eprintid: 10096
rev_number: 7
eprint_status: archive
userid: 1305
dir: disk0/00/01/00/96
datestamp: 2017-07-19 05:03:55
lastmod: 2017-07-19 05:03:55
status_changed: 2017-07-19 05:03:55
type: article
metadata_visibility: show
creators_name: Sinclair, T R
creators_name: Devi, J
creators_name: Shekoofa, A
creators_name: Choudhary, S
creators_name: Sadok, W
creators_name: Vadez, V
creators_name: Riar, M
creators_name: Rufty, T
icrisatcreators_name: Choudhary, S
icrisatcreators_name: Vadez, V
affiliation: Crop Science Department, North Carolina State University (Raleigh)
affiliation: ICRISAT (Patancheru)
affiliation: Department of Agronomy and Plant Genetics, University of Minnesota (St. Paul)
country: USA
country: India
title: Limited-transpiration response to high vapor pressure deficit in crop species
ispublished: pub
subjects: s2.18
divisions: CRPS4
full_text_status: none
keywords: Aquaporins, Drought, Hydraulic conductivity, Transpiration, Vapor pressure deficit, VPD, Drought tolerance, Crop species, Physiological traits, Water shortage, Physiological research
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.
date: 2017-07
date_type: published
publication: Plant Science
volume: 260
publisher: Elsevier
pagerange: 109-118
id_number: 10.1016/j.plantsci.2017.04.007
refereed: TRUE
issn: 01689452
official_url: http://dx.doi.org/10.1016/j.plantsci.2017.04.007
related_url_url: https://scholar.google.co.in/scholar?hl=en&q=Limited-transpiration+response+to+high+vapor+pressure+deficit+in+crop+species&btnG=
related_url_type: pub
citation:   Sinclair, T R and Devi, J and Shekoofa, A and Choudhary, S and Sadok, W and Vadez, V and Riar, M and Rufty, T  (2017) Limited-transpiration response to high vapor pressure deficit in crop species.  Plant Science, 260.  pp. 109-118.  ISSN 01689452