Molecular systematics of marsupials based on the rRNA 12S mitochondrial gene: the phylogeny of didelphimorphia and of the living fossil microbiotheriid Dromiciops gliroides thomas.

Nucleotide sequence data from the mitochondrial 12S rRNA gene were used to evaluate the phylogenetic relationships among the major groups of didelphimorph and paucituberculatan marsupials from South America, the microbiotheriid Dromiciops gliroides, and representatives of four orders of Australasian marsupials. Based on approximately 800 bp in 18 genera, we conclude that the didelphids constitute a monophyletic group with large-sized forms differentiated from small opossums, while Caluromys constitutes the sister taxon to didelphids. The peramelid Isoodon was recovered as the sister taxon to the paucituberculatans Caenolestes and Rhyncholestes, although it is in an uncertain phylogenetic position within the marsupial tree. Dromiciops was recovered as a well-differentiated lineage from South American opossums within the Australidelphian radiation of metatherians that include dasyurid, diprotodontian, and notoryctemorph marsupials.

Tandem and centric fusions in the chromosomal evolution of the South American phyllotines of the genus Auliscomys (Rodentia, cricetidae).

The karyotypes of three of the four extant species of the genus Auliscomys (A. micropus, living in central [2n = 32, NF = 34] and southern [2n = 34, NF = 36, 37] Chile; A. sublimis [2n = 28, NF = 32] and A. boliviensis [2n = 22, NF = 32], which inhabit the Andean Altiplano) were analyzed. Comparisons of G-, C-, and AgNOR-banded karyotypes showed that extensive conservation of entire chromosomes and chromosomal regions had occurred during the evolution of this genus, with centromeretelomere tandem fusions and centric fusions probably being the most frequent chromosome changes. A chromosomal phylogeny, based on the chromosome homoeologies detected and parsimonious analysis of the nature and distribution of the inferred chromosomal changes, is proposed. This hypothetical phylogeny assumes that the ancestral telocentric karyotype would have undergone three consecutive tandem fusions, first originating the 2n = 32 (NF = 34) karyomorph exhibited by present-day specimens of A. micropus captured in central Chile and then the 2n = 28 (NF = 32) karyotype of A. sublimis. Subsequent centric fusions involving the tandem-fusion products would presumably have generated the 2n = 22 (NF = 32) A. boliviensis karyotype. Assuming some conditions related to early geographic distribution, this chromosomal phylogeny is in agreement with a paleogeographic model, which explains the present distribution of living Auliscomys species mainly on the basis of geologic and climatic events.(ABSTRACT TRUNCATED AT 250 WORDS)

Genome size variation and its phenotypic consequences in Phyllotis rodents.

Constitutive heterochromatin and genome size were studied in Phyllotis darwini, three Phyllotis xanthopygus subspecies, and their interspecific laboratory hybrids. P. darwini, with no or only small C-bands, had the smallest genome size; P. xanthopygus rupestris and P. x. vaccarum, with large C-bands in all the chromosomes, had the largest; and P. x. xanthopygus, with heterochromatin only in a few chromosomes, showed intermediate genome size. To examine some phenotypic consequences of nuclear DNA content, we measured nuclear and cellular surfaces and volumes. Linear regression analyses showed that all these cellular characters had a highly significant direct relationship with genome size. Hybrids had always the expected intermediate parental characteristics. Previous results indicate that P. x. vaccarum should have longer mitotic cycles and lower reproductive capacity than P. darwini. Our findings suggest that the "nucleotypic DNA" hypothesis, which considers genome size as an adaptive feature in higher plants and lower vertebrates, could be extended to these mammals. The analysis of heterochromatin and nuclear DNA amounts of other phyllotine and akodontine rodents supports the idea that small C-bands and genomes are ancestral conditions, from which independent and parallel events occurred until large genomes were produced.

The largest known chromosome number for a mammal, in a South American desert rodent.

Tympanoctomys barrerae, a desert specialist member of the family Octodontidae, until now thought to be conservative, and ancestral to South American hystricognath rodents, presents the highest diploid chromosome number (2n = 102) known in a mammal. Unexpectedly, its karyotype was found to be composed mainly of metacentric to sub-metacentric chromosomes. Mechanisms by which such a karyotype may have been derived are discussed.

Conservation of whole arms during chromosomal divergence of phyllotine rodents.

The assumption of simple fusion in a group showing a constant number of chromosome arms was tested by comparison of the G-band patterns of chromosomes of three Phyllotis species. The karyotypes, each of which has 40 chromosome arms, have a 2n of 38, 38, and 40 and are made up of mostly metacentric chromosomes. Operational concepts describing the amount of matching in G-band patterns are proposed, separating chromosomes or arms into those with total correspondence, partial correspondence, or unique cases. Seven chromosomes and 21 arms out of the total were identical in the three species, denoting a conservation of whole-arm band sequences in this group. A greater number of identical arms than of identical chromosomes were observed, giving some support to the simple fusion hypothesis. An unexpected chromosomal divergence was detected, including chromosomal variation in the C-banded sex chromosomes.