Indicator patches: exploiting spatial heterogeneity to improve monitoring systems
C. J. Stokes A D G , R. I. Yeaton A E , M. B. Bayer B F and B. T. Bestelmeyer CA Department of Botany, Research Unit for Plant Growth and Development, University of Natal, P/Bag X01, Scotsville, Pietermaritzburg 3209, South Africa.
B Elsenberg Agricultural Development Institute, Department of Agricultural Development, Private Bag, Elsenberg 7607, South Africa.
C USDA-ARS Jornada Experimental Range, Box 30003 MSC3JER, Las Cruces, New Mexico 88003, USA.
D Present Address: CSIRO Davies Laboratory, PMB PO Aitkenvale, Qld 4814, Australia.
E Present Address: Instituto de Investigación de Zonas Desérticas, Universidad Autónoma de San Luis Potosí, Altair # 200, Fracc. Del Llano, San Luis Potosí 78377, México.
F Present Address: 29 Weltevrede St, Paarl 7646, South Africa.
G Corresponding author. Email: chris.stokes@csiro.au
The Rangeland Journal 31(4) 385-394 https://doi.org/10.1071/RJ08021
Submitted: 17 April 2008 Accepted: 11 September 2009 Published: 27 November 2009
Abstract
When choosing which environmental attributes to monitor in assessing disturbance, it is important to consider not only which metric will provide the most sensitive indicator of disturbance, but also the spatial considerations of where in the landscape that metric will be most responsive to change. Degradation in landscapes is often unevenly expressed because: (i) disturbance is spatially localised, (ii) landscape elements differ in their sensitivity to disturbance, and (iii) degradation following localised disturbance is spatially contagious. The spatial heterogeneity of degradation has proven to be a key obstacle to rangeland monitoring (e.g. where the initiating processes of broad-scale degradation are concentrated in landscape locations that are not detected by surveys) but can also provide opportunities to focus monitoring efforts. We propose that the effectiveness of monitoring could be enhanced by identifying and selectively monitoring ‘indicator patches’, i.e. specific landscape locations that provide the most management-relevant and timely information about the consequences of a monitored disturbance. We tested and demonstrated the utility of the ‘indicator patch’ concept in the rangelands of the Succulent Karoo in southern Africa. We contrasted the grazing response of dominant ‘representative’ vegetation, with responses of interspersed patches of distinct vegetation associated with zoogenic mounds. Since mound vegetation is more palatable and preferentially grazed by sheep, we tested whether mounds could serve as ‘indicator patches’ in providing a sensitive measure of grazing disturbance. Percentage canopy cover measurements in dominant off-mound vegetation provided a poor indicator of grazing disturbance (although more intensive plant size measurements did reveal grazing impacts on plant population dynamics). In contrast, vegetation on mounds displayed patterns of changes in species abundances that were easier to detect and useful for interpreting and quantifying the effects of grazing. Mound vegetation could, therefore, be used as ‘indicator patches’ and targeted for exclusive sampling as a sensitive method for monitoring rangeland condition and detecting early warnings of vegetation change. This approach could be widely employed to better harness the extensive knowledge base regarding the patchy, spatially localised nature of degradation-initiating processes in numerous other landscapes. Routinely incorporating this understanding into the design of monitoring programs could improve the effectiveness of sampling effort, allow detection of more subtle trends (changes), and provide earlier warning of impending degradation so remedial action can be taken before degradation becomes severe and widespread.
Additional keywords: Karoo, plant demographics, rangeland.
Acknowledgements
We wish to thank the Foundation for Research Development for financial support through the Special Program ‘Effects of disturbance on the Karoo’. In addition, we are grateful to the Department of Agricultural Development, and to the owners of the smallholdings for allowing us access to the properties used in this study. We also acknowledge seven reviewers whose comments on previous versions helped improve this paper.
Acocks J. P. H.
(1953) Veld types of South Africa. Memoirs of the Botanical Survey of South Africa 28, 1–192.
Adler P. B.,
Raff D. A., Lauenroth W. K.
(2001) The effect of grazing on the spatial heterogeneity of vegetation. Oecologia 128, 465–479.
| Crossref | GoogleScholarGoogle Scholar |
Aguiar M. R., Sala O. E.
(1999) Patch structure, dynamics and implications for the functioning of arid ecosystems. Trends in Ecology & Evolution 14, 273–277.
| Crossref | GoogleScholarGoogle Scholar |
Armstrong A. J., Siegfried W. R.
(1990) Selective use of heuweltjie earth mounds by sheep in the Karoo. South African Journal of Ecology 1, 77–80.
Augustine D. J.
(2004) Influence of cattle management on habitat selection by impala on central Kenyan rangeland. Journal of Wildlife Management 68, 916–923.
| Crossref | GoogleScholarGoogle Scholar |
Bestelmeyer B. T.,
Trujillo D. A.,
Tugel A. J., Havstad K. M.
