes under low VPD conditions (1.2kPa) i.e when there is no high evaporative demand from the atmosphere. PgAQP genes (PgPIP2;1 in leaf and root tissues; PgPIP1;2 and PgTIP2;2 in leaf and PgPIP2;6 in root) followed a diurnal rhythm in leaves and roots that have either higher or lower expression levels at different time intervals. Under high VPD conditions (4.21kPa), PgPIP2;3 showed higher transcript abundance in VPD-insensitive genotypes, and PgPIP2;1 in VPD-sensitive genotypes, while rest of the PgAQPs showed differential expression. Our current hypothesis is that these differences in the expression of AQP genes under different VPDs suggests a role of the AQPs in tuning the water transport pathways with variation between genotypes., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2017

5. Limited-transpiration response to high vapor pressure deficit in crop species.

Author

Sinclair TR, Devi J, Shekoofa A, Choudhary S, Sadok W, Vadez V, Riar M, and Rufty T

Subjects

Aquaporins genetics, Aquaporins metabolism, Droughts, Plant Leaves metabolism, Plant Leaves physiology, Plant Transpiration genetics, Plant Transpiration physiology, Vapor Pressure

Abstract

Water deficit under nearly all field conditions is the major constraint on plant yields. Other than empirical observations, very little progress has been made in developing crop plants in which specific physiological traits for drought are expressed. As a consequence, there was little known about under what conditions and to what extent drought impacts crop yield. However, there has been rapid progress in recent years in understanding and developing a limited-transpiration trait under elevated atmospheric vapor pressure deficit to increase plant growth and yield under water-deficit conditions. This review paper examines the physiological basis for the limited-transpiration trait as result of low plant hydraulic conductivity, which appears to be related to aquaporin activity. Methodology was developed based on aquaporin involvement to identify candidate genotypes for drought tolerance of several major crop species. Cultivars of maize and soybean are now being marketed specifically for arid conditions. Understanding the mechanism of the limited-transpiration trait has allowed a geospatial analyses to define the environments in which increased yield responses can be expected. This review highlights the challenges and approaches to finally develop physiological traits contributing directly to plant improvement for water-limited environments., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2017

6. DREB1A overexpression in transgenic chickpea alters key traits influencing plant water budget across water regimes.

Author

Anbazhagan K, Bhatnagar-Mathur P, Vadez V, Dumbala SR, Kishor PB, and Sharma KK

Subjects

Arabidopsis genetics, Arabidopsis Proteins metabolism, Biomass, Cicer physiology, Dehydration, Droughts, Gene Expression, Phenotype, Plant Proteins genetics, Plant Proteins metabolism, Plant Roots genetics, Plant Roots physiology, Plant Shoots genetics, Plant Shoots physiology, Plant Stomata genetics, Plant Stomata physiology, Plants, Genetically Modified, Promoter Regions, Genetic genetics, Soil chemistry, Transcription Factors metabolism, Transgenes, Arabidopsis Proteins genetics, Cicer genetics, Plant Transpiration physiology, Transcription Factors genetics, Water metabolism

Abstract

Key Message: We demonstrate the role of DREB1A transcription factor in better root and shoot partitioning and higher transpiration efficiency in transgenic chickpea under drought stress Chickpea (Cicer arietinum L.) is mostly exposed to terminal drought stress which adversely influences its yield. Development of cultivars for suitable drought environments can offer sustainable solutions. We genetically engineered a desi-type chickpea variety to ectopically overexpress AtDREB1A, a transcription factor known to be involved in abiotic stress response, driven by the stress-inducible Atrd29A promoter. From several transgenic events of chickpea developed by Agrobacterium-mediated genetic transformation, four single copy events (RD2, RD7, RD9 and RD10) were characterized for DREB1A gene overexpression and evaluated under water stress in a biosafety greenhouse at T6 generation. Under progressive water stress, all transgenic events showed increased DREB1A gene expression before 50 % of soil moisture was lost (50 % FTSW or fraction of transpirable soil water), with a faster DREB1A transcript accumulation in RD2 at 85 % FTSW. Compared to the untransformed control, RD2 reduced its transpiration in drier soil and higher vapor pressure deficit (VPD) range (2.0-3.4 kPa). The assessment of terminal water stress response using lysimetric system that closely mimics the soil conditions in the field, showed that transgenic events RD7 and RD10 had increased biomass partitioning into shoot, denser rooting in deeper layers of soil profile and higher transpiration efficiency than the untransformed control. Also, RD9 with deeper roots and RD10 with higher root diameter showed that the transgenic events had altered rooting pattern compared to the untransformed control. These results indicate the implicit influence of rd29A::DREB1A on mechanisms underlying water uptake, stomatal response, transpiration efficiency and rooting architecture in water-stressed plants.

