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        <dc:title>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</dc:title>
        <dc:creator>Sivasakthi, K</dc:creator>
        <dc:creator>Tharanya, M</dc:creator>
        <dc:creator>Zaman‐Allah, M</dc:creator>
        <dc:creator>Kholová, J</dc:creator>
        <dc:creator>Thirunalasundari, T</dc:creator>
        <dc:creator>Vadez, V</dc:creator>
        <dc:subject>Crop Physiology</dc:subject>
        <dc:subject>Chickpea</dc:subject>
        <dc:subject>Drought</dc:subject>
        <dc:subject>Water Conservation</dc:subject>
        <dc:description>Terminal drought substantially reduces chickpea yield. Reducing water use at vegetative&#13;
stage by reducing transpiration under high vapor pressure deficit (VPD), i.e. under dry/&#13;
hot conditions, contributes to drought adaptation. We hypothesized that this trait could&#13;
relate to differences in a genotype’s dependence on root water transport pathways and&#13;
hydraulics.&#13;
• Transpiration rate responses in conservative and profligate chickpea genotypes were&#13;
evaluated under increasing VPD in the presence/absence of apoplastic and cell-to-cell&#13;
transport inhibitors.&#13;
• Conservative genotypes ICC 4958 and ICC 8058 restricted transpiration under high&#13;
VPD compared to the profligate genotypes ICC 14799 and ICC 867. Profligate genotypes&#13;
were more affected by aquaporin inhibition of the cell-to-cell pathway than conservative&#13;
genotypes, as measured by the root hydraulic conductance and transpiration&#13;
under high VPD. Aquaporin inhibitor treatment also led to a larger reduction in root&#13;
hydraulic conductivity in profligate than in conservative genotypes. In contrast, blockage&#13;
of the apoplastic pathway in roots decreased transpiration more in conservative&#13;
than in profligate genotypes. Interestingly, conservative genotypes had high early vigour,&#13;
whereas profligate genotypes had low early vigour.&#13;
• In conclusion, profligate genotypes depend more on the cell-to-cell pathway, which&#13;
might explain their higher root hydraulic conductivity, whereas water-saving by&#13;
restricting transpiration led to higher dependence on the apoplastic pathway. This&#13;
opens the possibility to screen for conservative or profligate chickpea phenotypes using&#13;
inhibitors, itself opening to the search of the genetic basis of these differences.</dc:description>
        <dc:publisher>Wiley</dc:publisher>
        <dc:date>2020-06</dc:date>
        <dc:type>Article</dc:type>
        <dc:type>PeerReviewed</dc:type>
        <dc:format>application/pdf</dc:format>
        <dc:language>en</dc:language>
        <dc:identifier>http://oar.icrisat.org/11620/1/plb.13147.pdf</dc:identifier>
        <dc:identifier>  Sivasakthi, K and Tharanya, M and Zaman‐Allah, M and Kholová, J and Thirunalasundari, T and Vadez, V  (2020) 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.  Plant Biology (TSI).  pp. 769-780.  ISSN 1435-8603     </dc:identifier>
        <dc:relation>https://doi.org/10.1111/plb.13147</dc:relation>
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