User:JamaicaPaleoProject/sandbox

Article Evaluation

I chose the page, "Geography of Jamaica" (Geography of Jamaica), for my article evaluation. I chose to evaluate this article because a good understanding of physical geography is fundamental to ecology, and specifically to the subfields of paleoecology and biogeography. Furthermore, my graduate field research site is located in southwestern Jamaica, and I was interested in perusing Wikipedia articles that were pertinent to my academic studies.

I believe that the content of the article, which discussed the physical landforms and landscape of Jamaica, climate, and biota, was relevant to the topic of the article. I did not find any aspects of the article to be distracting. The article was written from a neutral perspective, and the content was unbiased in its representation of the island's geography. I found that the sections that focused on the geology and climate of Jamaica were far more developed relative to the section about vegetation and wildlife. Consequently, I believe that there was an over-representation of information related to physical aspects of Jamaican geography, with a more minimal focus on relationships between the island's geography and ecology.

All the citation web links included in the article work, and the cited sources support the claims made in the article. However, each fact stated in the article is not referenced with an appropriate citation, and I find that one of the few cited sources, FiWi Roots.com--a non-profit organization committed to celebrating and commemorating Jamaican culture and natural history--may qualify as a biased source. Information from that site may not have undergone an adequate peer review process, and might be intentionally stated in a fashion that highlights only certain facts about Jamaica. On the other hand, the other sources referenced--a published journal article and the book "Encyclopedia of Earth", which was commissioned by the National Council for Science and the Environment, appear to be neutral, reputable, and unbiased sources. The content of the article is up-to-date, however, I believe that the article could be improved by further developing the section titled "Vegetation and wildlife". Increased attention could be paid to discussing the modern plant and animal communities inhabiting the island, with special references to endemism, endangered species and areas of high conservation importance. Furthermore, the article would benefit from placing Jamaican ecological communities in the broader context of global species diversity, and also within the framework of current global and local biodiversity stressors.

Several conversations were initiated on the article's talk page, mostly centered on the clarification of facts included in the article, proposing images that could be placed in the article (e.g. a physical map of Jamaica), and outlining revisions or suggestions that could enhance the overall quality of the article. The article is a part of WikiProject Caribbean and WikiProject Geology, and is rated as "High-importance" and "Low-importance" respectively, on each of the WikiProject's importance scales. Some comments and suggestions mentioned on the article's Talk page were presented without specifically identifying the sections that needed revision--that is, comments were vague--or, supporting facts were offered without any associated citations/references. In class and during the online training, an important point that was raised was to be courteous and thorough while making suggestions on the Wikipedia Talk page, and to add fact-based, reputable information from reliable sources to article discussions. Furthermore, the original sources containing the facts to be added should be referenced at all points throughout the Wikipedia editing process.

Optional assignment: Completed on article's Talk page.

Assigned Article-Megafauna

I plan to update the subsection of the article titled Megafauna called "Consequences of depletion of megafauna". This subsection currently discusses the effects of megafaunal populations on nutrient transport and methane emissions; however, the article lacks substantive information about megafaunal impacts on vegetation communities. I believe that the article would benefit from the inclusion of information about the effects of megafaunal extinction on the composition, structure and diversity of plant communities, in addition to a broader discussion about how these ecological changes may influence physical environmental factors such as landscape openness, light availability, and fire regimes. My current plan for updating the article focuses on three primary mechanisms by which megafaunal activity or collapse can alter vegetation dynamics: 1) selective grazing/browsing, 2) seed dispersal of megafauna-adapted plants, and 3) physical modification of the environment via trampling, uprooting of large trees etc. Furthermore, I plan to discuss the relationship between megafauna and these ecological processes using information from both modern observations and field experiments, and the paleoecological record. It is my hope that outlining the impacts of megafauna on vegetation communities and landscapes will further illuminate the ecological implications of past and present megafaunal declines, and ultimately, improve the overall quality of the chosen Wikipedia article.

In order to comprehensively address my discussion points, I will rely on information from the sources listed below:

Bibliography

Bakker, E.S., Gill, J.L., Johnson, C.N., Vera, F.W., Sandom, C.J., Asner, G.P. and Svenning, J.C. 2016. Combining paleo-data and modern exclosure experiments to assess the impact of megafauna extinctions on woody vegetation. Proceedings of the National Academy of Sciences 113(4): 847-855.

