When is an island not an island? Insular effects and their causes in fynbos shrublands

Bond, William J.; Midgley, J. J.; Vlok, Jan

doi:10.1007/bf00377267

Cited by 62 publications

(50 citation statements)

References 16 publications

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“…Level I is an analytical model that mimics (Minnich 1983) 10 0 -l()' (Keeley 1991;Yealon and Bond 1991; others bird dispersed [Bond et al 1988]) 10 3 -I0 7 (Minnich 1983;Bond et al 1988) 10-60 (Powells 1965;Loehle 1988) I0 2 -10 3 (Powells 1965) .005-.02 (Zackrisson 1977;Johnson 1979;Foster 1982) 10'-10 2 (Johnson 1992) 10 s -10 8 (Foster 1982;Eberhart and Woodard 1987;Payette et al 1989) .25 (.2-1.6)…”

Section: Relationships Among Three Types Of Modelsmentioning

confidence: 99%

Fecundity and Dispersal in Plant Populations: Implications for Structure and Diversity

Clark¹,

Yuan²

1995

The American Naturalist

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Abstract.-Demographic models of tree populations assume that seed availability does not depend on the populations themselves. We develop models to assess the consequences of fecundity and dispersal for population structure and diversity. Results show that population structure and reproductive success are importantly affected by seed production and dispersal for realistic parameterization of time scales describing thinning, disturbance, maturation, and longevity. Maturation age affects mean and variance in seed rain. Populations with well-dispersed seed have a structure that is most sensitive to maturation age when disturbance is frequent. With restricted dispersal, delayed maturation means increased variability in seed rain, maximized when half of all patches support reproductive individuals. Density-dependent thinning compensates for the initial variability conferred by limited dispersal but not enough to permit the neglect of fecundity and dispersal at the disturbance frequencies and thinning rates typical in many forests. Longevity matters most when it is short and disturbance rare. To assess the effects of dispersal on reproductive success, we partition the contributions of seed-rain mean and variance. Fecundity and population structure affect both the mean and the variance in seed rain, albeit in different ways. Dispersal affects only the variance. The partitioned contribution of mean and variance are used to consider two cases: how dispersal consequences for reproductive success depend on life-history schedules and disturbance regime, and boundary growth rates of a globally dispersed population invading a resident population with restricted dispersal. In both cases, restricted dispersal has important consequences on the scales observed in many real forests. Most models of forest tree dynamics assume a globally dispersed seed pool that is disconnected from the populations that should produce that seed. This assumption leads to two opposing (offsetting?) consequences for species diversity: artificially high diversity due to continuous seed supply and artificially low diversity due to lack of sites where good competitors with restricted dispersal should be absent.Recruitment represents a potentially significant, yet poorly described, aspect of tree population dynamics. Fecundity schedules may affect the success of a population in competition and when the environment varies in time (e.g., because of weather or disturbance). Dispersal governs spatial variance in seed rain. That variability can determine whether offspring locate suitable sites and the importance of density-and frequency-dependent interactions (e.g., pathogens, herbivores, competition with parent, siblings, other species). These relationships affect, in turn, species diversity and rates at which species ranges respond to changing environments (Watts 1973;Baker 1974;Payette and Gagnon 1985). Fecundity and dispersal are difficult to parameterize in closed stands, because seed production can vary with age, size, stand characteristics, and across tim...

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Section: Relationships Among Three Types Of Modelsmentioning

confidence: 99%

Fecundity and Dispersal in Plant Populations: Implications for Structure and Diversity

Clark¹,

Yuan²

1995

The American Naturalist

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“…However, small areas should not be dismissed as a subset of processes can be maintained in them. For example, plant and invertebrate diversity can be maintained in habitat fragments as small as 5 ha provided they are subject to appropriate fire regimes and kept free of invasive plants (Bond et al, 1988;Cowling and Bond, 1991;Kemper et al, 1999;. Consequently, populations of specialised pollinators that are responsible for driving speciation in numerous lineages (e.g.…”

Section: Spatial Components Of Processesmentioning

confidence: 99%

“…While protected areas of > 1000 ha might be regarded as having low conservation value in some parts of the world (e.g. Noss and Cooperrider, 1994), in the CFR areas much smaller than this can accommodate a wide range of biodiversity patterns and processes if appropriately managed (Bond et al, 1988;Cowling and Bond, 1991;Kemper et al, 1999).…”

Section: Assessment Of the Planning Approachmentioning

confidence: 99%

A conservation plan for a global biodiversity hotspot—the Cape Floristic Region, South Africa

Cowling

Pressey

Rouget

et al. 2003

Biological Conservation

332

266

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We produced a conservation plan that achieved conservation targets for biodiversity pattern and process in the species-and endemic-rich Cape Floristic Region of South Africa. Features given quantitative conservation targets were land classes, localities of Proteaceae and selected vertebrate (freshwater fish, amphibians and reptiles) species, population sizes for medium-and large-sized mammals, and six types of spatial surrogates for ecological and evolutionary processes. The plan was developed in several stages using C-Plan, a decision support system linked to a geographic information system. Accepting the existing reserve system as part of the plan, we first selected spatially fixed surrogates for biodiversity processes; then we included those planning units that were essential for achieving targets for land classes, Proteaceae and vertebrate species; next we included areas required to accommodate population and design targets for large and medium-sized mammals; we then selected planning units required to conserve entire upland-lowland and macroclimatic gradients; and finally we resolved the options for achieving remaining targets while also consolidating the design of conservation areas. The result was a system of conservation areas, requiring, in addition to the existing reserve system, 52% of the remaining extant habitat in the planning domain, as well as restorable habitat, that will promote the persistence and continued diversification of much of the region's biota in the face of ongoing habitat loss and climate change. After describing the planning process, we discuss implementation priorities in relation to conservation value and vulnerability to habitat loss, as well as socio-economic, political and institutional constraints and opportunities. #

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“…1, Ojeda et al 1996a) would cause population isolation, making them vulnerable to local extinction (Bond et al 1988). High disturbance regimes would probably increase adult plant mortality and hamper recruitment, amplifying the risk of extinction of isolated populations.…”

Section: Geographical Pattern: a Hypothesismentioning

confidence: 99%

Ecological distribution of four co-occurring Mediterranean heath species

Ojeda¹,

Marañón²

2000

Ecography

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When is an island not an island? Insular effects and their causes in fynbos shrublands

Cited by 62 publications

References 16 publications

Fecundity and Dispersal in Plant Populations: Implications for Structure and Diversity

Fecundity and Dispersal in Plant Populations: Implications for Structure and Diversity

A conservation plan for a global biodiversity hotspot—the Cape Floristic Region, South Africa

Ecological distribution of four co-occurring Mediterranean heath species

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