Recovery of leaf area through accelerated shoot ontogeny in thrips-damaged cotton seedlings.

BACKGROUND AND AIMS: Leaf area of cotton seedlings (Gossypium hirsutum) can be reduced by as much as 50 % by early season thrips infestations, but it is well documented that plants can regain the difference in leaf area once infestation ceases. The processes involved in the recovery have not been identified. Hypotheses include enhancement of the photosynthetic rate of the damaged leaves, more efficient leaf construction (i.e. more leaf area per unit of dry matter invested in new leaves), and more branching. METHODS: This 2-year field study examined these hypotheses and found that thrips-affected plants recovered from a 30 % reduction in total leaf area. During the recovery period, repeated measurements of gas exchange, leaf morphology and individual leaf areas at all nodes were made to assess their contribution to the recovery. KEY RESULTS: Recovery was not achieved through the previously proposed mechanisms. The pattern of nodal development indicated that the duration of leaf expansion of the smaller deformed leaves was shorter than that of control leaves, possibly because they had fewer cells. The production and expansion of healthy upper node leaves in thrips-affected plants could, therefore, begin sooner, about 1-2.5 nodes in advance of control plants. The proposed process of recovery was evident but weaker in the second year where thrips numbers were higher. CONCLUSIONS: It is concluded that thrips-affected plants overcame the leaf area disparity through an accelerated ontogeny of main stem leaves. By completing the expansion of smaller but normally functioning lower node leaves earlier, resources were made available to the unfolding of larger upper node leaves in advance of control plants. The generality of this mode of plant resistance in pest damage remains to be determined.

Recovery from terminal and fruit damage by dry season cotton crops in tropical Australia.

We conducted a 2-yr field study on growth and yield compensation in cotton (Gossypium hirsutum L.) after artificial pest damage in Kununurra in NW Australia. The aim was to assess the responses of cotton grown in tropical Australia to simulated Helicoverpa damage early in the season (tip damage) and during fruiting (square removal). In this region, cotton is grown in an inverse temperature regimen to cotton grown in temperate regions, and it is possible that tropical cotton crops exhibit different responses to pest damage (Yeates 2001). To examine this, we imposed manual damage treatments by excising plant tips before squaring (flower bud production) and removing all large squares at 800 degree-days DD, (at base 12 degrees C; early square loss) or 1,200 DD (mid-square loss). We found high levels of tolerance in tropical cotton to simulated pest damage (particularly early square loss) equaling or possibly surpassing the compensatory response of cotton grown in temperate Australia. While yield did not differ between damage and control treatments, the trend suggests an increase in yield resulting from tip damage and early fruit loss. Compared with temperate crops, the delay in maturity caused by damage was minimal, owing to high rates of boll opening (up to 11% d(-1)). Early season tip damage resulted in a significant increase in lateral branch growth that later contributed to a higher fruiting potential. The altered canopy of tip-damaged plants also increased light interception, particularly in the upper canopy. Both of the above factors could confer a greater tolerance to subsequent fruit damage in tipped plants.