Johnson, C.N. 2009. Ecological consequences of Late Quaternary extinctions of megafauna. Proceedings of the Royal Society of London B: Biological Sciences, DOI: 10.1098/rspb.2008.1921.

Rule, S., Brook, B.W., Haberle, S.G., Turney, C.S., Kershaw, A.P. and Johnson, C.N. 2012. The aftermath of megafaunal extinction: ecosystem transformation in Pleistocene Australia. Science 335(6075): 1483-1486.

Gill, J.L. 2014. Ecological impacts of the late Quaternary megaherbivore extinctions. New Phytologist 201(4): 1163-1169.

Gill, J.L., Williams, J.W., Jackson, S.T., Lininger, K.B. and Robinson, G.S. 2009. Pleistocene megafaunal collapse, novel plant communities, and enhanced fire regimes in North America. Science 326(5956): 1100-1103.

Guimarães Jr, P.R., Galetti, M. and Jordano, P. 2008. Seed dispersal anachronisms: rethinking the fruits extinct megafauna ate. PloS One 3(3): e1745. https://doi.org/10.1371/journal.pone.0001745

Janzen, D.H. and Martin, P.S. 1982. Neotropical anachronisms: the fruits the gomphotheres ate. Science 215(4528): 19-27.

Campos-Arceiz, A. and Blake, S. 2011. Megagardeners of the forest–the role of elephants in seed dispersal. Acta Oecologica 37(6): 542-553.

Zaya, D.N. and Howe, H.F. 2009. The anomalous Kentucky coffeetree: megafaunal fruit sinking to extinction?. Oecologia 161(2): 221-226.

Waldram, M.S., Bond, W.J. and Stock, W.D. 2008. Ecological engineering by a mega-grazer: white rhino impacts on a South African savanna. Ecosystems 11(1): 101-112.

Sandom, C.J., Ejrnæs, R., Hansen, M.D. and Svenning, J.C. 2014. High herbivore density associated with vegetation diversity in interglacial ecosystems. Proceedings of the National Academy of Sciences 111(11): 4162-4167.

Guldemond, R. and Van Aarde, R. 2008. A meta-analysis of the impact of African elephants on savanna vegetation. Journal of Wildlife Management 72(4): 892-899.

Haynes, G. 2012. Elephants (and extinct relatives) as earth-movers and ecosystem engineers. Geomorphology 157: 99-107.

Owen-Smith, N. 1987. Pleistocene extinctions: the pivotal role of megaherbivores. Paleobiology 13(3): 351-362.

Doughty, C.E., Faurby, S. and Svenning, J.C. 2016. The impact of the megafauna extinctions on savanna woody cover in South America. Ecography 39(2): 213-222.

Zimov, S.A., Chuprynin, V.I., Oreshko, A.P., Chapin III, F.S., Reynolds, J.F. and Chapin, M.C. 1995. Steppe-tundra transition: a herbivore-driven biome shift at the end of the Pleistocene. The American Naturalist 146(5): 765-794.

Brown, J.R. and Archer, S. 1988. Woody plant seed dispersal and gap formation in a North American subtropical savanna woodland: the role of domestic herbivores. Vegetatio 73(2): 73-80.

Assigned Article Workspace

Effects of Megafauna on Vegetation

Megafauna, as a result of their large body size and unique life history traits (e.g. high trophic requirements, large home ranges)^[1], can cause significant alteration to vegetation communities. These ecological changes may precipitate as shifts in the composition and/or structure of the vegetation of a region, or as distributional shifts in the ranges of different plant species. Furthermore, the resulting changes in vegetation dynamics can modify the abiotic environment in myriad ways, including changes in understory light availability, landscape openness, and the frequency and intensity of fire events^[2]. Consequently, many megafaunal species have been classified as "keystone species" or "ecosystem engineers", due to their strong and wide-ranging impacts on ecological function and processes, and the disproportionately large effects that these changes have on the biodiversity of ecological communities. Megafaunal activity, or the lack thereof, can alter vegetation dynamics via selective browsing and/or grazing on different plant taxa, acting as seed dispersers, and physical modification of the structural environment. Evidence for the role of megafauna in shaping vegetation communities via the above-mentioned mechanisms arises from both the paleoecological record, and from contemporary field experiments and observations. These studies highlight the important ecological ramifications of megafaunal loss in both past and present temporal contexts, and draw attention to the ongoing decline of megafauna being experienced at the global scale^[3].

