Combined with the long-term trend toward increasing aridity, extinctions may have resulted from a complex feedback loop where the loss of large herbivores increased fuel loads and generated more intense fires that were increasingly ignited by humans (Barnosky et al., 2004 and Wroe et al., 2006). Edwards and MacDonald (1991) identified increases in charcoal abundance and shifts in pollen assemblages, but arguments still remain over the chronological resolution and whether or not these are tied to natural or anthropogenic burning
(Bowman, 1998). Evidence for anthropogenic burning in the Americas and Eurasia is more ephemeral, although Robinson et al. (2005) reported evidence for increased charcoal and human burning in eastern North America in the terminal Pleistocene.
Similar to some earlier syntheses (e.g., Nogués-Bravo et al., 2008), Fillios et al. (2010), argue that humans provided the coup de grâce in megafaunal extinctions selleck in Australia, with environmental factors acting as the primary driver. In a recent study, Lorenzen et al. (2011) synthesized archeological, genetic, and climatic data to study the demographic histories of six megafauna species, the wooly rhinoceros, wooly mammoth, wild horse, reindeer, bison, and musk ox. They found that climatic fluctuation was the major driver of population change over the last 50,000 years, but not the sole mechanism. Climate change alone can explain the extinction of the Eurasian musk ox and the wooly rhinoceros, Bosutinib datasheet for example, but the extinction of the Eurasian steppe bison and wild horse was the result of both climatic and anthropogenic influences. Lorenzen et al.’s (2011) findings demonstrate the need for a species by species approach to understanding megafaunal extinctions. The most powerful argument supporting a mix of humans and climate for late Quaternary megafauna extinctions may be the simplest. Given current best age estimates for the arrival of AMH in Australia, Eurasia, and the Americas, a wave of extinctions appears to have occurred shortly
after human colonization of all three continents. In some cases, climate probably contributed significantly to these extinctions, C59 chemical structure in other cases, the connection is not as obvious. Climate and vegetation changes at the Pleistocene–Holocene transition, for example, likely stressed megafauna in North America and South America (Barnosky et al., 2004 and Metcalfe et al., 2010). The early extinction pulse in Eurasia (see Table 3) generally coincides with the arrival of AMH and the later pulse may have resulted from human demographic expansion and the invention of new tool technologies (Barnosky et al., 2004:71). This latter pulse also coincides with warming and vegetation changes at the Pleistocene–Holocene transition. Extinctions in Australia appear to occur shortly after human colonization and are not clearly linked to any climate events (Roberts et al.