Abstract:
Fire is an important disturbance in many biomes throughout the world and plays a major role in
savannas, where it affects the composition and structure of vegetation, which in turn structures
faunal assemblages. Higher intensity and more frequent fires tend to simplify habitat structure,
leading to a decrease in faunal abundance and diversity. Fire is often used as a tool in
conservation areas, but the effects of fire, in particular long-term burning regimes, on fauna is
largely unknown, especially in the case of invertebrates. This is problematic given the pivotal
roles that invertebrates play in ecosystem functioning. The study aimed to address this paucity of
studies on the effect of long-term burning regimes on invertebrates by making use of the longterm
fire experiment in Kruger National Park, South Africa, initiated in 1954 and using spiders,
which are important predators that play critical roles in ecosystem functioning and are a highly
diverse group, known to be sensitive to changes in vegetation structure. Specifically, the study
aimed to investigate whether spider taxonomic diversity, composition and functional traits were
affected by four burning regimes and how this response varied across three different savanna
types along a rainfall gradient. This was explored in the context of changes in vegetation
structure. It was hypothesised that spider assemblages would be influenced more by high intensity, frequent fires and that the response to the burning regimes would be greatest at the
wettest savanna site, where burning has a greater effect on vegetation structure. The burning regimes used were annual and triennial, high intensity winter burns, respectively, and triennial,
low intensity summer burns, which were all compared to unburnt plots, enabling comparisons of
the effects of fire intensity, frequency and the presence of fire versus its absence. Burning
regimes were replicated three times in three savanna types and spider sampling took place in
autumn, spring and summer using a variety of sampling techniques in order to encompass
seasonal variation in spider assemblages and to sample spiders in all components of the savanna
systems. Spiders were found to be highly resistant and resilient to changes in habitat structure
related to the burning regimes examined, with no major differences in abundance, species
richness, assemblage composition and distribution of spiders in the various functional trait
groupings investigated across burning regimes. However, there was a response by spiders
between annual, high intensity burns and unburnt plots at the wettest savanna site in terms of
abundance suggesting the possibility of a greater response by spiders to burning in wetter
savannas as hypothesised. Spider abundance and species richness decreased along the rainfall
gradient and assemblages were shown to change across the study areas as predicted. This study is one of the most comprehensive studies on savanna spiders (and the effects of long-term burning
regimes on them) in terms of spatial and temporal extent and sampling intensity but more studies
are required to further investigate the questions asked in light of the enormous turn-over in
species that is encountered when sampling spiders.