Megafaunal decline can have significant impacts on the composition and structure of vegetation communities, as a result of the release from herbivory of plant taxa that megafaunal species preferentially feed upon. That is, high megafaunal abundances limit the proliferation of certain plant species due to selective feeding behaviors, and a decrease in megafaunal populations causes a relaxation of herbivory pressure, and consequent increases in plants that were heavily browsed/grazed upon. For example, a multi-proxy paleoecological record from the upper Midwestern United States indicated that the collapse of local megafaunal populations at approximately 13,700 years ago was associated with the proliferation of the hardwood tree species, black ash (Fraxinus nigra), hophornbeam (Ostrya) and ironwood (Carpinus), coeval with a period of high spruce (Picea) abundances. The composition of plant species in the resultant vegetation community, that is, abundant hardwood trees and spruce, has no present-day analog^[4]. Similarly, the analysis of pollen, charcoal, and Sporormiella abundances in swamp sediments collected from northeastern Australia, suggested that megafaunal declines at approximately 41,000 years ago were linked to a shift from rainforest-type vegetation to dominance by grasses and sclerophyllous taxa^[5]. In both of the above-mentioned studies, increased fire regimes followed the decline of megafauna, and the researchers hypothesized that the observed enhancement of fire intensity was at least partly due to the accumulation of fuel that would have been otherwise consumed by the once-abundant megafauna.

 

African elephant (Loxodonta africana) feeding on a toppled Acacia tree.

A contemporary exclusion experiment conducted in the semi-arid savanna of Kenya demonstrated that selective feeding of large herbivores resulted in a shift in plant community dominance from palatable, broad-leaved species, such as Grewia tenax, to unpalatable, thorny shrubs, such as Acacia^[6]. Indeed, modern experimental evidence suggests that increased thorn length and density are inducible plant defensive responses that serve to reduce herbivory^[7][8], thus highlighting the important role of plant-herbivore interactions in determining savannah vegetation structure and composition^[9]. Close to a decade of monitoring at the Ithala Game Reserve, South Africa revealed that heavy feeding activity by elephants, black rhinoceros and other browsers was associated with significant shifts in plant community composition, including sharp declines in Aloe marlothii, Acacia nilotica, Acacia davyi and other woodland species, and increased abundances of unpalatable species, such as Euclea racemosa and Euclea crispa^[10]. Researchers documented significant reductions in Acacia spp. abundances after giraffe introduction to a southern African savannah, while noting that areas with steep terrain that provided spatial refugia from giraffe browsing did not experience similar elevated levels of tree mortality^[11].

Large herbivore removal from vegetated areas can also have significant influences on the frequency and intensity of disturbance events via controlling the landscape availability of flammable biomass. For example, megaherbivore exclosures in a wooded African savannah were associated with increased tree densities and fine fuel accumulation, which resulted in more intense fires^[12]. Selective moose (Alces alces) browsing can shift forest community composition from deciduous trees (e.g. Populus tremuloides, Betula, Corylus) to spruce (Picea) dominance, which reduces nutrient availability and net primary productivity due to decreased quality of leaf litter inputs to the soil^[13]. Results from paleoecological studies as well as modern experiments indicate that shifts in vegetation community composition and structure may result from megafaunal decline, and thus constitutes an important ecological consequence of megafaunal loss from ecosystems. These ecological changes may modify abiotic processes, such as fire regimes and biogeochemical cycling, and can have differential cascading effects on the diversity of other fauna that co-inhabit the affected ecosystems, including ants^[12], spiders^[14], and rodents^[15].

 

Spondias mombin tree with large fruits, which are hypothesized to have evolved for dispersal by megafauna^[16].

