Matthew G. Powell scite author profile

AimThe latitudinal diversity gradient, in which taxonomic richness is greatest at low latitudes and declines towards the poles, is a pervasive feature of the biota through geological time. This study utilizes fossil data to examine how the latitudinal diversity gradient and associated spatial patterns covaried through the major climate shifts at the onset and end of the late Palaeozoic ice age.Location Data were acquired from fossil localities from around the world. MethodsLatitudinal patterns of diversity, mean geographical range size and macroevolutionary rates were constructed from a literature-derived data base of occurrences of fossil brachiopod genera in space and time. The literature search resulted in a total of 18,596 occurrences for 991 genera from 2320 localities.Results Climate changes associated with the onset of the late Palaeozoic ice age ( c. 327 Ma) altered the biogeographical structure of the brachiopod fauna by the preferential elimination of narrowly distributed, largely tropical genera when glaciation began. Because the oceans were left populated primarily with widespread genera, the slope of the diversity gradient became gentle at this time, and the gradient of average latitudinal range size weakened. In addition, because narrowly distributed genera had intrinsically high rates of origination and extinction, the gradients of both of these macroevolutionary rates were also reduced. These patterns were reversed when the ice age climate abated in early Permian time ( c. 290 Ma): narrowly distributed genera rediversified at low latitudes, restoring steep gradients of diversity, average latitudinal range size and macroevolutionary rates.Main conclusions During late Palaeozoic time, these latitudinal gradients for brachiopods may have been linked by the increased magnitude of seasonality during the late Palaeozoic ice age. Pronounced seasonality would have prevented the existence of genera with narrow latitudinal ranges. These results for the late Palaeozoic ice age suggest a climatic basis for the present-day latitudinal diversity gradient.

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Geographic range and genus longevity of late Paleozoic brachiopods

Powell¹

2007

Paleobiology

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Geographic range size is one of the few traits that promoted survivorship during both mass and background extinctions, but the exact reason (or reasons) why a large geographic range confers extinction resistance remains unclear. Proposed explanations have focused on the roles of dispersal ability, climate tolerance, global abundance, and widespread ranges in predicting taxon longevities. This study uses biogeographic data for late Paleozoic brachiopod genera to test the relative contribution of these traits to genus longevities, using simple but accurate proxy mea surements. The results demonstrate a strong positive relationship between genus longevity and geographic range size, which is robust to several potential errors. Further, latitudinal range, which predominantly reflects climate tolerance, was no more important than longitudinal range, which predominantly reflects dispersal ability, in predicting genus longevities. Rather, longevities were an outcome of the total number of occurrences, which estimates global abundance, and the advan tages of widespread distribution, regardless of which particular traits were responsible for gen erating the total geographic range. The advantages of a large geographic range were apparent dur ing both background and mass extinctions of late Paleozoic time. Although not statistically signif icant, there was a tendency for the greatest selectivity to occur in intervals with the lowest extinc tion rates. The correlation of genus longevity and geographic range size had a profound consequence for the secular pattern of global brachiopod diversity: because the diversity of genera with small geographic ranges was more volatile owing to their correspondingly shorter longevities, global diversity and mean geographic range size paralleled each other almost exactly. Given that the correlation between taxon longevity and geographic range size has also been demonstrated for other taxonomic groups and at other time intervals, these results suggest that global diversity curves compiled from taxonomic databases dominantly reflect changes in the diversity of genera with small geographic ranges.

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Matthew G. Powell

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Geographic range and genus longevity of late Paleozoic brachiopods

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