Biology:High Arctic camel

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High Arctic camel

The High Arctic camel, from the mid-Pliocene epoch, is a fossil camel related to the fossil genus Paracamelus from which modern camels arose. It is also related to the extinct Ice Age Yukon giant camel.[clarification needed] Collagen-containing fossils were found in 2006 near Strathcona Fiord on Ellesmere Island in Nunavut, Canada. The High Arctic camel lived at least 3.4 million years ago during a warmer period in a boreal-type forest environment.

Fossil discovery

The remains of a High Arctic camel were discovered over several field seasons (2006-2010) in the Strathcona Fiord area of Ellesmere Island, in the Canadian Arctic Archipelago, at about 78°N latitude. About 30 fragments were collected from the Fyles Leaf Bed site and assembled, forming part of a right tibia.[1] The presence of a fibular notch at the distal end of the bone suggests the bone was from an artiodactyl hooved mammal (e.g. cows, deer, camels). Size estimates are consistent with camels, as they were the largest artiodactyls in North America at the time.[2] This is the first evidence of camels in the High Arctic and a new taxon for the mammal assemblage of the Pliocene High Arctic.

Collagen fingerprinting

Collagen fingerprinting showed the fragmentary fossil remains were from a camel and involved comparison of the ancient collagen with that of 37 modern mammal species, as well as the Pleistocene-Aged giant Yukon camel (tentatively referred to the genus Paracamelus).[3] The High Arctic camel was most similar to the one-humped Dromedary camel and the Yukon giant camel.[1]

Age and paleoenvironment

The estimated age of the camel fossil was obtained using a terrestrial cosmogenic nuclide[4] (TCN) burial dating technique,[5][6] which was applied to quartz sand containing the fossils.[1] These deposits are at least 3.4 million years old and equivalent in age to the mammal fossil record in the nearby Beaver Pond fossil site.[7] The deposits hosting the camel remains correlate to the Beaufort Formation,[1] which was emplaced prior the onset of extensive North American glaciation at ~2.6 Ma.[8]

The results showed that the High Arctic camel was most similar to the one-humped Dromedary camel and the Yukon giant camel.[1] Paleoenvironmental reconstruction shows that in the mid-Pliocene the camel would have been living in a landscape that supported a boreal-type forest, dominated by larch trees. At the time, global temperatures are estimated to have been 2 to 3 degrees warmer than today, whereas locally, in the Strathcona Fiord area, temperatures would have been 14 – 22 °C warmer.[9][10][11] Means annual temperature would have been around freezing, with cold and snowy winters.

References

  1. 1.0 1.1 1.2 1.3 1.4 Rybczynski, N., Gosse, J. C., Harington, C. R., Wogelius, R. A., Hidy, A. J., and Buckley, M. (2013). "Mid-Pliocene warm-period deposits in the High Arctic yield insight into camel evolution". Nature Communications 4 (1550): 1550. doi:10.1038/ncomms2516. PMID 23462993. Bibcode2013NatCo...4.1550R. 
  2. Evans, A. R., Jones, D., Boyer, A. G., Brown, J. H., Costa, D. P., Ernest, S. K. M., Fitzgerald, E. M. G., Fortelius, M., Gittleman, J. L., Hamilton, M. J., Harding, L. E., Lintulaakso, K., Lyons, S. K., Okie, J. G., Saarinen, J. J., Sibly, R. M., Smith, F. A., Stephens, P. R., Theodor, J. M., and Uhen, M. D. (2012). "The maximum rate of mammal evolution". Proceedings of the National Academy of Sciences 109 (11): 4187–4190. doi:10.1073/pnas.1120774109. PMID 22308461. Bibcode2012PNAS..109.4187E. 
  3. Harington, C. R. (2011). "Pleistocene vertebrates of the Yukon Territory". Quaternary Science Reviews 30 (17–18): 2341–2354. doi:10.1016/j.quascirev.2011.05.020. Bibcode2011QSRv...30.2341H. 
  4. Gosse, J. C.; Phillips, F. M. (2001). "Terrestrial in situ cosmogenic nuclides: theory and application". Quaternary Science Reviews 20 (14): 1475–1560. doi:10.1016/S0277-3791(00)00171-2. Bibcode2001QSRv...20.1475G. 
  5. Nishiizumi, K., Kohl, C. P., Arnold, J. R., Klein, J., Fink, D., and Middleton, R. (1991). "Cosmic ray produced 10Be and 26Al in Antarctic rocks: exposure and erosion history". Earth and Planetary Science Letters 104 (2): 440–454. doi:10.1016/0012-821X(91)90221-3. Bibcode1991E&PSL.104..440N. 
  6. Granger, D. E. and Muzikar, P. F.; Muzikar (1991). "Dating sediment burial with in situ-produced cosmogenic nuclides: theory, techniques, and limitations". Earth and Planetary Science Letters 188 (1): 269–281. doi:10.1016/S0012-821X(01)00309-0. Bibcode2001E&PSL.188..269G. 
  7. Tedford, R. H. and Harington, C. R.; Harington (2003). "An Arctic mammal fauna from the Early Pliocene of North America". Nature 425 (6956): 425388–425390. doi:10.1038/nature01892. PMID 14508486. Bibcode2003Natur.425..388T. 
  8. Hidy, A. J., Gosse, J. C., Froese, D. G., Bond, J. D., and Rood, D. H.; Gosse; Froese; Bond; Rood (2013). "A latest Pliocene age for the earliest and most extensive Cordilleran Ice Sheet in northwestern Canada". Quaternary Science Reviews 61: 77–84. doi:10.1016/j.quascirev.2012.11.009. Bibcode2013QSRv...61...77H. 
  9. Ballantyne, A. P., Greenwood, D. R., Damste, J. S. S., Csank, A. Z., Eberle, J. J., and Rybczynski, N. (2010). "Significantly warmer Arctic surface temperatures during the Pliocene indicated by multiple independent proxies". Geology 38 (7): 603–606. doi:10.1130/G30815.1. Bibcode2010Geo....38..603B. 
  10. Csank, A. Z., Patterson, W. P., Eglington, B. M., Rybczynski, N., and Basinger, J. F. (2011). "Climate variability in the Early Pliocene Arctic: Annually resolved evidence from stable isotope values of sub-fossil wood, Ellesmere Island, Canada". Palaeogeography, Palaeoclimatology, Palaeoecology 308 (3–4): 339–349. doi:10.1016/j.palaeo.2011.05.038. Bibcode2011PPP...308..339C. 
  11. Csank, A. Z., Tripati, A. K., Patterson, W. P., Eagle, R. A., Rybczynski, N., Ballantyne, A. P., and Eiler, J. M.; Tripati; Patterson; Eagle; Rybczynski; Ballantyne; Eiler (2011). "Estimates of Arctic land surface temperatures during the early Pliocene from two novel proxies". Earth and Planetary Science Letters 304 (3–4): 291–299. doi:10.1016/j.epsl.2011.02.030. Bibcode2011E&PSL.304..291C. 

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