Megafaunal decline could result in the disruption of seed dispersal relationships between plants with megafauna-adapted dispersal traits and imperiled large herbivores. Plant species that are vulnerable to the loss of seed dispersal services provided by megafauna exhibit a suite of seed and fruit traits that is collectively referred to as "megafaunal dispersal syndrome". These traits include: large fruits, large seeds that are often covered by a thick seed coat or smaller seeds that are encased in a hard nut, fruits that fall off the tree prior to or at maturation, fruits that do not typically attract arboreal and volant dispersers, fruits that are consumed freely by modern domesticated animals like horses and cattle or extant megafauna such as elephants and tapirs, and trees that are usually not found in areas that are inaccessible to potential megafauna dispersers, such as steep slopes. Given that global megafauna populations plummeted after the end-Pleistocene extinction event, the observation of these megafauna-adapted seed and fruit traits in numerous plant species suggest that many extant plants may already experience dispersal limitation problems as a result of the loss of their co-evolved dispersal agents, or a lack of suitable surrogate dispersers that may wholly or partially compensate for past megafaunal declines. However, the characteristic traits that define megafauna dispersal syndrome would have been ecologically advantageous in the context of prehistoric megafauna-rich ecosystems. Extant plant species that have seed and fruit traits consistent with megafaunal dispersal syndrome include, but are not limited to: Crescentia alata, Prosopis juliflora, Balanites wilsoniana, and Spondias spp.^[17].

Contemporary research has illuminated the key role of extant megafauna in seed dispersal processes, and thus, in maintaining landscape-level tree diversity. A literature analysis showed that elephants either consume the fruit or disperse the seed of approximately 450 plant species from about 268 genera across their range, giving them the name "megagardeners of the forest"^[18]. Furthermore, a study in the Democratic Republic of Congo found that fourteen forest tree species were dependent on elephants for seed dispersal, and these tree species experienced poor recruitment due to poaching-induced elephant decline and consequent increases in density-dependent seedling mortality^[19]. Endemic Galapagos tortoises (Chelonoidis nigra) were found to be effective long distance seed dispersers of both native and introduced plants, dispersing the seeds of approximately 45 plant species up to several thousand meters away from the parent plant^[20]. Similarly, Greater one-horned rhinoceroses (Rhinoceros unicornis) were shown to be important dispersers of the megafauna-adapted plant Trewia nudiflora in southern Nepal, as they transport and deposit large numbers of its seeds, and promote seedling growth via the provision of nutrients in manure^[21]. Further megafaunal decline has the potential to disrupt coevolutionary interactions between plants and their large-bodied seed dispersal agents, which may lead to future compositional shifts in vegetation, range reductions and poor recruitment in megafauna-adapted plant species, and at the extreme, local extirpation and species extinction, particularly in the absence of compensatory dispersal strategies.

 

An Asian elephant (Elephas maximus) debarking a tree for food.

The widespread impacts of megafaunal activity, including uprooting of trees, bark removal, and branch breaking, on the physical structure of vegetation are well-documented, particularly in regions such as Africa, where extant megafauna occur at high densities. Male elephants can topple over four trees per day annually, and up to nine trees per day during the dry season^[22]. A study in northeastern South Africa demonstrated that mean treefall rates were five times higher in areas that contained elephants compared to an adjacent nature reserve that lacked elephants^[23]. Similarly, high elephant densities in the Zambezi Valley escarpment of Zimbabwe were associated with reductions in tree cover and density, and increased shrub encroachment, which resulted in a decline in the diversity of ants and woodland birds in elephant-impacted habitats^[24]. Vegetation modification by elephants can increase landscape openness and light penetration through the canopy, which facilitates gap colonization by herbs and grasses, and promotes formation of woodland-grassland mosaic habitats. These vegetation shifts can result in an increase in grazers and decrease in browsers where elephant activity has facilitated the spread of grasses^[25]. Elephant damage to woody trees has also been shown to have a positive effect on herpetofaunal species richness due to the creation of new habitats that can be utilized for hunting, breeding, and/or for refugia from predators^[26]. Similar positive effects were reported for local population densities of the gecko Lygodactylus keniensis in areas with high densities of elephant-damaged trees, due to the creation of refugia for the lizards via bark stripping and branch breaking^[27]. Paleoecological and paleontological evidence also point to the transformative ecological role of extinct megafauna in prehistoric ecosystems^[28]. Indeed, researchers hypothesize that megafauna trampling caused a shift in dominance from mosses to fast-growing grasses in tundra ecosystems, and was a critical ecological process for maintaining the iconic Pleistocene mammoth-steppe biome^[29][30]. Previous research highlights the key role of megafauna as ecosystem engineers that can alter the three-dimensional structure of plant communities by using brute force to physically modify woody vegetation. These megafauna-induced changes in the structural characteristics of vegetation communities can have significant impacts on both plant and animal diversity and ecological interactions, and would be greatly minimized in the event of megafaunal population decline.

