Rate Of Chromosomal Evolution Research Articles

Chromosome evolution in Australian Rattus ? G-banding and hybrid meiosis

The karyotypes of seven species of Australian Rattus were studied by G-banding. When taken in conjunction with molecular data, it is shown that rate of chromosome evolution in the R. sordidus group (R. sordidus, R. villosissimus and R. colletti) has been remarkably rapid and directed entirely towards changes of the Robertsonian type. From data on hybrid fertility it is concluded that the presence of fusions with monobrachial homology contributes more to reduced fertility than fusions per se or genetic differences.

Chromosomal change and rectangular evolution in North American cyprinid fishes

SUMMARYAn important question in evolutionary biology concerns the manner and tempo in which organismal and/or genetic changes that promote evolutionary divergence occur. One recent hypothesis, termedrectangular evolution, holds that most significant evolutionary change occurs during occasional or periodic speciation episodes, with long periods of evolutionary stability in the interim. An alternative view, termedphyletic gradualism, holds that evolutionary divergences proceed by the slow and even accumulation of genetic differences within populations of established species. Two brief tests of rectangular evolution are presented using chromosomal data from North American cyprinid fishes (minnows), a group known to have experienced heterogeneous rates of splitting. Within the rapidly speciated genusNotropis, rates of chromosomal evolution appear slower relative to other, less rapidly speciated confamilial genera. Species ofNotropisalso are less divergent chromosomally, on the average, than are species from other cyprinid genera. These results are in compatible with a rectangular mode of chromosomal divergence these fishes. The results also reveal inconsistencies with a gradual mode chromosomal divergence, but at present this hypothesis cannot be falsified. Consideration of these and other data suggests that different levels of the cyprinid genome may follow independent evolutionary paths.

Rapid speciation and chromosomal evolution in mammals.

To test the hypothesis that population subdivision into small demes promotes both rapid speciation and evolutionary changes in gene arrangement by inbreeding and drift, we estimated rates of speciation and rates of chromosomal evolution in 225 genera of vertebrates. Rates of speciation were estimated by considering the number of living species in each genus and the fossil record of each genus as well as information about extinction rates. Speciation rate was strongly correlated with rate of chromosomal evolution and average rates of speciation in lower vertebrate genera were one-fifth those in mammalian genera. Genera with high karyotypic diversity and rapid speciation rates may generally have small effective population size (Ne), whereas large Ne values may be associated with karyotypically uniform genera and slow rates of speciation. Speciation and chromosomal evolution seem fastest in those genera with species organized into clans or harems (e.g., some primates and horses) or with limited adult vagility and juvenile dispersal, patchy distribution, and strong individual territoriality (e.g., some rodents). This is consistent with the above hypothesis regarding the evolutionary importance of demes.