Rust, Jes ; Singh, Hukam ; Rana, Rajendra S. ; McCann, Tom ; Singh, Lacham ; Anderson, Ken ; Sarkar, Nivedita ; Nascimbene, Paul C. ; Stebner, Frauke ; Thomas, Jennifer C. ; Soló, Monica ; Kraemera, rzano ; Williams, Christopher J. ; Engel, Michael S. ; Sahni, Ashok ; Grimaldi, David (2010) Biogeographic and evolutionary implications of a diverse paleobiota in amber from the early Eocene of India PNAS, 107 (43). pp. 18360-18365. ISSN 0027-8424
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Official URL: http://www.pnas.org/content/107/43/18360.short
Related URL: http://dx.doi.org/10.1073/pnas.1007407107
Abstract
For nearly 100 million years, the India subcontinent drifted from Gondwana until its collision with Asia some 50 Ma, during which time the landmass presumably evolved a highly endemic biota. Recent excavations of rich outcrops of 50-52-million-year-old amber with diverse inclusions from the Cambay Shale of Gujarat, western India address this issue. Cambay amber occurs in lignitic and muddy sediments concentrated by near-shore chenier systems; its chemistry and the anatomy of associated fossil wood indicates a definitive source of Dipterocarpaceae. The amber is very partially polymerized and readily dissolves in organic solvents, thus allowing extraction of whole insects whose cuticle retains microscopic fidelity. Fourteen orders and more than 55 families and 100 species of arthropod inclusions have been discovered thus far, which have affinities to taxa from the Eocene of northern Europe, to the Recent of Australasia, and the Miocene to Recent of tropical America. Thus, India just prior to or immediately following contact shows little biological insularity. A significant diversity of eusocial insects are fossilized, including corbiculate bees, rhinotermitid termites, and modern subfamilies of ants (Formicidae), groups that apparently radiated during the contemporaneous Early Eocene Climatic Optimum or just prior to it during the Paleocene-Eocene Thermal Maximum. Cambay amber preserves a uniquely diverse and early biota of a modern-type of broad-leaf tropical forest, revealing 50 Ma of stasis and change in biological communities of the dipterocarp primary forests that dominate southeastern Asia today.
Item Type: | Article |
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Source: | Copyright of this article belongs to National Academy of Sciences. |
Keywords: | Biogeography; Arthropoda; Eusociality; Tropical Forests |
ID Code: | 43659 |
Deposited On: | 14 Jun 2011 12:08 |
Last Modified: | 18 May 2016 00:34 |
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