Published

2015

7. Transpiration efficiency: new insights into an old story.

Author

Vadez V, Kholova J, Medina S, Kakkera A, and Anderberg H

Subjects

Crops, Agricultural physiology, Plant Transpiration, Water physiology

Abstract

Producing more food per unit of water has never been as important as it is at present, and the demand for water by economic sectors other than agriculture will necessarily put a great deal of pressure on a dwindling resource, leading to a call for increases in the productivity of water in agriculture. This topic has been given high priority in the research agenda for the last 30 years, but with the exception of a few specific cases, such as water-use-efficient wheat in Australia, breeding crops for water-use efficiency has yet to be accomplished. Here, we review the efforts to harness transpiration efficiency (TE); that is, the genetic component of water-use efficiency. As TE is difficult to measure, especially in the field, evaluations of TE have relied mostly on surrogate traits, although this has most likely resulted in over-dependence on the surrogates. A new lysimetric method for assessing TE gravimetrically throughout the entire cropping cycle has revealed high genetic variation in different cereals and legumes. Across species, water regimes, and a wide range of genotypes, this method has clearly established an absence of relationships between TE and total water use, which dismisses previous claims that high TE may lead to a lower production potential. More excitingly, a tight link has been found between these large differences in TE in several crops and attributes of plants that make them restrict water losses under high vapour-pressure deficits. This trait provides new insight into the genetics of TE, especially from the perspective of plant hydraulics, probably with close involvement of aquaporins, and opens new possibilities for achieving genetic gains via breeding focused on this trait. Last but not least, small amounts of water used in specific periods of the crop cycle, such as during grain filling, may be critical. We assessed the efficiency of water use at these critical stages., (© The Author 2014. Published by Oxford University Press on behalf of the Society for Experimental Biology. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2014

8. Restriction of transpiration rate under high vapour pressure deficit and non-limiting water conditions is important for terminal drought tolerance in cowpea.

Author

Belko N, Zaman-Allah M, Diop NN, Cisse N, Zombre G, Ehlers JD, and Vadez V

Subjects

Environment, Fabaceae genetics, Fabaceae metabolism, Genetic Variation, Genotype, Linear Models, Plant Leaves growth & development, Plant Leaves metabolism, Plant Roots growth & development, Plant Roots metabolism, Species Specificity, Stress, Physiological, Temperature, Time Factors, Adaptation, Physiological, Droughts, Fabaceae growth & development, Plant Transpiration, Vapor Pressure, Water metabolism

Abstract

Drought stress is a major constraint on cowpea productivity, since the crop is grown under warm conditions on sandy soils having low water-holding capacity. For enhanced performance of crops facing terminal drought stress, like cowpea, water-saving strategies are crucial. In this work, the growth and transpiration rate (TR) of 40 cowpea genotypes with contrasting response to terminal drought were measured under well-watered conditions across different vapour pressure deficits (VPD) to investigate whether tolerant and sensitive genotypes differ in their control of leaf water loss. A method is presented to indirectly assess TR through canopy temperature (CT) and the index of canopy conductance (Ig). Overall, plants developed larger leaf area under low than under high VPD, and there was a consistent trend of lower plant biomass in tolerant genotypes. Substantial differences were recorded among genotypes in TR response to VPD, with tolerant genotypes having significantly lower TR than sensitive ones, especially at times with the highest VPD. Genotypes differed in TR response to increasing VPD, with some tolerant genotypes exhibiting a clear VPD breakpoint at about 2.25 kPa, above which there was very little increase in TR. In contrast, sensitive genotypes presented a linear increase in TR as VPD increased, and the same pattern was found in some tolerant lines, but with a smaller slope. CT, estimated with thermal imagery, correlated well with TR and Ig and could therefore be used as proxy for TR. These results indicate that control of water loss discriminated between tolerant and sensitive genotypes and may, therefore, be a reliable indicator of terminal drought stress tolerance. The water-saving characteristics of some genotypes are hypothesised to leave more soil water for pod filling, which is crucial for terminal drought adaptation., (© 2012 German Botanical Society and The Royal Botanical Society of the Netherlands.)

