Genotypic variation for drought tolerance in cotton ( Gossypium hirsutum L.): Leaf gas exchange and productivity

Abstract

Although water-limited environments are detrimental to cotton growth and productivity worldwide, identification of cotton ( Gossypium hirsutum L.) genotypes that are less sensitive to drought may improve productivity in drought prone areas. The objective of the study was to assess genotypic variation for drought tolerance in cotton varieties using physiological attributes as selection criteria, and to determine the relationship of physiological attributes with productivity traits. The association of target physiological traits for drought tolerance (photosynthetic rate ( P n), stomatal conductance ( g s), and transpiration rate ( E)) with productivity traits under well-watered (W 1) and water-limited (W 2) regimes was analyzed using 32 public cotton cultivars/bred lines in two field experiments conducted during the normal cotton growing seasons 2003 and 2004. Seed cotton yield (SCY) and biological yield (BY) were markedly affected under W 2 regime in all cultivars except the outstanding performance of CIM-1100 and RH-510 proving their superiority to other cultivars in drought tolerance. Conversely, FH-901, FH-634, and FH-2000 were high yielding under W 1 regime; however, exhibited a sharp decline in yield under W 2 regime. A positive correlation between SCY and BY under water stress ( r=0.44 in 2003; r=0.69 in 2004) indicates that BY is also a primary determinant of SCY under water stress and genetic improvement of BY under water-limited environment may also improve SCY. P n, g s, and E were significantly reduced by water stress. Substantial genotypic variation for gas exchange attributes existed among the cotton cultivars. A positive association ( P<0.01) was observed between g s and E under both regimes in both years indicating the prevalence of stomatal control of transpiration. The positive association ( P<0.01) between P n and g s in both years in W 2 regime indicates also a major role of stomatal effects in regulating leaf photosynthesis under water-limited conditions. P n was significantly correlated with SCY ( P<0.01) and BY ( P<0.05 in 2003; P<0.01 in 2004) in W 2 regime; however, the level of these associations was not significant in W 1 regime. These findings demonstrate that association of P n with productivity is effective under water-limited environment and may be useful as a selection criterion in breeding programs with the objective of improving drought tolerance and SCY under water-limited environments. Moreover, association between SCY and BY under water stress suggests that genetic improvement of BY under water stress may also improve SCY.