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Acinonyx sp. · 04-05-2021, 04:49 AM

CHAPTER 9: DEMOGRAPHY OF THE NAMIBIAN CHEETAH
ABSTRACT
Namibian cheetahs have suffered, and continue to suffer, high levels of removal due to conflict with local farmers, and it is important to understand the demography of this population in order to determine its likely persistence. Examination of cheetahs reported live-trapped or killed by local farmers, combined with subsequent information from radio-telemetry, allowed demographic parameters such as sex ratios, age and social structure, litter size, interbirth intervals and survivorship to be estimated for cheetahs on Namibian farmlands. Cub mortality was relatively low, but adult mortality was high, particularly for males, and peaked at 5-6 years of age. Neither marking nor relocating cheetahs seemed to affect survivorship, and there was no difference in survivorship between the sexes. Time spent in captivity did not appear to affect survival after release. These findings will be useful in formulating recommendations regarding the conservation and sustainable utilization of cheetah populations outside protected areas.

9.1 INTRODUCTION
Determining vital rates and demographic parameters is fundamentally important to the accurate understanding of any population (Eberhardt 1985, Lebreton et al. 1992, Lebreton et al. 1993). When a population is subject to high offtake, it is essential to establish whether the level of removal threatens its long-term viability. Large mammals are particularly sensitive in light of their long gestation and interbirth intervals, extended parental care and long maturation. Their life history parameters effectively lower the potential rate of population increase (Eisenberg 1981, Harvey et al. 1989), creating a higher extinction risk. Adult survival is a particularly important parameter, documented to exert a substantial impact on population viability for large, long-lived species (Crooks et al. 1998, Doak et al. 1994, Eberhardt 1985, Taylor et al. 1987). The Namibian cheetah is an example of a threatened population which has been subject to a high level of removal, and whose vital rates require more accurate determination in order to assess and manage the impact of such removals. Vital rates of cheetahs have been reported in the Serengeti (Caro 1994, Kelly and Durant 2000, Kelly et al. 1998, Laurenson 1995, Laurenson et al. 1992), but the population in Namibia is subject to strikingly different pressures (Marker-Kraus et al. 1996). The intense conflict with humans results in a high number of adults being removed, which could have a more severe effect on long-term population viability (Crooks et al. 1998) than the lion-perpetrated high cub mortality reported in the Serengeti ecosystem (Laurenson 1995).In order to ascertain the impact of such mortality, this paper reports and examines the vital rates and life history parameters of cheetahs on Namibian farmlands. Assessment of these reproduction and survivorship estimates provides insight into the vulnerability and likely persistence of the cheetah population in Namibia. In 1996, a Population and Habitat Viability Assessment was conducted, and called for, as a priority, more data on demographic parameters such as annual female mortality and reproductive information (Berry et al. 1996). Here, we provide these data.

9.2 METHODS
Demographic parameters were estimated using data from cheetahs captured opportunistically by farmers between 1991 and 2000. Some of these cheetahs were subsequently radio-collared and released, which provided information regarding reproduction and survivorship in the wild. Our interpretations take note of a potential bias in the sample population arising from the high proportion of cheetahs captured at ‘playtrees’, which are used more by adult males than by adult females (Marker-Kraus and Kraus 1995).

9.2.1 Trapping, immobilising and marking cheetahs
During the course of the study, we examined cheetahs that had been trapped on Namibian farms, using the capture and immobilisation protocols described in Chapter 3. Each live cheetah that we examined during the study was marked with a uniquely numbered implantable transponder (Trovan Electronic Identification Systems, Model-ID 100) placed at the base of its tail, and/or an aluminium ear-tag with a unique ID number in the individual’s ear. On designated animals (those released in the core study area), a neoprene radio-telemetry collar with external antenna was also fitted (Advanced Telemetry Systems, Minnesota). The radio-collars were 3.8 cm wide with an adjustable strap from 30-45 cm long, with a 30 cm antenna extending about 18 cm from the collar. The collars were fitted with a "C" cell lithium battery with a life expectancy of over 36 months. Radio-collars weighed 280g and were equivalent to 0.56% of body mass for a 50kg male and 0.76% for a 37kg female, well below the limit suggested by Amlaner and Macdonald in 1980. In line with Caro (1994), we could detect no impact of these collars on cheetah survival.

