<mods:mods version="3.3" xsi:schemaLocation="http://www.loc.gov/mods/v3 http://www.loc.gov/standards/mods/v3/mods-3-3.xsd" xmlns:mods="http://www.loc.gov/mods/v3" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"><mods:titleInfo><mods:title>Water: the most important ‘molecular’ component of water&#13;
stress tolerance research</mods:title></mods:titleInfo><mods:name type="personal"><mods:namePart type="given">V</mods:namePart><mods:namePart type="family">Vadez</mods:namePart><mods:role><mods:roleTerm type="text">author</mods:roleTerm></mods:role></mods:name><mods:name type="personal"><mods:namePart type="given">J</mods:namePart><mods:namePart type="family">Kholova</mods:namePart><mods:role><mods:roleTerm type="text">author</mods:roleTerm></mods:role></mods:name><mods:name type="personal"><mods:namePart type="given">M</mods:namePart><mods:namePart type="family">Zaman-Allah</mods:namePart><mods:role><mods:roleTerm type="text">author</mods:roleTerm></mods:role></mods:name><mods:name type="personal"><mods:namePart type="given">N</mods:namePart><mods:namePart type="family">Nouhoun BelkoA,</mods:namePart><mods:role><mods:roleTerm type="text">author</mods:roleTerm></mods:role></mods:name><mods:abstract>Water deficit is the main yield-limiting factor across the Asian and African semiarid tropics and a basic&#13;
consideration when developing crop cultivars for water-limited conditions is to ensure that crop water demand matches&#13;
season water supply. Conventional breeding has contributed to the development of varieties that are better adapted to&#13;
water stress, such as early maturing cultivars that match water supply and demand and then escape terminal water stress.&#13;
However, an optimisation of this match is possible. Also, further progress in breeding varieties that cope with water stress is&#13;
hampered by the typically large genotype environment interactions in most field studies. Therefore, a more comprehensive&#13;
approach is required to revitalise the development of materials that are adapted to water stress. In the past two decades,&#13;
transgenic and candidate gene approaches have been proposed for improving crop productivity under water stress, but&#13;
have had limited real success. The major drawback of these approaches has been their failure to consider realistic water&#13;
limitations and their link to yield when designing biotechnological experiments. Although the genes are many, the plant&#13;
traits contributing to crop adaptation to water limitation are few and revolve around the critical need to match water supply&#13;
and demand. We focus here on the genetic aspects of this, although we acknowledge that crop management options also&#13;
have a role to play. These traits are related in part to increased, better or more conservative uses of soil water. However, the&#13;
traits themselves are highly dynamic during crop development: they interact with each other and with the environment.&#13;
Hence, success in breeding cultivars that are more resilient under water stress requires an understanding of plant traits&#13;
affecting yield under water deficit as well as an understanding of their mutual and environmental interactions. Given that&#13;
the phenotypic evaluation of germplasm/breeding material is limited by the number of locations and years of testing, crop&#13;
simulation modelling then becomes a powerful tool for navigating the complexity of biological systems, for predicting the&#13;
effects on yield and for determining the probability of success of specific traits or trait combinations across water stress&#13;
scenarios.</mods:abstract><mods:classification authority="lcc">Genetics and Genomics</mods:classification><mods:originInfo><mods:dateIssued encoding="iso8061">2013</mods:dateIssued></mods:originInfo><mods:originInfo><mods:publisher>CSIRO Publishing</mods:publisher></mods:originInfo><mods:genre>Article</mods:genre></mods:mods>