Published

2013

9. DREB1A promotes root development in deep soil layers and increases water extraction under water stress in groundnut.

Author

Vadez V, Rao JS, Bhatnagar-Mathur P, and Sharma KK

Subjects

Arabidopsis genetics, Arachis genetics, Arachis growth & development, Biomass, Dehydration, Droughts, Genotype, Kinetics, Phenotype, Plant Roots genetics, Plant Roots growth & development, Plant Roots physiology, Plants, Genetically Modified, Promoter Regions, Genetic genetics, Soil, Time Factors, Adaptation, Physiological physiology, Arachis physiology, Plant Transpiration physiology, Water metabolism

Abstract

Water deficit is a major yield-limiting factor for many crops, and improving the root system has been proposed as a promising breeding strategy, although not in groundnut (Arachis hypogaea L.). The present work was carried out mainly to assess how root traits are influenced under water stress in groundnut, whether transgenics can alter root traits, and whether putative changes lead to water extraction differences. Several transgenic events, transformed with DREB1A driven by the rd29 promoter, along with wild-type JL24, were tested in a lysimeter system that mimics field conditions under both water stress (WS) and well-watered (WW) conditions. The WS treatment increased the maximum rooting depth, although the increase was limited to about 20% in JL24, compared to 50% in RD11. The root dry weight followed a similar trend. Consequently, the root dry weight and length density of transgenics was higher in layers below 100-cm depth (Exp. 1) and below 30 cm (Exp. 2). The root diameter was unchanged under WS treatment, except a slight increase in the 60-90-cm layer. The root diameter increased below 60 cm in both treatments. In the WW treatment, total water extraction of RD33 was higher than in JL24 and other transgenic events, and somewhat lower in RD11 than in JL24. In the WS treatment, water extraction of RD2, RD11 and RD33 was higher than in JL24. These water extraction differences were mostly apparent in the initial 21 days after treatment imposition and were well related to root length density in the 30-60-cm layer (R(2) = 0.68), but not to average root length density. In conclusion, water stress promotes rooting growth more strongly in transgenic events than in the wild type, especially in deep soil layers, and this leads to increased water extraction. This opens an avenue for tapping these characteristics toward the improvement of drought adaptation in deep soil conditions, and toward a better understanding of genes involved in rooting in groundnut., (© 2012 German Botanical Society and The Royal Botanical Society of the Netherlands.)

Published

2013

10. Terminal drought-tolerant pearl millet [Pennisetum glaucum (L.) R. Br.] have high leaf ABA and limit transpiration at high vapour pressure deficit.

Author

Kholová J, Hash CT, Kumar PL, Yadav RS, Kocová M, and Vadez V

Subjects

Abscisic Acid genetics, Gene Expression Regulation, Plant genetics, Gene Expression Regulation, Plant physiology, Pennisetum genetics, Plant Leaves genetics, Quantitative Trait Loci genetics, Quantitative Trait Loci physiology, Vapor Pressure, Abscisic Acid metabolism, Droughts, Pennisetum metabolism, Pennisetum physiology, Plant Leaves metabolism, Plant Leaves physiology, Plant Transpiration physiology

Abstract

It was previously shown that pearl millet genotypes carrying a terminal drought tolerance quantitative trait locus (QTL) had a lower transpiration rate (Tr; g cm(-2) d(-1)) under well-watered conditions than sensitive lines. Here experiments were carried out to test whether this relates to leaf abscisic acid (ABA) and Tr concentration at high vapour pressure deficit (VPD), and whether that leads to transpiration efficiency (TE) differences. These traits were measured in tolerant/sensitive pearl millet genotypes, including near-isogenic lines introgressed with a terminal drought tolerance QTL (NIL-QTLs). Most genotypic differences were found under well-watered conditions. ABA levels under well-watered conditions were higher in tolerant genotypes, including NIL-QTLs, than in sensitive genotypes, and ABA did not increase under water stress. Well-watered Tr was lower in tolerant than in sensitive genotypes at all VPD levels. Except for one line, Tr slowed down in tolerant lines above a breakpoint at 1.40-1.90 kPa, with the slope decreasing >50%, whereas sensitive lines showed no change in that Tr response across the whole VPD range. It is concluded that two water-saving (avoidance) mechanisms may operate under well-watered conditions in tolerant pearl millet: (i) a low Tr even at low VPD conditions, which may relate to leaf ABA; and (ii) a sensitivity to higher VPD that further restricts Tr, which suggests the involvement of hydraulic signals. Both traits, which did not lead to TE differences, could contribute to absolute water saving seen in part due to dry weight increase differences. This water saved would become critical for grain filling and deserves consideration in the breeding of terminal drought-tolerant lines.

