RELAXATION OF AN INDUCED DEFENSE AFTER EXCLUSION OF HERBIVORES - SPINES ON ACACIA-DREPANOLOBIUM

Descriptive and experimental evidence suggests that spine length is an inducible defense, with longer spines being produced by branches expe riencing greater levels of herbivory. Here we present results from a r eplicated, controlled herbivore exclusion experiment in which cattle, wildlife (large mammalian herbivores), and megaherbivores (elephants a nd giraffes) were independently manipulated. Experimental wildlife bar riers virtually eliminated herbivory on Acacia drepanolobium branches at all heights. Megaherbivore barriers reduced herbivory on branches m ore than 1.75 m from the ground by up to 80%, and reduced herbivory on lower branches by 40%. These patterns of herbivory were matched by pa tterns of relaxation of spine length that occurred in response to the treatments. After 22 months of herbivore exclusion, the lengths of new ly produced spines were 19% shorter on branches protected from large m ammal herbivory than on trees in control plots. On low branches, there was a steady increase in spine length from total exclusion plots (sho rtest spines) to plots with wildlife to plots with both megaherbivores and wildlife (longest spines). On higher branches, new spines were sh orter in total exclusion plots and wildlife plots than in plots in whi ch megaherbivores were allowed. This is the first replicated, controll ed experimental demonstration that browsing by free-ranging herbivores is associated with greater spine lengths. Examination of trees incide ntally protected from herbivory for several years suggests that reduct ion in spine length in the experimental plots will eventually exceed 7 0%. Initially slow relaxation of spine length may represent a cautious adaptive strategy in an environment where a given branch is likely to escape herbivory in a given growth season, even when herbivores are p resent.