Megafauna diversity has a critical role in influencing the vegetation dynamics of ecosystems, whereby past fluctuations in megafaunal populations have been implicated as the primary driving force behind large-scale reorganizations of regional plant communities^[4], and biome-scale changes in vegetation patterns^[29]. Contemporary studies also highlight how the reintroduction of megafaunal species to areas where they were historically absent can restore key ecological functions and processes related to vegetation, and thus, from a biodiversity and conservation management standpoint, induce ecosystems to shift towards a more desirable state^[31][32]. Consequently, severe declines in megafaunal population numbers, local extirpation, or extinction represent a loss of these important ecological services, and can confer major changes to the stability and resilience of vegetation communities. Extant megafauna are experiencing severe population declines at the global scale due to a variety of factors, including poaching, habitat fragmentation, climate change, and human and livestock encroachment^[3]. The ecological impacts of this most recent wave of declines in megafaunal populations on vegetation community composition, structure and function pose several unresolved questions and remains a field of active research^{[33][34][35][36]}.

This is a user sandbox of JamaicaPaleoProject. You can use it for testing or practicing edits. This is not the sandbox where you should draft your assigned article for a dashboard.wikiedu.org course. To find the right sandbox for your assignment, visit your Dashboard course page and follow the Sandbox Draft link for your assigned article in the My Articles section. Get Help