Published

2010

11. Assessment of transpiration efficiency in peanut (Arachis hypogaea L.) under drought using a lysimetric system.

Author

Ratnakumar P, Vadez V, Nigam SN, and Krishnamurthy L

Subjects

Soil analysis, Arachis metabolism, Arachis physiology, Droughts, Plant Transpiration physiology

Abstract

Transpiration efficiency (TE) is an important trait for drought tolerance in peanut (Arachis hypogaea L.). The variation in TE was assessed gravimetrically using a long time interval in nine peanut genotypes (Chico, ICGS 44, ICGV 00350, ICGV 86015, ICGV 86031, ICGV 91114, JL 24, TAG 24 and TMV 2) grown in lysimeters under well-watered or drought conditions. Transpiration was measured by regularly weighing the lysimeters, in which the soil surface was mulched with a 2-cm layer of polythene beads. TE in the nine genotypes used varied from 1.4 to 2.9 g kg(-1) under well-watered and 1.7 to 2.9 g kg(-1) under drought conditions, showing consistent variation in TE among genotypes. A higher TE was found in ICGV 86031 in both well-watered and drought conditions and lower TE was found in TAG-24 under both water regimes. Although total water extraction differed little across genotypes, the pattern of water extraction from the soil profile varied among genotypes. High water extraction within 24 days following stress imposition was negatively related to pod yield (r(2) = 0.36), and negatively related to water extraction during a subsequent period of 32 days (r(2) = 0.73). By contrast, the latter, i.e. water extraction during a period corresponding to grain filling (24 to 56 days after flowering) was positively related to pod yield (r(2) = 0.36). TE was positively correlated with pod weight (r(2) = 0.30) under drought condition. Our data show that under an intermittent drought regime, TE and water extraction from the soil profile during a period corresponding to pod filling were the most important components.

Published

2009

12. Differential antioxidative responses in transgenic peanut bear no relationship to their superior transpiration efficiency under drought stress.

Author

Bhatnagar-Mathur P, Devi MJ, Vadez V, and Sharma KK

Subjects

Arabidopsis Proteins genetics, Arachis genetics, Ascorbate Peroxidases, Gene Expression Regulation, Plant genetics, Gene Expression Regulation, Plant physiology, Glutathione Reductase metabolism, Lipid Peroxidation physiology, Oxidative Stress physiology, Peroxidases metabolism, Plants, Genetically Modified genetics, Superoxide Dismutase metabolism, Transcription Factors genetics, Antioxidants metabolism, Arachis metabolism, Arachis physiology, Droughts, Plant Transpiration physiology, Plants, Genetically Modified metabolism, Plants, Genetically Modified physiology

Abstract

To counter the effects of environmental stresses, the plants must undergo detoxification that is crucial to avoid the accumulation of damaging free oxygen radicals (ROI). Here, we detail the oxidative damage, the antioxidant composition, and the osmoprotection achieved in transgenic plants of peanut overexpressing the AtDREB1A transgene, driven by a stress-inducible promoter (Atrd29A) when exposed to progressive water stress conditions. This study explored the biochemical mechanisms where (i) the antioxidants such as superoxide dismutase (SOD), ascorbate peroxidase (APOX), and glutathione reductase (GR) accumulated in the transgenic plants at comparably higher levels than their untransformed counterparts under dry soil conditions, (ii) a significant increase in the proline levels in the transgenic plants was observed in dry soils, and (iii) a dramatic increase in the lipid peroxidation in the untransformed controls in drier soils. Most of the biochemical parameters related to the antioxidative machinery in the tested peanut transgenics were triggered by the overexpression of AtDREB1A that appeared to differ from the untransformed controls. The antioxidants showed a negative correlation with the fraction of transpirable soil water (FTSW) thresholds, where the normalized transpiration rate (NTR) started decreasing in the tested plants. However, no significant relationship was observed between any of these biochemical indicators and the higher transpiration efficiency (TE) values found in the transgenic events. Our results show that changes in the antioxidative machinery in these transgenic peanut plants (overexpressing the AtDREB1A transcription factor) under water-limiting conditions played no causative role in improved TE.