(2006a) A multi-scale classification of vegetation dynamics in arid lands: what is the right scale for models, monitoring, and restoration? Journal of Arid Environments 65, 296–318.
| Crossref | GoogleScholarGoogle Scholar |
Bestelmeyer B. T.,
Ward J. P., Havstad K. M.
(2006b) Soil-geomorphic heterogeneity governs patchy vegetation dynamics at an arid ecotone. Ecology 87, 963–973.
| Crossref | GoogleScholarGoogle Scholar | PubMed |
Bestelmeyer B. T.,
Ward J. P.,
Herrick J. E., Tugel A. J.
(2006c) Fragmentation effects on soil aggregate stability in a patchy arid grassland. Rangeland Ecology and Management 59, 406–415.
| Crossref | GoogleScholarGoogle Scholar |
Bisigato A. J., Bertiller M. B.
(1997) Grazing effects on patchy dryland vegetation in northern Patagonia. Journal of Arid Environments 36, 639–653.
| Crossref | GoogleScholarGoogle Scholar |
Bond W. J.,
Stock W. D., Hoffman M. T.
(1994) Has the Karoo spread – a test for desertification using carbon isotopes from soils. South African Journal of Science 90, 391–397.
|
CAS |
Chesselet P.,
Mössmer M., Smith G. F.
(1995) Research priorities in the succulent plant family Mesembryanthemaceae Fenzl. South African Journal of Science 91, 197–209.
Cox G. W.
(1984) The distribution and origin of mima mound grasslands in San Diego County, California. Ecology 65, 1397–1405.
| Crossref | GoogleScholarGoogle Scholar |
Cox G. W., Gakahu C. G.
(1987) Biogeographical relationships of rhizomyid mole rats with mima mound terrain in the Kenya highlands. Pedobiologia 30, 263–275.
Cox G. W., Roig V. G.
(1986) Argentinean mima mounds occupied by ctenomyid rodents. Journal of Mammalogy 67, 428–432.
| Crossref | GoogleScholarGoogle Scholar |
Dean W. R. J.,
Milton S. J., DuPlessis M. A.
(1995) Where, why, and to what extent have rangelands in the Karoo, South Africa, desertified. Environmental Monitoring and Assessment 37, 103–110.
| Crossref | GoogleScholarGoogle Scholar |
Denbow J. R.
(1979) Cenchrus ciliaris; an ecological indicator of Iron Age middens using serial photography in eastern Botswana. South African Journal of Science 75, 405–408.
Dyksterhuis E. J.
(1949) Condition and management of range land based on quantitative ecology. Journal of Range Management 2, 104–115.
| Crossref | GoogleScholarGoogle Scholar |
Esler K. J., Cowling R. M.
(1993) Edaphic factors and competition as determinants of pattern in South-African Karoo vegetation. South African Journal of Botany 59, 287–295.
Friedel M. H.,
Pickup G., Nelson D. J.
(1993) The interpretation of vegetation change in a spatially and temporally diverse arid Australian landscape. Journal of Arid Environments 24, 241–260.
| Crossref | GoogleScholarGoogle Scholar |
Heard C. A. H.,
Tainton N. M.,
Clayton J., Hardy M. B.
(1986) A comparison of five methods for assessing veld condition in the Natal Midlands. Journal of the Grassland Society of Southern Africa 3, 70–76.
Hoffman M. T.,
Bond W. J., Stock W. D.
(1995) Desertification of the eastern Karoo, South Africa: conflicting paleoecological, historical, and soil isotopic evidence. Environmental Monitoring and Assessment 37, 159–177.
| Crossref | GoogleScholarGoogle Scholar |
CAS |
Klijn F., Dehaes H. A. U.
(1994) A hierarchical approach to ecosystems and its implications for ecological land classification. Landscape Ecology 9, 89–104.
Lovegrove B. G., Siegfried W. R.
(1986) Distribution and formation of mima-like earth mounds in the Western Cape Province of South Africa. South African Journal of Science 82, 432–436.
Ludwig J. A.,
Wilcox B. P.,
Breshears D. D.,
Tongway D. J., Imeson A. C.
(2005) Vegetation patches and runoff-erosion as interacting ecohydrological processes in semiarid landscapes. Ecology 86, 288–297.
| Crossref | GoogleScholarGoogle Scholar |
McAuliffe J. R.
(1994) Landscape evolution, soil formation, and ecological patterns and processes in Sonoran Desert bajadas. Ecological Monographs 64, 111–148.
| Crossref | GoogleScholarGoogle Scholar |
Midgley G. F., Musil C. F.
(1990) Substrate effects of zoogenic soil mounds on vegetation composition in the Worcester-Robertson valley, Cape Province. South African Journal of Botany 56, 158–166.
