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3. Spatial distribution of transcript changes in the maize primary root elongation zone at low water potential

Author

Bohnert Hans J, Zhu Jinming, LeNoble Mary E, Kim Jong-Joo, Hejlek Lindsey G, Chen Kegui, Valliyodan Babu, Tao Wenjing, Spollen William G, Henderson David, Schachtman Daniel P, Davis Georgia E, Springer Gordon K, Sharp Robert E, and Nguyen Henry T

Subjects
Botany, QK1-989
Abstract

Abstract Background Previous work showed that the maize primary root adapts to low Ψw (-1.6 MPa) by maintaining longitudinal expansion in the apical 3 mm (region 1), whereas in the adjacent 4 mm (region 2) longitudinal expansion reaches a maximum in well-watered roots but is progressively inhibited at low Ψw. To identify mechanisms that determine these responses to low Ψw, transcript expression was profiled in these regions of water-stressed and well-watered roots. In addition, comparison between region 2 of water-stressed roots and the zone of growth deceleration in well-watered roots (region 3) distinguished stress-responsive genes in region 2 from those involved in cell maturation. Results Responses of gene expression to water stress in regions 1 and 2 were largely distinct. The largest functional categories of differentially expressed transcripts were reactive oxygen species and carbon metabolism in region 1, and membrane transport in region 2. Transcripts controlling sucrose hydrolysis distinguished well-watered and water-stressed states (invertase vs. sucrose synthase), and changes in expression of transcripts for starch synthesis indicated further alteration in carbon metabolism under water deficit. A role for inositols in the stress response was suggested, as was control of proline metabolism. Increased expression of transcripts for wall-loosening proteins in region 1, and for elements of ABA and ethylene signaling were also indicated in the response to water deficit. Conclusion The analysis indicates that fundamentally different signaling and metabolic response mechanisms are involved in the response to water stress in different regions of the maize primary root elongation zone.

Published
2008
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5. Proteomic dataset of sorghum leaf and root responses to single and combined drought and heat stress.

Author

Ali, Ali Elnaeim Elbasheir, Sharp, Robert E., Greeley, Laura, Peck, Scott C., Tabb, David L., and Ludidi, Ndiko

Subjects
CROP science, LIFE sciences, AGRICULTURE, SORGHUM farming, BOTANY, SORGHUM, PLANT-water relationships
Abstract

Drought and heat stress significantly limit crop growth and productivity. Their simultaneous occurrence, as often observed in summer crops, leads to larger yield losses. Sorghum is well adapted to dry and hot conditions. Despite the progress that has been made in determining proteomic responses to water deficit or heat stress in crops, such information remains limited for crops subjected to combined water deficit and heat stress. This study presents quantitative proteomics analyses of leaf and root tissues of two contrasting sorghum genotypes grown under normal conditions, water deficit stress, heat stress, and water deficit combined with heat stress. We identified differentially expressed proteins between the two genotypes under these different treatments. GO and KEGG annotation revealed biological processes and molecular pathways associated with sorghum responses to these treatments. Interpretation as well as integration of these proteomics data with other 'omics' signatures may highlight key mechanisms involved in sorghum adaptations to these stresses. [ABSTRACT FROM AUTHOR]

Published
2025
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23. Hydraulic flux–responsive hormone redistribution determines root branching

Author

Mehra, Poonam, primary, Pandey, Bipin K., additional, Melebari, Dalia, additional, Banda, Jason, additional, Leftley, Nicola, additional, Couvreur, Valentin, additional, Rowe, James, additional, Anfang, Moran, additional, De Gernier, Hugues, additional, Morris, Emily, additional, Sturrock, Craig J., additional, Mooney, Sacha J., additional, Swarup, Ranjan, additional, Faulkner, Christine, additional, Beeckman, Tom, additional, Bhalerao, Rishikesh P., additional, Shani, Eilon, additional, Jones, Alexander M., additional, Dodd, Ian C., additional, Sharp, Robert E., additional, Sadanandom, Ari, additional, Draye, Xavier, additional, and Bennett, Malcolm J., additional

Published
2022
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26. Hydraulic flux–responsive hormone redistribution determines root branching

Author

UCL - SST/ELI/ELIA - Agronomy, Mehra, Poonam, Pandey, Bipin K., Melebari, Dalia, Banda, Jason, Leftley, Nicola, Couvreur, Valentin, Rowe, James, Anfang, Moran, De Gernier, Hugues, Morris, Emily, Sturrock, Craig J., Mooney, Sacha J., Swarup, Ranjan, Faulkner, Christine, Beeckman, Tom, Bhalerao, Rishikesh P., Shani, Eilon, Jones, Alexander M., Dodd, Ian C., Sharp, Robert E., Sadanandom, Ari, Draye, Xavier, Bennett, Malcolm J., UCL - SST/ELI/ELIA - Agronomy, Mehra, Poonam, Pandey, Bipin K., Melebari, Dalia, Banda, Jason, Leftley, Nicola, Couvreur, Valentin, Rowe, James, Anfang, Moran, De Gernier, Hugues, Morris, Emily, Sturrock, Craig J., Mooney, Sacha J., Swarup, Ranjan, Faulkner, Christine, Beeckman, Tom, Bhalerao, Rishikesh P., Shani, Eilon, Jones, Alexander M., Dodd, Ian C., Sharp, Robert E., Sadanandom, Ari, Draye, Xavier, and Bennett, Malcolm J.