Published

2009

13. Stress-inducible expression of At DREB1A in transgenic peanut (Arachis hypogaea L.) increases transpiration efficiency under water-limiting conditions.

Author

Bhatnagar-Mathur P, Devi MJ, Reddy DS, Lavanya M, Vadez V, Serraj R, Yamaguchi-Shinozaki K, and Sharma KK

Subjects

Arabidopsis Proteins physiology, Arachis physiology, Blotting, Southern, Disasters, Gene Expression Regulation, Plant, Models, Genetic, Phenotype, Plants, Genetically Modified physiology, Reverse Transcriptase Polymerase Chain Reaction, Transcription Factors physiology, Water metabolism, Arabidopsis Proteins genetics, Arachis genetics, Plant Transpiration physiology, Plants, Genetically Modified genetics, Transcription Factors genetics

Abstract

Water deficit is the major abiotic constraint affecting crop productivity in peanut (Arachis hypogaea L.). Water use efficiency under drought conditions is thought to be one of the most promising traits to improve and stabilize crop yields under intermittent water deficit. A transcription factor DREB1A from Arabidopsis thaliana, driven by the stress inducible promoter from the rd29A gene, was introduced in a drought-sensitive peanut cultivar JL 24 through Agrobacterium tumefaciens-mediated gene transfer. The stress inducible expression of DREB1A in these transgenic plants did not result in growth retardation or visible phenotypic alterations. T3 progeny of fourteen transgenic events were exposed to progressive soil drying in pot culture. The soil moisture threshold where their transpiration rate begins to decline relative to control well-watered (WW) plants and the number of days needed to deplete the soil water was used to rank the genotypes using the average linkage cluster analysis. Five diverse events were selected from the different clusters and further tested. All the selected transgenic events were able to maintain a transpiration rate equivalent to the WW control in soils dry enough to reduce transpiration rate in wild type JL 24. All transgenic events except one achieved higher transpiration efficiency (TE) under WW conditions and this appeared to be explained by a lower stomatal conductance. Under water limiting conditions, one of the selected transgenic events showed 40% higher TE than the untransformed control.

Published

2007

14. Variation in Drought-Tolerance Components and their Interrelationships in the Minicore Collection of Finger Millet Germplasm.

Author

Krishnamurthy, L., Upadhyaya, Hari D., Kashiwagi, J., Purushothaman, R., Dwivedi, Sangam L., and Vadez, V.

Subjects

DROUGHT tolerance, RAGI, PLANT germplasm, PLANT yields, PLANT transpiration

Abstract

Finger millet [Eleusine coracana (L.) Gaertn.] is an important and nutritious cereal cultivated largely in the tropics of Africa and Asia. It is adversely affected by intermittent droughts, and a trait-based selection for drought tolerance is expected to enhance yield stability. The current work has segregated the shoot biomass as total water use (T) and transpiration efficiency (TE) and assessed the importance of these components and their association with drought tolerance. A major part of the minicore collection of finger millet germplasm (n = 69) was evaluated in mini-lysimeters for the variation in T and TE under both terminal drought-stress (DS) and well-watered (WW) environments. Contribution of T to shoot biomass under drought was minor but that of TE was large and positive. Both T and TE positively influenced the shoot biomass production. Total water use explained the shoot biomass variation more when WW, whereas TE explained more variation under DS. Under DS, the minicore germplasm accessions varied in shoot biomass by 0.5-fold, T by 0.16- to 0.36-fold, and the TE by twofold. Categorization of the finger millet germplasm for TE differentiated accessions, into high and low groups, each with 11 accessions. No distinct or useful race or subrace-specific variation was found for T, TE, or the total shoot biomass productivity among the four races of finger millet. Selection and incorporation of both T and TE would enhance the efficient use of water and yield stability. [ABSTRACT FROM AUTHOR]

Published

2016

15. Quantitative trait loci associated with constitutive traits control water use in pearl millet [ Pennisetum glaucum (L.) R. Br.].

