Methods

Mammal count data for the private conservancies were obtained from the Agricultural Research Council's Animal Production Institute (ARC-API) in Nelspruit, South Africa. The data comprised annual (from 1992 in some conservancies) aerial surveys (total area counts from fixed-wing aircraft; 300–500 m strips) in late winter (August–September) when reduced vegetation growth facilitated highest visibility of animals. These surveys are solicited by conservancy managers as independent ecological audits and are thus performed by the same ARC-API team using the same methodology each year and are amongst the most reliable, long-term ecological datasets in Africa (Peel et al., Reference Peel, Biggs and Zacharias1999). Mammal count data for Kruger National Park, where total area counts for 1977–1997 and strip transect sampling for 1998–2008 were undertaken using a fixed-wing aircraft (Kruger et al., Reference Kruger, Reilly and Whyte2008), were obtained from South African National Parks (SANParks), Scientific Services, Skukuza. To make the transect data of the Park comparable with the total area counts of the conservancies, the effective strip widths were obtained from Kruger National Park Scientific Services and density was calculated by converting the transects to area (strip length × strip width). Densities of white rhinoceros, elephant and buffalo were calculated from a separate helicopter census (focusing on drainage networks; for 1985–2007) and were subsampled from the transects described above. Only the common time period shared amongst all conservancies was used (1999–2007). The common and Latin names of all species used in the analyses are listed in Appendix 1.

To calculate stocking rates the unit mass (the mean body mass of an age-structured population) of the species was used. However, the combined adult male and female body mass of each species was used when calculating offtake and translocation biomass values, as it is mostly adult animals that are hunted, culled or sold (Damm, Reference Damm2005). Unless otherwise stated only the central section of Kruger National Park, which bounds the upper and lower limits of latitude of the private conservancy sample, was used in the analyses (Fig. 1). Grass standing crop was measured annually as a function of primary productivity at multiple sites within each conservancy (longest time series: 1979–2009; time period shared across conservancies: 1992–2009). The surveys focus on the perennial grass component and are a good indicator of habitat condition (Peel et al., Reference Peel, Biggs and Zacharias1999). Grass communities were measured on transect lines using a disc pasture meter and converted to biomass using the calibration equation from Trollope & Potgieter (Reference Trollope and Potgieter1986). Landscape vegetation structure has been classified at broad scales by using satellite imagery that has been corroborated by local empirical data (Peel et al., Reference Peel, Kruger and MacFadyen2007). We summarized these data by calculating the proportion of closed woodland, open woodland, riverine woodland and grassland from each plant community within each conservancy.

Quantitative and qualitative variables relating to management were determined through 21 semi-structured interviews (lasting 50–70 minutes) with conservancy managers, from March to June 2010. Most were interviewed in person on the conservancy (n = 15), but some were interviewed by telephone (n = 6). Managers from all conservancies from which ARC-API data were available were interviewed, as well as representatives from other private protected areas within the area (all interviewees were informed beforehand of strict confidentiality). The interviews were primarily aimed at securing permission to access the ARC-API mammal count and grass biomass data, as well as quantitative records relating to culling, hunting, reintroductions and translocations. In the absence of quantitative records of other management variables (for example, burning and bush-clearing records), managers were asked standardized questions with binary answers relating to the degree of management of other variables (Appendix 2). These answers were transcribed by hand and coded as ordinal variables for use in the management index.

