1 / 37

Xingli Giam and Ann Thomas

Effects of livestock grazing and environmental parameters on butterfly species richness and community composition in an East African catena. Xingli Giam and Ann Thomas. Introduction. Anthropogenic land-use change is a major threat to species

lelia
Download Presentation

Xingli Giam and Ann Thomas

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Effects of livestock grazing and environmental parameters on butterfly species richness and community composition in an East African catena XingliGiam and Ann Thomas

  2. Introduction • Anthropogenic land-use change is a major threat to species • Increasing humans and livestock in the Acacia-Commiphorabushlands and thickets of Africa • Environmental degradation owing to heavy grazing (WWF 2001) • In Mpala Conservancy, livestock herding is actively managed to prevent overgrazing and to minimize impacts on the natural habitat • No study has assessed the efficacy of this low intensity and highly-managed form of ranching towards species conservation

  3. 5 4 2 1 3

  4. Research questions 1. Does grazing affect butterfly species composition and result in species turnover between plots? 2. Does grazing affect butterfly species richness? 3. If not, can we identify the transect-level predictors of butterfly species richness?

  5. Field Sites Boma 2 Old Cattle Transition Soil Boma 3 Old Cattle Transition Soil Boma 4 New Sheep Transition Soil Boma 5 Old Cattle Red Soil Boma 1 New Cattle Red soil

  6. Methods 1000 m 500 m 250 m E F G H Boma D C B A 100 m

  7. Methods 25m 10m

  8. Methods

  9. Estimating percent cover

  10. Confounding Factors

  11. Results: Species Richness Estimation through Incidence Rarefaction Curves

  12. Estimating Species Richness Day

  13. Success of Rarefaction Curves • High degree of variation in saturation levels, even between adjacent plots (right) • Rare species estimator • Criteria for Saturation somewhat arbitrary, but: • Percent change from Day 1Day 2 > D2  D3 • RSE ≤ 20% of Day 3 species number • Half the plots fail these criteria (mostly the 2nd)

  14. Effects of Pastoral Practices on Community Composition

  15. Diversity at the Community Level If livestock grazing affects biodiversity, we would expect the community composition of grazed and ungrazed land to differ Hypothesis: Changes in community composition correlate positively with distance from boma to create a “grazing gradient”

  16. Diversity at the Community Level β diversity • Comparison of community composition between two sites • β diversity = ((unique A) + (unique B))/(shared species) Example to the right: β diversity = 1.0 6 unique 4 unique 10 shared

  17. β diversity as a proxy for community homogeneity around bomas Boma 1B Boma 1C Unique to Site 1B: 3 species Unique to Site 1C: 1 species Common to both: 10 species β diversity / shared = 0.4 Perform for all combinations of sites within a boma Plot (β diversity / shared) against distance for each side and across entire boma Small values and small slope indicates homogeneity between sites E F G H Boma D C B A

  18. After Bonferroni correction, no evidence of significant relationship between distance and β diversity

  19. Effect of Soil Type and Boma Age on β diversity

  20. Conclusions from β diversity trends • Lack of relationship between β diversity and distance suggests that ranch pastoral methods do not create a “grazing gradient” on the scale of 100s of meters from the boma • The natural heterogeneity of the environment overshadows any effects of pastoral practices on biodiversity • Alternately, grazing is highly heterogeneous and unrelated to distance from boma; not sufficient data to rule this out

  21. 2. Effect of grazing on butterfly species richness Assumption: Grazing intensity decreases as a function of increasing distance from boma Hypothesis: Species richness will increase with distance from boma as grazing intensity decreases Candidate models: Sij ~ Pois(μij), a ~ N(0, σa2) • μij = exp(β0 + β1Ageij + ai) • μij = exp(β0 + ai), for thejthtransect in ithboma

  22. Results of Distance Analysis • Distance from boma does not predict butterfly species richness across 16 current transects • Suggests that the impact on grazing on butterfly species richness is minimal

  23. 2. Effect of grazing on butterfly species richness Assumption: The effect of grazing is more pronounced in current bomas Hypothesis: Species richness is higher in old bomas compared to current bomas Candidate GLMMs: Sij~ Pois(μij), a ~ N(0, σa2) • μij= exp(β0 + β1Ageij+ ai) • μij= exp(β0 + ai), for thejthtransect in ithboma

  24. Results of age analysis • Status of boma does not predict butterfly species richness across 38 transects • Similar conclusions as Distance analysis – grazing does not seem to affect butterfly species richness

  25. 3. Environmental correlates of butterfly species richness • Data suggests that the impact of grazing on butterfly species richness is minimal • Are there any plot-level environmental factors that predict species richness? • Fitted candidate GLMMs based on a priori hypotheses • Multimodel selection and model using Akaike weights (Burnham & Anderson 2002) • Information-theoretic measure of the likelihood of model i being the best model in the set

  26. Model specification • Species richness is modeled as a poisson count • Non negative integers • Random intercept model • The intercept is allowed to vary among bomas • Transects are nested within bomas • Account for some of the spatial dependence between transects of the same boma • Candidate GLMMs: Sij~ Pois(μij), a ~ N(0, σa2) Sample model: μij = exp(β0 + β1Coverij + β1Shrubij + ai)

  27. Candidate models

  28. Environmental correlates of species richness • Null model is the best (prob ~23%) • Some evidence that species richness increases with the abundance of flowering grasses

  29. Conclusions • Livestock grazing at Mpala does not appear to affect butterfly species diversity • Management regime is effective • Butterfly species richness is largely stochastic at the plot level • Very weak evidence that species richness increases with abundance of flowering grasses • Species observed were not grass feeders • Camouflage, grass flowers, habitat heterogeneity • Species richness might be better characterized at a landscape scale or region scale (e.g., Kerr et al 2001)

  30. Natural History: Time to Meet the Butterflies!

  31. All day generalists Belenois spp. Colotis spp. Catopsiliaflorella Pontiahelice Junoniahierta Vanessa cardui* Zizeeriaknysa Pieridae Nymphalidae Lycaenidae * Entirely absent from Boma 5

  32. All day specialists/rare Pinacopteryxeriphia(Pieridae) Azanusjesous(Lycaenidae) Ziziniaantanossa

  33. Time-sensitive generalists Pieridae Euremabrigitta Junoniaoenone Danauschrysippus Hypolimnusmissippus Chiladeskedonga Nymphalidae Lycaenidae

  34. Rare species Pieridae Dixea spp. Eronialeda Acraeaalicia Charaxeskirkii Neocoenyragregorii Papiliodemodocus Nymphalidae Papilionidae

  35. Thank you!

More Related