Author

Aparna, K., Nepolean, T., Srivastsava, R. K., Kholová, J., Rajaram, V., Kumar, S., Rekha, B., Senthilvel, S., Hash, C.T., Vadez, V., and Sparks, J.

Subjects

PEARL millet, PLANT water requirements, PLANT transpiration, QUANTITATIVE research, ALLELES in plants, PLANT genetics

Abstract

There is substantial genetic variation for drought adaption in pearl millet in terms of traits controlling plant water use. It is important to understand genomic regions responsible for these traits. Here, F7 recombinant inbred lines were used to identify quantitative trait loci ( QTL) and allelic interactions for traits affecting plant water use, and their relevance is discussed for crop productivity in water-limited environments. Four QTL contributed to increased transpiration rate under high vapour pressure deficit ( VPD) conditions, all with alleles from drought-sensitive parent ICMB 841. Of these four QTL, a major QTL (35.7%) was mapped on linkage group ( LG) 6. The alleles for 863B at this QTL decreased transpiration rate and this QTL co-mapped to a previously detected LG 6 QTL, with alleles from 863B for grain weight and panicle harvest index across severe terminal drought stress environments. This provided additional support for a link between water saving from a lower transpiration rate under high VPD and drought tolerance. 863B alleles in this same genomic region also increased shoot weight, leaf area and total transpiration under well-watered conditions. One unexpected outcome was reduced transpiration under high VPD (15%) from the interaction of two alleles for high VPD transpiration ( LG 6 (B), 40.7) and specific leaf mass and biomass ( LG 7 (A), 35.3), (A, allele from ICMB 841, B, allele from 863B, marker position). The LG 6 QTL appears to combine alleles for growth potential, beneficial for non-stress conditions, and for saving water under high evaporative demand, beneficial under stressful conditions. Mapping QTL for water-use traits, and assessing their interactions offers considerable potential for improving pearl millet adaptation to specific stress conditions through physiology-informed marker-assisted selection. [ABSTRACT FROM AUTHOR]

Published

2015

16. Seed Number and 100-Seed Weight of Pearl Millet ( Pennisetum glaucum L.) Respond Differently to Low Soil Moisture in Genotypes Contrasting for Drought Tolerance.

Author

Aparna, K., Hash, C. T., Yadav, R. S., and Vadez, V.

Subjects

SEEDS, PEARL millet, SOIL moisture, PLANT genetics, EFFECT of drought on plants, BIOMASS, PLANT transpiration

Abstract

Water stress after flowering, one of the major factors limiting yields of pearl millet, affects both seed setting and grain filling and is a consequence of more/less water used prior to anthesis. However, whether genotypes have different sensitivities for seed setting and filling under drought, if exposed to similar stress intensity, is unclear. Experiments were conducted in two pairs of pearl millet genotypes, that is, PRLT2/89-33 and H77/833-2, 863B and 841B, contrasting for terminal drought tolerance, and two genotypes, ICMR 01046 and ICMR 01029 ( IL- QTLs), introgressed with a terminal drought tolerance QTL from PRLT2/89-33 into H77/833-2. Total seed weight, panicle number, 100-seed weight, seed number and stover biomass were measured at different soil moistures and throughout grain filling. Sensitive H77/833-2 had higher seed number and yield under well-watered ( WW) conditions than in PRLT2/89-33 and IL- QTLs. Upon increases in water stress intensity, H77/833-2 suffered losses mostly in stover biomass (45 %) and seed number (60 %) at 0.3 FTSW whereas the biomass and seed number of PRLT2/89-33 decreased little (20 % and 25 %). The 100-seed weight of H77/833-2 decreased only 20 % under stress. Tolerant 863B also maintained a higher seed number and biomass under water stress than 841B. Grain filling duration in PRLT2/89-33 and IL- QTLs was similar to that of H77/833-2 under WW conditions but lasted longer than in H77833-2 under water stress ( WS). Similarly, seed growth of 863B was longer than 841B under WS. It is concluded that the higher seed yield of tolerant parents PRLT2/89-33 and 863B, and of IL- QTLs under WS was explained by the retention of a higher number of seeds than in sensitive lines, while the decrease in the 100-seed weight was proportionally less than the decrease in seed number. Phenotype with lesser number and larger size of panicles and larger grain size, like genotypes PRLT2/89-33 and 863B, withstood post-anthesis water stress better. IL- QTL inherited part of these characteristics, indicating a role for the terminal drought QTL in maintaining larger seed number and higher 100-seed weight. The continuous stover biomass increase under WW in H77/833-2, due to tillering, might indicate that tiller growth and grains are in competition for resources after anthesis, and this may relate to the relatively shorter grain-filling period. [ABSTRACT FROM AUTHOR]

Published

2014

17. Relationships Between Transpiration Efficiency and Its Surrogate Traits in the rd29A:DREB1A Transgenic Lines of Groundnut.