9.2.2 Age classification
Age classification was based both on experience with captive cheetahs and on information from previous studies (Burney 1980, Caro 1994), and followed the protocol described in Chapter 3.

9.2.3 Determining social structure
Cheetahs are relatively social felids and often occur in groups: in many cases, farmers left adjoining traps open after catching a cheetah, to ensure that all members of any social group were captured at the same time. In other instances, capture was more random and it was likely that other cheetahs in the same social group remained free. Parameters such as coalition size, litter size and age-specific cub mortality were therefore determined using data from cases where determined attempts had been made to capture the entire group of cheetahs. Cheetahs were classified as to the social group of which they were a part when they were captured, using the following categories. Males over 18 months old were classed either as single males or as members of male coalitions, while females over 18 months old were classed as either being single females or as mothers trapped with cubs. The remaining classes were cubs (18 months old or younger) trapped without a dam, and mixed-sex groups of young independent cheetahs (19-30 months old), which were presumed to be littermate groups.

9.2.4 Estimating reproductive parameters
Age at parturition was estimated by examining females trapped with cubs, and by observing new litters of cubs produced by radio-collared females of known age. Long-term monitoring of six radio-collared females that had multiple litters provided information regarding interbirth intervals. Information regarding the distribution of births through the year was gathered from the examination and ageing of cubs trapped, and from observations made of females and cubs during radio-telemetry. Litter size was determined from groups trapped where determined efforts had been made to capture the entire family unit, and from observations of radio-collared females with cubs during aerial tracking. Although we have no data regarding litter size at birth, observations of litters of different ages allowed some estimation of agespecific cub mortality.

9.2.5 Estimating mortality and survivorship
Most cheetahs were released at site of capture, but when this was not possible, the cheetahs were relocated. Relocation was classified as being 100km or more away, as this should be well beyond the diameter of a normal home range (Marker 2000). The majority of cheetahs released within the core study area were radiocollared in order to gain information regarding post-release movements and home ranges. In addition, the tracking of cheetahs enabled information to be gathered regarding survivorship. Wild cheetah deaths reported to CCF included cheetahs that had been radio-collared, some that were tagged, and some that had not been marked at all. The deaths of marked cheetahs, whether radio-collared or simply ear-tagged, were often reported and enabled comparisons to be made about the approximate age of death of handled cheetahs versus those of cheetahs that had never been handled. Mortality rates and life expectancy data were calculated following Downing (1980). The age of a cheetah at death was taken to be the midpoint of the age category in which it was recorded at the time of death. By using this midpoint, the formulae used should underestimate and overestimate the age at death for equal numbers of cheetahs and thereby give an approximation that is close to the actual distribution of ages at death. Statistical analyses were performed using SPSS version 10.0 software (SPSS Inc. Chicago, USA). Means significance testing was carried out using the parametric independent samples t-test, using Levene’s test to determine equality of variances, while departures from expected ratios were analysed using a chi-squared test. The non-parametric Spearman’s rank correlation coefficient was used to determine the significance of relationships between variables measured on nominal scales, while Pearson’s correlation coefficient was determined for interval data. Tests performed included one-way analysis of variance, and log rank for the equality of survival distributions following a Kaplan Meier analysis. All tests were two-tailed unless otherwise stated.

Table 9.1 Annual demographic breakdown into social groups of the cheetahs captured and examined (SM = single males; C = coalition, CM = coalition males, CS = coalition size, SF = single females, LS = litter size, LM = littermate).