Iron-ion radiation accelerates atherosclerosis in apolipoprotein E-deficient mice

Radiation exposure from a number of terrestrial sources is associated with an increased risk for atherosclerosis. Recently, concern over whether exposure to cosmic radiation might pose a similar risk for astronauts has increased. To address this question, we examined the effect of 2 to 5 Gy iron ions ((56)Fe), a particularly damaging component of cosmic radiation, targeted to specific arterial sites in male apolipoprotein E-deficient (apoE(-/-)) mice. Radiation accelerated the development of atherosclerosis in irradiated portions of the aorta independent of any systemic effects on plasma lipid profiles or circulating leukocytes. Further, radiation exposure resulted in a more rapid progression of advanced aortic root lesions, characterized by larger necrotic cores associated with greater numbers of apoptotic macrophages and reduced lesional collagen compared to sham-treated mice. Intima media thickening of the carotid arteries was also exacerbated. Exposure to (56)Fe ions can therefore accelerate the development of atherosclerotic lesions and promote their progression to an advanced stage characterized by compositional changes indicative of increased thrombogenicity and instability. We conclude that the potential consequences of radiation exposure for astronauts on prolonged deep-space missions are a major concern. Knowledge gained from further studies with animal models should lead to a better understanding of the pathophysiological effects of accelerated ion radiation to better estimate atherogenic risk and develop appropriate countermeasures to mitigate its damaging effects.     

Sexual selection on protamine and transition nuclear protein expression in mouse species

Post-copulatory sexual selection in the form of sperm competition is known to influence the evolution of male reproductive proteins in mammals. The relationship between sperm competition and regulatory evolution, however, remains to be explored. Protamines and transition nuclear proteins are involved in the condensation of sperm chromatin and are expected to affect the shape of the sperm head. A hydrodynamically efficient head allows for fast swimming velocity and, therefore, more competitive sperm. Previous comparative studies in rodents have documented a significant association between the level of sperm competition (as measured by relative testes mass) and DNA sequence evolution in both the coding and promoter sequences of protamine 2. Here, we investigate the influence of sexual selection on protamine and transition nuclear protein mRNA expression in the testes of eight mouse species that differ widely in levels of sperm competition. We also examined the relationship between relative gene expression levels and sperm head shape, assessed using geometric morphometrics. We found that species with higher levels of sperm competition express less protamine 2 in relation to protamine 1 and transition nuclear proteins. Moreover, there was a significant association between relative protamine 2 expression and sperm head shape. Reduction in the relative abundance of protamine 2 may increase the competitive ability of sperm in mice, possibly by affecting sperm head shape. Changes in gene regulatory sequences thus seem to be the basis of the evolutionary response to sexual selection in these proteins.     

A Bayesian extension of phylogenetic generalized least squares: Incorporating uncertainty in the comparative study of trait relationships and evolutionary rates

Phylogenetic comparative methods use tree topology, branch lengths, and models of phenotypic change to take into account nonindependence in statistical analysis. However, these methods normally assume that trees and models are known without error. Approaches relying on evolutionary regimes also assume specific distributions of character states across a tree, which often result from ancestral state reconstructions that are subject to uncertainty. Several methods have been proposed to deal with some of these sources of uncertainty, but approaches accounting for all of them are less common. Here, we show how Bayesian statistics facilitates this task while relaxing the homogeneous rate assumption of the well-known phylogenetic generalized least squares (PGLS) framework. This Bayesian formulation allows uncertainty about phylogeny, evolutionary regimes, or other statistical parameters to be taken into account for studies as simple as testing for coevolution in two traits or as complex as testing whether bursts of phenotypic change are associated with evolutionary shifts in intertrait correlations. A mixture of validation approaches indicates that the approach has good inferential properties and predictive performance. We provide suggestions for implementation and show its usefulness by exploring the coevolution of ankle posture and forefoot proportions in Carnivora.     

Climate and morphological change on decadal scales: Multiannual variation in the common shrew <Emphasis Type=Italic>Sorex araneus</Emphasis> in northeast Russia

Multiannual variation is one of several types of species morphological variability, one that is directly related to ecophenotypic and evolutionary responses to changing environments. The morphology of small mammal populations can change quickly because generation length is short, usually one year, and individual lifespans are often only a year or two. We studied the response of skull and mandible morphology in the common shrew Sorex araneus Linnaeus, 1758 to nine climate factors related to snow cover, temperature and precipitation at a study site near Syktyvkar, Russia through the period 1976 to 2003. We found that these multivariate phenotypes changed significantly from year to year, though there were no clear directional trends in the change. The phenotype itself was closely associated with the range of annual temperature and winter precipitation. Changes in summer temperatures and precipitation seem to drive change in size-related phenotypes, whereas changes in snow cover and winter temperature seem to drive change in shape.     

The Evolution of Enamel Microstructure: How Important Is Amelogenin?

The shape, size, and orientation of enamel prisms have heretofore been thought to be controlled solely by the shape of the Tomes' process. It is known, however, that amelogenin proteins play an important role in enamel deposition and maturation and it is possible that they contribute independently to enamel structure. Using a phylogenetic framework, we clarify the role of amelogenin proteins in the formation of enamel microstructure. We found a negative association between evolutionary changes in amelogenin protein sequences and enamel complexity: amelogenin evolution slows as enamel complexity increases. This is probably because selective constraints on amelogenin increase as enamel complexity increases. Monotremes, which have lost their adult dentition, have particularly high rates of amelogenin evolution while rodents, which have very complex enamel, have very low rates. There is a positive correlation between the number of different amelogenin proteins in a given species and the complexity of its enamel microstructure. An increased number of amelogenins may be necessary for the formation of multiple enamel types in the same tooth. Alternative splicing of amelogenin exons, which allows multiple protein products to be produced from the same gene, may be a key innovation in the diversification of enamel microstructure.