Molecular phylogeny, biogeography, and habitat preference evolution of marsupials.

Marsupials exhibit great diversity in ecology and morphology. However, compared with their sister group, the placental mammals, our understanding of many aspects of marsupial evolution remains limited. We use 101 mitochondrial genomes and data from 26 nuclear loci to reconstruct a dated phylogeny including 97% of extant genera and 58% of modern marsupial species. This tree allows us to analyze the evolution of habitat preference and geographic distributions of marsupial species through time. We found a pattern of mesic-adapted lineages evolving to use more arid and open habitats, which is broadly consistent with regional climate and environmental change. However, contrary to the general trend, several lineages subsequently appear to have reverted from drier to more mesic habitats. Biogeographic reconstructions suggest that current views on the connectivity between Australia and New Guinea/Wallacea during the Miocene and Pliocene need to be revised. The antiquity of several endemic New Guinean clades strongly suggests a substantially older period of connection stretching back to the Middle Miocene and implies that New Guinea was colonized by multiple clades almost immediately after its principal formation.

Revising the recent evolutionary history of equids using ancient DNA.

The rich fossil record of the family Equidae (Mammalia: Perissodactyla) over the past 55 MY has made it an icon for the patterns and processes of macroevolution. Despite this, many aspects of equid phylogenetic relationships and taxonomy remain unresolved. Recent genetic analyses of extinct equids have revealed unexpected evolutionary patterns and a need for major revisions at the generic, subgeneric, and species levels. To investigate this issue we examine 35 ancient equid specimens from four geographic regions (South America, Europe, Southwest Asia, and South Africa), of which 22 delivered 87-688 bp of reproducible aDNA mitochondrial sequence. Phylogenetic analyses support a major revision of the recent evolutionary history of equids and reveal two new species, a South American hippidion and a descendant of a basal lineage potentially related to Middle Pleistocene equids. Sequences from specimens assigned to the giant extinct Cape zebra, Equus capensis, formed a separate clade within the modern plain zebra species, a phenotypicically plastic group that also included the extinct quagga. In addition, we revise the currently recognized extinction times for two hemione-related equid groups. However, it is apparent that the current dataset cannot solve all of the taxonomic and phylogenetic questions relevant to the evolution of Equus. In light of these findings, we propose a rapid DNA barcoding approach to evaluate the taxonomic status of the many Late Pleistocene fossil Equidae species that have been described from purely morphological analyses.

Novel sequence elements define ancestral haplotypes of the region encompassing complement factor H.

The genomic region encompassing complement factor H (CFH) is thought to be important in determining susceptibility to inflammatory diseases such as age-related macular degeneration, but only limited polymorphism has been described. After applying the genomic matching technique to three-generation families and an ethnically diverse reference panel we have demonstrated that the polymorphism resembles that found in the major histocompatibility complex. The different ancestral haplotypes carry either T or C at T1277C but also other more polymorphic alleles over a region of 2 Mb. Thus the association between age-related macular degeneration and T1277 or Y402 actually reflects multiple linked polymorphisms including an indel that cannot be dissected from any direct effect of Y402 and may be more important. We show for the first time that simple algorithms can identify genomic sequence elements that appear to be more useful haplospecific markers than single nucleotide polymorphism or microsatellites.

Ancient DNA clarifies the evolutionary history of American Late Pleistocene equids.

Hippidions are past members of the equid lineage which appeared in the South American fossil record around 2.5 Ma but then became extinct during the great late Pleistocene megafaunal extinction. According to fossil records and numerous dental, cranial, and postcranial characters, Hippidion and Equus lineages were expected to cluster in two distinct phylogenetic groups that diverged at least 10 MY, long before the emergence of the first Equus. However, the first DNA sequence information retrieved from Hippidion fossils supported a striking different phylogeny, with hippidions nesting inside a paraphyletic group of Equus. This result indicated either that the currently accepted phylogenetic tree of equids was incorrect regarding the timing of the evolutionary split between Hippidion and Equus or that the taxonomic identification of the hippidion fossils used for DNA analysis needed to be reexamined (and attributed to another extinct South American member of the equid lineage). The most likely candidate for the latter explanation is Equus (Amerhippus) neogeus. Here, we show by retrieving new ancient mtDNA sequences that hippidions and Equus (Amerhippus) neogeus were members of two distinct lineages. Furthermore, using a rigorous phylogenetic approach, we demonstrate that while formerly the largest equid from Southern America, Equus (Amerhippus) was just a member of the species Equus caballus. This new data increases the known phenotypic plasticity of horses and consequently casts doubt on the taxonomic validity of the subgenus Equus (Amerhippus).

A common site within factor H SCR 7 responsible for binding heparin, C-reactive protein and streptococcal M protein.

The complement inhibitor factor H (fH) interacts via its seventh short consensus repeat (SCR) domain with multiple ligands including heparin, streptococcal M protein and C-reactive protein (CRP). The aim of this study was to localize the residues in SCR 7 required for these interactions. We initially built a homology model of fH SCR 6-7 using the averaged NMR structures of fH SCR 15-16 and vaccinia control protein SCR 3-4 as templates. Electrostatic potentials of the model's surface demonstrated a co-localization of three clusters of positively charged residues on SCR 7, labeled site A (R369 and K370), site B (R386 and K387) and site C (K392). These residues, localized to the linker region preceding SCR 7 and to the end of a "hypervariable loop" in SCR 7, were systematically replaced with uncharged alanine residues in an fH construct containing SCR 1-7. The resulting proteins were expressed in the methylotrophic yeast, Pichia pastoris. By ELISA analysis we demonstrated: first, that substituting site A inhibited heparin and CRP binding; secondly, that substituting site B inhibited binding to heparin, CRP and M protein; and thirdly, that substituting site C clearly inhibited only heparin binding.

Identification of the streptococcal M protein binding site on membrane cofactor protein (CD46).

Adherence of group A streptococcus (GAS) to keratinocytes is mediated by an interaction between human CD46 (membrane cofactor protein) with streptococcal cell surface M protein. CD46 belongs to a family of proteins that contain structurally related short consensus repeat (SCR) domains and regulate the activation of the complement components C3b and/or C4b. CD46 possesses four SCR domains and the aim of this study was to characterize their interaction with M protein. Following confirmation of the M6 protein-dependent interaction between GAS and human keratinocytes, we demonstrated that M6 protein binds soluble recombinant CD46 protein and to a CD46 construct containing only SCRs 3 and 4. M6 protein did not bind to soluble recombinant CD46 chimeric proteins that had the third and/or fourth SCR domains replaced with the corresponding domains from another complement regulator, CD55 (decay-accelerating factor). Homology-based molecular modeling of CD46 SCRs 3 and 4 revealed a cluster of positively charged residues between the interface of these SCR domains similar to the verified M protein binding sites on the plasma complement regulators factor H and C4b-binding protein. The presence of excess M6 protein did not inhibit the cofactor activity of CD46 and the presence of excess C3b did not inhibit the ability of CD46 to bind M6 protein by ELISA. In conclusion, 1) adherence of M6 GAS to keratinocytes is M protein dependent and 2) a major M protein binding site is located within SCRs 3 and 4, probably at the interface of these two domains, at a site distinct from the C3b-binding and cofactor site of CD46.