Abstract
With grasslands and savannas covering 20% of the world’s land surface, accounting for 30–35% of worldwide Net Primary Productivity and supporting hundreds of millions of people, predicting changes in tree/grass systems is priority. Inappropriate land management and rising atmospheric CO2 levels result in increased woody cover in savannas. Although woody encroachment occurs world-wide, Africa’s tourism and livestock grazing industries may be particularly vulnerable. Forecasts of responses of African wildlife and available grazing biomass to increases in woody cover are thus urgently needed. These predictions are hard to make due to non-linear responses and poorly understood feedback mechanisms between woody cover and other ecological responders, problems further amplified by the lack of long-term and large-scale datasets. We propose that a space-for-time analysis along an existing woody cover gradient overcomes some of these forecasting problems. Here we show, using an existing woody cover gradient (0–65%) across the Kruger National Park, South Africa, that increased woody cover is associated with (i) changed herbivore assemblage composition, (ii) reduced grass biomass, and (iii) reduced fire frequency. Furthermore, although increased woody cover is associated with reduced livestock production, we found indigenous herbivore biomass (excluding elephants) remains unchanged between 20–65% woody cover. This is due to a significant reorganization in the herbivore assemblage composition, mostly as a result of meso-grazers being substituted by browsers at increasing woody cover. Our results suggest that woody encroachment will have cascading consequences for Africa’s grazing systems, fire regimes and iconic wildlife. These effects will pose challenges and require adaptation of livelihoods and industries dependent on conditions currently prevailing.
Highlights
Savanna is a unique biome since it covers a wide range of woody cover, yet neither “drifts” towards fully closed canopy forest/thicket, neither does it drift to fully open grassland—savannas maintain a spatially and/or temporally variable tree/grass mix under most conditions of environmental forcing [1]
The study was conducted in Kruger National Park (KNP), South Africa, which was established as a conservation area in 1902 and proclaimed a national park in 1926
The five meso-grazer species as well as one of the mixed feeding species decrease along the woody cover gradient, whilst the two browsing species and a mixed feeding species that mostly browse in the dry season [39] increase with increasing woody cover (Table 2; Fig 2). (Note: Because sable is virtually absent from basalts (0.044 ind. km-2) compared to granites (0.150 ind.km-2), we focused on the trend on the granites as a more reliable indicator of sable’s tendency to decrease with increasing woody cover)
Summary
Savanna is a unique biome since it covers a wide range of woody cover, yet neither “drifts” towards fully closed canopy forest/thicket, neither does it drift to fully open grassland—savannas maintain a spatially and/or temporally variable tree/grass mix under most conditions of environmental forcing [1] The explanation for this tree/grass co-existence has been the subject of many savanna studies and the debate is still ongoing, it seems as if resource availability and variability ( rainfall), divergent rooting systems and disturbance regimes (like fire and herbivory) are some core conditions needed for co-existence [1,2,3]. Woody encroachment, which we define as a unidirectional and a hard-to-reverse increase in woody cover, is a serious threat to the persistence of the species richness and functioning associated with structurally heterogeneous savannas
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