Small mammal community structure (Rodentia: Muridae) in Punda Maria, Kruger National Park, South Africa : Causes and consequences

Scholtz, Rheinhardt

09 March 2017

The population dynamics of small mammal populations in Punda Maria, Kruger National Park, South Africa was investigated with respect to community size and structure, seed predation and dispersal of several trees. Species populations, community structure and habitat attributes were measured at six sites comprising of 3 habitat types (2 sites per habitat); namely Acaciagrassland, North-facing and South-facing sloped sites. Seasonal variation was investigated at the Acacia sites during late summer (April) and winter months (July). Five habitat attributes were measured; percentages of total cover and herbage, plant litter depth (cm), height of dominant vegetation type measured (m) and edaphic condition were recorded at 15 randomly selected traps per site. Almonds (Prunus dulcis), baobabs (Adansonia digitata), mopane (Colophospermum mopane), and Acacia tortilis seeds were used in the predation and dispersal experiment. North- and South-facing sites were dominated by Aethomys sp. while Acacia sites were dominated by Mastomys natalensis. Seed predation was high at the North-facing slopes, with a significant difference in predation on A. tortilis seeds. Seed dispersal activity was low; no , scatter hoarding was identified; only larder hoarding was observed by Aethomys sp. and M. natalensis at North-facing sites and Acacia sites respectively. Trampling by megaherbivore activity impacted vegetation structure and has negatively affected rodent population and ground activity, particularly at the Acacia sites.

Botany

Habitat attributes

small mammals

megaherbivores

vegetation structure

seed predation

seed dispersal

Modeling Habitat Attributes of Cavity-Nesting Birds in the Uinta Mountains, Utah: A Hierarchical Approach

Lawler, Joshua J.

01 May 1999

Birds may have the ability to view their environments at a wide range of spatial scales; accordingly, they may make habitat-selection decisions at multiple spatial scales. I investigated the implications of hierarchy theory and a landscape perspective on nestsite selection in cavity-nesting birds in the Uinta Mountains in northeastern Utah. I used · three different approaches to address the concept of a multi-scaled nest-site selection Ill process. First, I conducted an exploratory study in which I investigated nest-site selection at three spatial scales for Red-naped Sapsucker (Sphyrapicus nuchalis), Northern Flicker (Colaptes auratus), Tree Swallow (Tachycineta bicolor), and Mountain Chickadee (Parus gambeli). By conducting a hierarchically structured analysis, I was able to investigate the habitat relationships that might result from a hierarchically organized nest site selection process . I found that the four species were associated with patterns of vegetation at three spatial scales and that these associations combined in such a way as to imply a process of nest-site selection that may be more complex than that posited by the niche-gestalt concept. Second, I conducted an experiment in which I investigated nest-site selection at two spatial scales. I compared the use of four types of aspen stands in a two-by-two factorial design according to within-stand structure and landscape context. Stands were classified as either dense or sparse and as having predominantly meadow or forested edges. To address nest-site selection by secondary cavity nesters , who may be limited by cavity availability, I augmented the natural cavities with nest boxes. I found that birds predominantly nested in sparse stands and in stands with meadow edges. Although only five nest boxes were used for nesting, all five of these boxes were in sparse stands with meadow edges. The third way in which I investigated the process of nest-site selection was to build and test predictive models using associations between birds and landscape patterns. By using landscape patterns to predict habitat, I was able to build models that were easily applied ; predictions could be made without any additional data collection in the field. The models were very accurate for both Red-naped Sapsuckers and Tree Swallows (86- 98% and 53-93% nests correctly predicted, respectively) but were less accurate for Mountain Chickadees and Northern Flickers (33-42% and 19-37%, respectively) .

habitat attributes

model

cavity-nesting birds

uinta mountains

hierarchical

Poultry or Avian Science