1. Owen-Smith, R.N. (1992). Megaherbivores: the influence of very large body size on ecology. Cambridge University Press.
2. Laws, RM (January 1970). "Elephants as agents of habitat and landscape change in East Africa". Oikos. 1: 1–5 – via JSTOR.
3. Ripple, William J.; Newsome, Thomas M.; Wolf, Christopher; Dirzo, Rodolfo; Everatt, Kristoffer T.; Galetti, Mauro; Hayward, Matt W.; Kerley, Graham I. H.; Levi, Taal (2015-05-01). "Collapse of the world's largest herbivores". Science Advances. 1 (4): e1400103. doi:10.1126/sciadv.1400103. ISSN 2375-2548. PMC 4640652. PMID 26601172.
4. Gill, Jacquelyn L.; Williams, John W.; Jackson, Stephen T.; Lininger, Katherine B.; Robinson, Guy S. (2009-11-20). "Pleistocene Megafaunal Collapse, Novel Plant Communities, and Enhanced Fire Regimes in North America". Science. 326 (5956): 1100–1103. doi:10.1126/science.1179504. ISSN 0036-8075. PMID 19965426.
5. Rule, Susan; Brook, Barry W.; Haberle, Simon G.; Turney, Chris S. M.; Kershaw, A. Peter; Johnson, Christopher N. (2012-03-23). "The Aftermath of Megafaunal Extinction: Ecosystem Transformation in Pleistocene Australia". Science. 335 (6075): 1483–1486. doi:10.1126/science.1214261. ISSN 0036-8075. PMID 22442481.
6. Augustine, David J.; Mcnaughton, Samuel J. (2004-02-12). "Regulation of shrub dynamics by native browsing ungulates on East African rangeland". Journal of Applied Ecology. 41 (1): 45–58. doi:10.1111/j.1365-2664.2004.00864.x. ISSN 0021-8901.
7. Milewski, A. V.; Young, Truman P.; Madden, Derek (1991-03-01). "Thorns as induced defenses: experimental evidence". Oecologia. 86 (1): 70–75. doi:10.1007/BF00317391. ISSN 0029-8549.
8. GOWDA, J. H. (February 1997). "Physical and chemical response of juvenile Acacia tortilis trees to browsing. Experimental evidence". Functional Ecology. 11 (1): 106–111. doi:10.1046/j.1365-2435.1997.00065.x. ISSN 0269-8463.
9. Charles-Dominique, Tristan; Davies, T. Jonathan; Hempson, Gareth P.; Bezeng, Bezeng S.; Daru, Barnabas H.; Kabongo, Ronny M.; Maurin, Olivier; Muasya, A. Muthama; Bank, Michelle van der (2016-09-20). "Spiny plants, mammal browsers, and the origin of African savannas". Proceedings of the National Academy of Sciences. 113 (38): E5572–E5579. doi:10.1073/pnas.1607493113. ISSN 0027-8424. PMC 5035896. PMID 27601649.
10. Wiseman, Ruth (April 2004). "Woody vegetation change in response to browsing in Ithala Game Reserve, South Africa". South African Journal of Wildlife Research. 34(1): 25–37.
11. Bond and Loffell (2001). "Introduction of giraffe changes acacia distribution in a South African savanna". African Journal of Ecology. 39(3): 286–294.
12. Kimuyu, Duncan M. (June 2014). "Native and domestic browsers and grazers reduce fuels, fire temperatures, and acacia ant mortality in an African savanna". Ecological Applications. 24(4): 741–749.
13. Pastor, J.; Dewey, B.; Naiman, R. J.; McInnes, P. F.; Cohen, Y. (March 1993). "Moose Browsing and Soil Fertility in the Boreal Forests of Isle Royale National Park". Ecology. 74 (2): 467–480. doi:10.2307/1939308. ISSN 0012-9658.
14. Warui, Charles M.; Villet, Martin H.; Young, Truman P.; Jocqué, Rudy (2005-08-01). "Influence of grazing by large mammals on the spider community of a kenyan savanna biome". Journal of Arachnology. 33 (2): 269–279. doi:10.1636/CT05-43.1. ISSN 0161-8202.
15. Hagenah, Nicole; et al. (September 2009). "Effects of large herbivores on murid rodents in a South African savanna". Journal of Tropical Ecology. 25(5): 483–492. {{cite journal}}: Explicit use of et al. in: |last= (help)
16. Janzen, Daniel H. (May 1985). "Spondias mombin is culturally deprived in megafauna-free forest". Journal of Tropical Ecology. 1(2): 131–155.
17. Janzen, Daniel H.; Martin, Paul S. (1982-01-01). "Neotropical Anachronisms: The Fruits the Gomphotheres Ate". Science. 215 (4528): 19–27. doi:10.1126/science.215.4528.19. ISSN 0036-8075. PMID 17790450.
18. Campos-Arceiz and Blake (November–December 2011). "Megagardeners of the forest – the role of elephants in seed dispersal". Acta Oecologica. 37(6): 542–553 – via Elsevier.
