Turnover-pulse hypothesis

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The turnover-pulse hypothesis, formulated by

paleontologist Elisabeth Vrba, suggests that major changes to the climate or ecosystem often result in a period of rapid extinction and high turnover of new species (a "pulse") across multiple different lineages. Changes may include climate change, tectonic plate shifting, and catastrophes, among other things.[1] It can be seen as an extension of the concept of evolutionary radiation from a single to a multi-clade context.[2]

Theory

Ecosystems periodically experience significant disruptions which cause

mass extinctions and speciation. Vrba proposes that changes in the climate, through their effect on the physical environment, result in the "division of [animal] populations into geographically and genetically isolated groups", which subsequently evolve into separate species. She also predicts that within an ecosystem this should occur for different groups of animals at roughly the same time, creating a "synchronous pulse" across multiple lineages.[3]

The hypothesis was developed to explain the different patterns of evolution seen in African

Omo river
valley.

Hominins

Vrba later proposed these changes as the spark for the emergence of the

savannah, requiring the hominins to come down from the trees and walk on two legs. The earliest archaeological sites containing tools also date to this period.[7] However, it is still possible that the genus Homo had already evolved before the climate event.[5]

Criticism

The main opposing viewpoint is the Red Queen hypothesis, proposed by Leigh Van Valen, which holds that extinction occurs in a constant turnover, instead of pulses.[8]

Studies on fossils from Turkana basin at the time of the conjectured dramatic shift 2.5 million years ago found that the rate of adaptation was significantly less than had been predicted by the turnover-pulse hypothesis, with a 50% to 60% species turnover spread over 1 million years instead of a 90% turnover in a few hundred thousand.[9][10] Suggested explanations for the discrepancy include that "variations in fossil abundance through time skewed Vrba's data, creating a false peak" or that the "Turkana rift valley—which held a river bounded by woodland at this time—was buffered from the dramatic climatic shifts".

A change to a cooler, dryer climate and at some point between 2.8Ma and 2.5Ma is widely accepted (and corroborated by the composition of sediment layers on the seafloor),[5] but peaks of adaptation among different species in East Africa have been noted at different times, meaning that though "large-mammal evidence is consistent with the idea of a faunal change in the late Pliocene, [...] there is currently no agreement about its extent and precise date."[7]

While there is a consensus that major climatic events cause widespread extinction, other studies of East Africa and other regions have failed to identify any pulse-like events resulting in synchronous evolution or speciation, and this likely relies on local conditions.[4]

References

  1. ^ Bennett, K.D. (1997). Evolution and Ecology: The Pace of Life. Cambridge University Press. pp. 31–32.
  2. ^ "Login". linksource.ebsco.com. Retrieved 2015-10-30.
  3. S2CID 44614708
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  4. ^ .
  5. ^ .
  6. ^ McKee, Jeffrey K (1996). "Faunal Turnover Patterns In The Pliocene And Pleistocene Of Southern Africa". South African Journal of Science. 92 (3): 111.
  7. ^
    PMID 21514622
    .
  8. .
  9. .
  10. ^ Potts, Richard. "Environmental Hypotheses of Hominin Evolution." Yearbook of Physical Anthropology, 1998. Web. 29 Oct. 2015.