Spatial analyses were carried out in ArcGIS v. 9.3 (ESRI, Redlands, USA) and other statistics in SPSS v. 17.0 (SPSS Inc., Chicago, USA). Although the total conservancy sample size was 14 (including Kruger National Park), most analyses were performed with 10–12 conservancies because data were unavailable for particular variables in some conservancies. All variables were checked for normality and homoscedasticity, using a Kolmogorov–Smirnov test and Levene's test, respectively. If the variables did not conform to parametric assumptions a non-parametric test was used to corroborate or refute the results and Monte Carlo simulations were used to assess the significance of the test statistic. The large scales of the study necessitated the inclusion of many variables, which could have led to confounding effects. Before every analysis involving large variable sets a multiple regression was used to detect redundant variables, thereby reducing conflation between predictor variables. Ordinary least squares (OLS) regression or logistic regression models were used for univariate analyses of continuous and ordinal variables, respectively. Analyses of variance (ANOVAs) were corrected post hoc through the Bonferroni test for multiple comparisons, to minimize Type I error. Partial regressions were used when two or more explanatory variables correlated significantly with the response variable, to ascertain the independent effect of each explanatory variable. An analysis of covariance (ANCOVA) was employed to control for the effects of rainfall on primary productivity and the residual variation was correlated with management intensity. The success or failure of reintroductions (species new to or not currently found in the conservancy) and translocations (species already present within the conservancy) was also explored through binary logistic regressions. Reintroduction success was defined as the presence of the species for each year subsequent to the reintroduction. Environmental variables (rainfall, altitude, landscape structural diversity and plant community richness) were used as control explanatory variables in all analyses.

Because of data insufficiency and the limitations of traditional multivariate analyses (Appendix 3), a novel approach to quantifying management patterns was used. We hypothesized that the effects of management interventions might be hierarchically nested and exert different scales of influence on ecosystem properties. To create a hierarchical management intensity index (MII) we used eight management predictor variables (road density, building density, artificial water-point density, burning practice, bush-control practice, mammal biomass removal, mammal biomass addition and the number of species manipulated). We then allocated each variable to one of three levels. Level 1 variables (artificial water-point density, building density, road density) were classified as ‘fixed’, and exert a sustained spatio-temporal influence on ecological variables. These variables may also be indirect indicators of unseen management intensity mechanisms such as infrastructural disturbance and fine-scale habitat alteration (for example, bush thickening on road verges; Smit & Asner, Reference Smit and Asner2012). Level 2 variables (burning, bush-control) were classified as ‘periodic’, and exert broad-scale but intermittent influences. Level 3 variables (hunting, culling, translocation) were classified as ‘continuous’, and equate to small-scale community or species-specific practices (Appendix 4).

All data were standardized (Appendix 4) and relativized (giving each variable the same overall weight within the hierarchical level) to correct for measurement inequalities. This was achieved by dividing each value of each variable by the sum total for that variable, then multiplying by the conservancy sample size (N; Equation 1). The multiplication step created an intuitive index whereby each conservancy occupied on average one unit of the total ‘management space’ for that variable. The relativized values from each hierarchical level were then summed. Each sum was multiplied through by a correction factor so that the number of variables in each hierarchical level did not bias the index. Thus, the weight of each variable was equalized throughout the sample and the variance structure was conserved. The final step was to weight the hierarchical levels differentially. Level 1 landscape features were assumed to have the most explanatory power, thus were weighted 3. Level 2 periodic disturbances were weighted 2, and Level 3 community disturbances weighted 1. These three values were then summed to produce the final MII (Equation 1).

(1)$$\eqalign{{\rm MII}c = & \left[ {{\rm SF}_1 \times {\rm CF}_1 \times \left( {\sum\nolimits_{i = 1}^3 {\displaystyle{{N \times Vci} \over {\sum {vi}}}}} \right)} \right] \cr & + \left[ {{\rm SF}_2 \times {\rm CF}_2 \times \left( {\sum\nolimits_{\,j = 1}^2 {\displaystyle{{N \times Vcj} \over {\sum {vj}}}}} \right)} \right] \cr & + \left[ {{\rm SF}_3 \times {\rm CF}_3 \times \left( {\sum\nolimits_{k = 1}^3 {\displaystyle{{N \times Vck} \over {\sum {vk}}}}} \right)} \right]} $$

where MIIc = the management intensity index for conservancy c, N = number of conservancies, i=variables in level 1, j =variables in level 2, k=variables in level 3, Vci = value of variable i in conservancy c, SF = hierarchical scaling factor, and CF = correction factor. Equation 1 can be expanded to include more hierarchical levels or different weighting as appropriate for each context. We tested the efficacy and explanatory power of hierarchically organizing the MII by repeating all analyses with a non-weighted index. Similarly, the summed variables from each hierarchical level were used as separate predictors to test whether one hierarchical level of management could parsimoniously explain ecological variance.