Abstract

Plant roots exhibit plasticity in their branching patterns to forage efficiently for heterogeneously distributed resources, such as soil water. The xerobranching response represses lateral root formation when roots lose contact with water. Here, we show that xerobranching is regulated by radial movement of the phloem-derived hormone abscisic acid, which disrupts intercellular communication between inner and outer cell layers through plasmodesmata. Closure of these intercellular pores disrupts the inward movement of the hormone signal auxin, blocking lateral root branching. Once root tips regain contact with moisture, the abscisic acid response rapidly attenuates. Our study reveals how roots adapt their branching pattern to heterogeneous soil water conditions by linking changes in hydraulic flux with dynamic hormone redistribution

Published
2022

27. Hydraulic flux–responsive hormone redistribution determines root branching

Author

Mehra, Poonam, Pandey, Bipin K., Melebari, Dalia, Banda, Jason, Leftley, Nicola, Couvreur, Valentin, Rowe, James, Anfang, Moran, De Gernier, Hugues, Morris, Emily, Sturrock, Craig J., Mooney, Sacha J., Swarup, Ranjan, Faulkner, Christine, Beeckman, Tom, Bhalerao, Rishikesh P., Shani, Eilon, Jones, Alexander M., Dodd, Ian C., Sharp, Robert E., Sadanandom, Ari, Draye, Xavier, Bennett, Malcolm J., Mehra, Poonam, Pandey, Bipin K., Melebari, Dalia, Banda, Jason, Leftley, Nicola, Couvreur, Valentin, Rowe, James, Anfang, Moran, De Gernier, Hugues, Morris, Emily, Sturrock, Craig J., Mooney, Sacha J., Swarup, Ranjan, Faulkner, Christine, Beeckman, Tom, Bhalerao, Rishikesh P., Shani, Eilon, Jones, Alexander M., Dodd, Ian C., Sharp, Robert E., Sadanandom, Ari, Draye, Xavier, and Bennett, Malcolm J.

Abstract

Plant roots exhibit plasticity in their branching patterns to forage efficiently for heterogeneously distributed resources, such as soil water. The xerobranching response represses lateral root formation when roots lose contact with water. Here, we show that xerobranching is regulated by radial movement of the phloem-derived hormone abscisic acid, which disrupts intercellular communication between inner and outer cell layers through plasmodesmata. Closure of these intercellular pores disrupts the inward movement of the hormone signal auxin, blocking lateral root branching. Once root tips regain contact with moisture, the abscisic acid response rapidly attenuates. Our study reveals how roots adapt their branching pattern to heterogeneous soil water conditions by linking changes in hydraulic flux with dynamic hormone redistribution.

Published
2022

42. Water Deficit-Induced Changes in Phenolic Acid Content in Maize Leaves Is Associated with Altered Expression of Cinnamate 4-Hydroxylase and p-Coumaric Acid 3-Hydroxylase.

Author

Kolo, Zintle, Majola, Anelisa, Phillips, Kyle, Ali, Ali Elnaeim Elbasheir, Sharp, Robert E., and Ludidi, Ndiko

Subjects
PHENOLIC acids, GENE expression, CORN, GENETIC overexpression, FERULIC acid, CAFFEIC acid, DROUGHT tolerance
Abstract

The amino acid phenylalanine is a precursor to phenolic acids that constitute the lignin biosynthetic pathway. Although there is evidence of a role of some phenolic acids in plant responses to pathogens and salinity, characterization of the involvement of phenolic acids in plant responses to drought is limited. Drought reduces water content in plant tissue and can lead to decreased cell viability and increased cell death. We thus subjected maize seedlings to water deficit and evaluated relative water content and cell viability together with p-coumaric acid, caffeic acid and ferulic acid contents in the leaves. Furthermore, we measured the enzymatic activity of cinnamate 4-hydroxylase (EC 1.14.13.11) and p-coumarate 3-hydroxylase (EC 1.14.17.2) and associated these with the expression of genes encoding cinnamate 4-hydroxylase and p-coumarate-3 hydroxylase in response to water deficit. Water deficit reduced relative water content and cell viability in maize leaves. This corresponded with decreased p-coumaric acid but increased caffeic and ferulic acid content in the leaves. Changes in the phenolic acid content of the maize leaves were associated with increased enzymatic activities of cinnamate 4-hydroxylase and p-coumarate hydroxylase. The increased enzymatic activity of p-coumarate 3-hydroxylase was associated with increased expression of a gene encoding p-coumarate 3-hydroxylase. We thus conclude that metabolic pathways involving phenolic acids may contribute to the regulation of drought responses in maize, and we propose that further work to elucidate this regulation may contribute to the development of new maize varieties with improved drought tolerance. This can be achieved by marker-assisted selection to select maize lines with high levels of expression of genes encoding cinnamate 4-hydroxylase and/or p-coumarate 3-hydroxylase for use in breeding programs aimed and improving drought tolerance, or by overexpression of these genes via genetic engineering to confer drought tolerance. [ABSTRACT FROM AUTHOR]

Published
2023
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