Scriber J Mark
Department of Entomology, Cornell University, 14853, Ithaca, NY, USA.
Oecologia. 1977 Sep;28(3):269-287. doi: 10.1007/BF00751605.
Hyalophora cecropia larvae were reared on leaves of wild cherry,Prunus serotina, which contained variable amounts of leaf water but otherwise did not differ in fiber, total nitrogen, and caloric content. Larvae which were fed leaves low in leaf water grew more slowly and were less efficient at utilizing plant biomass, energy, and nitrogen than those larvae fed leaves which were fully supplemented with water.Experiments were performed using excised leaves under different regimes of relative humidity and leaf water supplementation in climatic control chambers maintained at identical temperatures and photoperiod. Foodplant biomass utilization efficiencies were severely reduced by decreasing amounts of leaf water. Growth rates were halved and the efficiency of conversion of assimilated dry matter into larval biomass was reduced from 82% in the treatment with fully supplemented leaves to 34% in the driest treatment. The nitrogen utilization efficiency (N.U.E.) was reduced from 75-80% to 48%, and the relative accumulation rate of nitrogen (N.A.R.) was suppressed nearly 2-fold for larvae on low-water leaves. Relative maintenance costs (calories expended in respiration/mg tissue/day) of larvae were nearly five times higher on dry leaves than on fully supplemented leaves. Larvae on leaves which were low in water content were themselves more desiccated, and metabolized greater portions of assimilated energy, perhaps in an attempt to supplement body water with metabolic water derived from respiration.The larval rates of consumption of biomass, energy, and nitrogen were the same for all treatments, indicating that leaf water affected larval growth primarily by restricting the efficiency of utilizing these nutrients. Where water was limiting (as in tree leaves), an increased consumption rate did not appear to be a successful means of increasing growth rates. There were daily and seasonal differences in leaf water content between different trees of the same species. Although absolute differences in leaf water exist between different trees and between young and old (fully expanded) leaves of a single tree, these differences are proportional and parallel each other through daily and seasonal cycles.In spite of evolutionary adaptations of herbivores to acquire adequate water and avoid desiccation, the leaf water content naturally encountered by cecropia larvae on cherry leaves may limit their growth, especially if the R.H. is low.
樗蚕蛾幼虫以野生樱桃(黑樱桃,Prunus serotina)的叶子为食,这些叶子的含水量各不相同,但在纤维、总氮和热量含量方面并无差异。取食叶片含水量低的幼虫生长较慢,与取食水分充足叶片的幼虫相比,其利用植物生物量、能量和氮的效率较低。实验在气候控制室内进行,使用切除的叶片,在相同温度和光周期下,设置不同的相对湿度和叶片水分补充条件。叶片含水量的减少严重降低了食料植物生物量的利用效率。生长速率减半,同化干物质转化为幼虫生物量的效率从叶片水分充足处理的82%降至最干燥处理的34%。低水分叶片上幼虫的氮利用效率(N.U.E.)从75 - 80%降至48%,氮相对积累率(N.A.R.)被抑制近2倍。幼虫在干燥叶片上的相对维持成本(呼吸消耗的卡路里/毫克组织/天)几乎是水分充足叶片上的五倍。含水量低的叶片上的幼虫自身脱水更严重,消耗了更大比例的同化能量,可能是试图用呼吸产生的代谢水补充身体水分。所有处理中幼虫对生物量、能量和氮的消耗速率相同,这表明叶片水分主要通过限制这些养分的利用效率来影响幼虫生长。在水分受限的情况下(如树叶中),增加消耗速率似乎并不是提高生长速率的有效方法。同一物种的不同树木之间,叶片含水量存在每日和季节性差异。尽管不同树木之间以及同一棵树的幼叶和老叶(完全展开)之间存在叶片水分的绝对差异,但这些差异是成比例的,并且在每日和季节性周期中相互平行。尽管食草动物经过进化适应以获取足够的水分并避免脱水,但樗蚕蛾幼虫在樱桃叶上自然遇到的叶片含水量可能会限制它们的生长,尤其是在相对湿度较低的情况下。