Author

Devi, M. J., Bhatnagar-Mathur, P., Sharma, K. K., Serraj, R., Anwar, S. Y., and Vadez, V.

Subjects

PEANUTS, PLANT transpiration, TRANSGENIC plants, DROUGHT-tolerant plants, CHLOROPHYLL, CARBON isotopes, SOIL moisture, STATISTICAL correlation

Published

2011

18. Groundnut (Arachis hypogaea) genotypes tolerant to intermittent drought maintain a high harvest index and have small leaf canopy under stress.

Author

Ratnakumar, P. and Vadez, V.

Subjects

*PEANUTS, *PLANT genetics, *EFFECT of stress on plants, *EFFECT of water levels on plants, *ROOT development, *PLANT transpiration, *PLANT reproduction

Abstract

Intermittent drought, which varies in intensity, severely limits groundnut (Arachis hypogaea L.) yields. Experiments were conducted to assess root development, water uptake, transpiration efficiency, yield components and their relationships, in 20 groundnut genotypes under well watered (WW), and mild (DS-1), medium (DS-2) and severe (DS-3) intermittent stress. Pod yield decreased 70%, 55% and 35% under severe, medium and mild stress, respectively. Pod yield varied among genotypes, and showed significant genotype-by-treatment effects. Root length density (RLD) varied among genotypes before and after stress, although RLD did not discriminate tolerant from sensitive lines. Total water uptake and RLD under water stress had a weakly significant relationship. Water extraction from the soil profile was highest under severe stress. Water uptake varied among genotypes in all water regimes, but correlated with pod yield under WW conditions. The relative harvest index (HI) (i.e. the ratio of the HI under stress to HI under WW conditions) was closely related to the pod yield in all three intermittent stresses (R² = 0.68 in DS-1; R² = 0.65 in DS-2; R² = 0.86 in DS-3) and was used as an index of stress tolerance. Under medium and severe stresses, the relative HI was negatively related to plant leaf weight (R² = 0.79 in DS-2; R² = 0.53 in DS-3), but less so under mild stress (R² = 0.31). The results suggest that under intermittent stress, genotypes with a lower leaf area may use water more sparingly during the drying cycle with less damaging consequences for reproduction and pod. [ABSTRACT FROM AUTHOR]

Published

2011

19. Peanut genotypic variation in transpiration efficiency and decreased transpiration during progressive soil drying

Author

Jyostna Devi, M., Sinclair, T.R., Vadez, V., and Krishnamurthy, L.

Subjects

*PEANUTS, *CROP genetics, *PLANT variation, *EFFECT of drought on plants, *PLANT transpiration, *PLANT-soil relationships, *SOIL moisture, *GAS exchange in plants

Abstract

Abstract: Peanut (Arachis hypogaea L.) is commonly grown on sandy soils in warm climates where water-deficit can impose a limitation on yield. Identification of plant traits related to increased productivity under water-deficit conditions could be used to increase yields in these water-limited environments. Two traits were examined among 17 peanut genotypes. Transpiration efficiency (TE), ratio of mass increase to water transpired, was the first trait examined. TE was measured both under well-watered conditions (greenhouse) and soil drying (outdoors in pots) conditions. Virtually no difference was observed in TE among genotypes under well-watered conditions indicating the gas exchange properties were similar. However, under soil drying conditions there were substantial differences among genotypes. These results indicated that TE with drying soil might interact with traits associated with water loss on drying soils. Therefore, the second trait examined in this study was the fraction transpirable soil water (FTSW) content at which the decline in transpiration with soil drying was observed. This greenhouse experiment showed large variability among the 17 genotypes. A second-order polynomial described the relationship between TE under soil drying conditions and the threshold for the decline in transpiration. The FTSW for maximum TE was 0.55, but this value is expected to depend on the environmental conditions to which the plants influence TE. [Copyright &y& Elsevier]

Published

2009