19. Beaune, David; et al. (May 2013). "Doom of the elephant-dependent trees in a Congo tropical forest". Forest Ecology and Management. 295: 109–117 – via Elsevier. {{cite journal}}: Explicit use of et al. in: |last= (help)
20. Blake, Stephen; Wikelski, Martin; Cabrera, Fredy; Guezou, Anne; Silva, Miriam; Sadeghayobi, E.; Yackulic, Charles B.; Jaramillo, Patricia (2012-01-27). "Seed dispersal by Galápagos tortoises". Journal of Biogeography. 39 (11): 1961–1972. doi:10.1111/j.1365-2699.2011.02672.x. ISSN 0305-0270.
21. Dinerstein, Eric; Wemmer, Chris M. (December 1988). "Fruits Rhinoceros Eat: Dispersal of Trewia Nudiflora (Euphorbiaceae) in Lowland Nepal". Ecology. 69 (6): 1768–1774. doi:10.2307/1941155. ISSN 0012-9658.
22. Guy, P.R. (January 1976). "The feeding behaviour of elephant (Loxodonta africana) in the Sengwa Area Rhodesia". South African Journal of Wildlife Research. 6(1): 55–63.
23. Mograbi, Penelope J.; Asner, Gregory P.; Witkowski, Ed T. F.; Erasmus, Barend F. N.; Wessels, Konrad J.; Mathieu, Renaud; Vaughn, Nicholas R. (2017-01-19). "Humans and elephants as treefall drivers in African savannas". Ecography. 40 (11): 1274–1284. doi:10.1111/ecog.02549. ISSN 0906-7590.
24. Cumming, David (May 1997). "Elephants, woodlands and biodiversity in southern Africa" (PDF). South African Journal of Science. 93: 231–236.
25. Western, David (1989). "The ecological role of elephants in Africa" (PDF). Pachyderm. 12(1): 42–48.
26. Nasseri, Nabil A.; McBrayer, Lance D.; Schulte, Bruce A. (2010-10-06). "The impact of tree modification by African elephant (Loxodonta africana) on herpetofaunal species richness in northern Tanzania". African Journal of Ecology. 49 (2): 133–140. doi:10.1111/j.1365-2028.2010.01238.x. ISSN 0141-6707.
27. Pringle, Robert M. (January 2008). "ELEPHANTS AS AGENTS OF HABITAT CREATION FOR SMALL VERTEBRATES AT THE PATCH SCALE". Ecology. 89(1): 26–33.
28. Haynes, Gary (July 2012). "Elephants (and extinct relatives) as earth-movers and ecosystem engineers". Geomorphology. 157–158: 99–107 – via Elsevier ScienceDirect.
29. Zimov, S. A.; Chuprynin, V. I.; Oreshko, A. P.; Chapin, F. S.; Reynolds, J. F.; Chapin, M. C. (1995-11-01). "Steppe-Tundra Transition: A Herbivore-Driven Biome Shift at the End of the Pleistocene". The American Naturalist. 146 (5): 765–794. doi:10.1086/285824. ISSN 0003-0147.
30. Zimov, S.A.; et al. (December 2012). "Mammoth steppe: a high-productivity phenomenon". Quaternary Science Reviews. 57: 26–45 – via Elsevier ScienceDirect. {{cite journal}}: Explicit use of et al. in: |last= (help)
31. Svenning, Jens-Christian; Pedersen, Pil B. M.; Donlan, C. Josh; Ejrnæs, Rasmus; Faurby, Søren; Galetti, Mauro; Hansen, Dennis M.; Sandel, Brody; Sandom, Christopher J. (2016-01-26). "Science for a wilder Anthropocene: Synthesis and future directions for trophic rewilding research". Proceedings of the National Academy of Sciences. 113 (4): 898–906. doi:10.1073/pnas.1502556112. ISSN 0027-8424. PMC 4743824. PMID 26504218.
32. Hansen, Dennis M.; et al. (June 2010). "Ecological history and latent conservation potential: large and giant tortoises as a model for taxon substitutions". Ecography. 33(2): 272–284. {{cite journal}}: Explicit use of et al. in: |last= (help)
33. Hoag, Colin; Svenning, Jens-Christian (2017-10-17). "African Environmental Change from the Pleistocene to the Anthropocene". Annual Review of Environment and Resources. 42 (1): 27–54. doi:10.1146/annurev-environ-102016-060653. ISSN 1543-5938.
34. Galetti, Mauro; et al. (November 2016). "Reversing defaunation by trophic rewilding in empty forests". Biotropica. 49(1): 5–8. {{cite journal}}: Explicit use of et al. in: |last= (help)
35. Hempson, Gareth P.; et al. (December 2017). "The consequences of replacing wildlife with livestock in Africa". Scientific Reports. 7(1): 17196. {{cite journal}}: Explicit use of et al. in: |last= (help)
36. Malhi, Yadvinder; Doughty, Christopher E.; Galetti, Mauro; Smith, Felisa A.; Svenning, Jens-Christian; Terborgh, John W. (2016-01-26). "Megafauna and ecosystem function from the Pleistocene to the Anthropocene". Proceedings of the National Academy of Sciences. 113 (4): 838–846. doi:10.1073/pnas.1502540113. ISSN 0027-8424. PMC 4743772. PMID 26811442.