To elucidate the phytohormonal basis of the feedback regulation of leaf senescence
induced by potassium (K) deficiency in cotton (Gossypium hirsutum L.),
two cultivars contrasting in sensitivity to K deficiency were self- and reciprocally
grafted hypocotyl-to-hypocotyl, using standard grafting (one scion grafted onto one
rootstock), Y grafting (two scions grafted onto one rootstock), and inverted Y grafting
(one scion grafted onto two rootstocks) at the seedling stage. K deficiency (0.03mM for
standard and Y grafting, and 0.01mM for inverted Y grafting) increased the root abscisic
acid (ABA) concentration by 1.6- to 3.1-fold and xylem ABA delivery rates by 1.8- to
4.6-fold. The K deficiency also decreased the delivery rates of xylem cytokinins [CKs;
including the zeatin riboside (ZR) and isopentenyl adenosine (iPA) type] by 29–65%
and leaf CK concentration by 16–57%. The leaf ABA concentration and xylem ABA
deliveries were consistently greater in CCRI41 (more sensitive to K deficiency) than in
SCRC22 (less sensitive to K deficiency) scions under K deficiency, and ZR- and iPA-type
levels were consistently lower in the former than in the latter, irrespective of rootstock
cultivar or grafting type, indicating that cotton shoot influences the levels of ABA and
CKs in leaves and xylem sap. Because the scions had little influence on phytohormone
levels in the roots (rootstocks) of all three types of grafts and rootstock xylem sap
(collected below the graft union) of Y and inverted Y grafts, it appears that the site for
basipetal feedback signal(s) involved in the regulation of xylem phytohormones is the
hypocotyl of cotton seedlings. Also, the target of this feedback signal(s) is more likely
to be the changes in xylem phytohormones within tissues of the hypocotyl rather than the
export of phytohormones from the roots.
A new split-root system was established through grafting to study cotton response to non-uniform salinity. Each root half was treated with either uniform (100/100 mM) or non-uniform NaCl concentrations (0/200 and 50/150 mM). In contrast to uniform control, non-uniform salinity treatment improved plant growth and water use, with more water absorbed from the non- and low salinity side. Non-uniform treatments decreased Na+ concentrations in leaves. The [Na+] in the ‘0’ side roots of the 0/200 treatment was significantly higher than that in either side of the 0/0 control, but greatly decreased when the ‘0’ side phloem was girdled, suggesting that the increased [Na+] in the ‘0’ side roots was possibly due to transportation of foliar Na+ to roots through phloem. Plants under non-uniform salinity extruded more Na+ from the root than those under uniform salinity. Root Na+ efflux in the low salinity side was greatly enhanced by the higher salinity side. NaCl-induced Na+ efflux and H+ influx were inhibited by amiloride and sodium orthovanadate, suggesting that root Na+ extrusion was probably due to active Na+/H+ antiport across the plasma membrane. Improved plant growth under non-uniform salinity was thus attributed to increased water use, reduced leaf Na+ concentration, transport of excessive foliar Na+ to the low salinity side, and enhanced Na+ efflux from the low salinity root.
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