Midgley J. J.,
Harris C.,
Hesse H., Swift A.
(2002) Heuweltjie age and vegetation change based on C-13 and C-14 analyses. South African Journal of Science 98, 202–204.
|
CAS |
Milton S. J., Dean W. R. J.
(1990) Mima-like mounds in the southern and western Cape – are the origins so mysterious. South African Journal of Science 86, 207–208.
Moore J. M., Picker M. D.
(1991) Heuweltjies (earth mounds) in the Clanwilliam District, Cape Province, South Africa – 4000-year-old termite nests. Oecologia 86, 424–432.
| Crossref | GoogleScholarGoogle Scholar |
Pastor J.,
Dewey B.,
Moen R.,
Mladenoff D. J.,
White M., Cohen Y.
(1998) Spatial patterns in the moose–forest–soil ecosystem on Isle Royale, Michigan, USA. Ecological Applications 8, 411–424.
Peters D. P. C.,
Pielke R. A.,
Bestelmeyer B. T.,
Allen C. D.,
Munson-McGee S., Havstad K. M.
(2004) Cross-scale interactions, nonlinearities, and forecasting catastrophic events. Proceedings of the National Academy of Sciences of the United States of America 101, 15130–15135.
| Crossref | GoogleScholarGoogle Scholar |
CAS |
PubMed |
Pickup G.,
Bastin G. N., Chewings V. H.
(1998) Identifying trends in land degradation in non-equilibrium rangelands. Journal of Applied Ecology 35, 365–377.
| Crossref | GoogleScholarGoogle Scholar |
Pringle H. J. R., Landsberg J.
(2004) Predicting the distribution of livestock grazing pressure in rangelands. Austral Ecology 29, 31–39.
| Crossref | GoogleScholarGoogle Scholar |
Pringle H. J. R., Tinley K. L.
(2003) Are we overlooking critical geomorphic determinants of landscape change in Australian rangelands? Ecological Management & Restoration 4, 180–186.
| Crossref | GoogleScholarGoogle Scholar |
Pringle H. J. R.,
Watson I. W., Tinley K. L.
(2006) Landscape improvement, or ongoing degradation – reconciling apparent contradictions from the and rangelands of Western Australia. Landscape Ecology 21, 1267–1279.
| Crossref | GoogleScholarGoogle Scholar |
Riginos C.,
Milton S. J., Wiegand T.
(2005) Context-dependent interactions between adult shrubs and seedlings in a semi-arid shrubland. Journal of Vegetation Science 16, 331–340.
| Crossref | GoogleScholarGoogle Scholar |
Senft R. L.,
Coughenour M. B.,
Bailey D. W.,
Rittenhouse L. R.,
Sala O. E., Swift D. M.
(1987) Large herbivore foraging and ecological hierarchies. Bioscience 37, 789–799.
| Crossref | GoogleScholarGoogle Scholar |
Smitheman J., Perry P.
(1990) A vegetation survey of the Karoo National Botanical Garden Reserve, Worcester. South African Journal of Botany 56, 525–541.
Stokes C. J., Yeaton R. I.
(1994) A line based vegetation sampling technique and its application in succulent Karoo. African Journal of Range and Forage Science 11, 11–17.
Stroh J. C.,
Archer S.,
Doolittle J. A., Wilding L.
(2001) Detection of edaphic discontinuities with ground-penetrating radar and electromagnetic induction. Landscape Ecology 16, 377–390.
| Crossref | GoogleScholarGoogle Scholar |
Swanson F. J.,
Kratz T. K.,
Caine N., Woodmansee R. G.
(1988) Landform effects on ecosystem patterns and processes. Bioscience 38, 92–98.
| Crossref | GoogleScholarGoogle Scholar |
Watson I. W.,
Thomas P. W. E., Fletcher W. J.
(2007) The first assessment, using a rangeland monitoring system, of change in shrub and tree populations across the arid shrublands of Western Australia. The Rangeland Journal 29, 25–37.
| Crossref | GoogleScholarGoogle Scholar |
West N. E.
(2003) Theoretical underpinnings of rangeland monitoring. Arid Land Research and Management 17, 333–346.
| Crossref | GoogleScholarGoogle Scholar |
Willis M. J., Trollope W. S. W.
(1987) Use of key grass species for assessing veld condition in the Eastern Cape. Journal of the Grassland Society of Southern Africa 4, 113–115.
Yeaton R. I.
(1984) Aspects of the population biology of sugar pine (Pinus lambertiana Dougl.) on an elevational gradient in the Sierra Nevada of Central California. American Midland Naturalist 111, 126–137.
| Crossref | GoogleScholarGoogle Scholar |
Yeaton R. I., Esler K. J.
(1990) The dynamics of a succulent Karoo vegetation – a study of species association and recruitment. Vegetatio 88, 103–113.
| Crossref | GoogleScholarGoogle Scholar |
