The genetic structure of the Swedish population

Patterns of genetic diversity have previously been shown to mirror geography on a global scale and within continents and individual countries. Using genome-wide SNP data on 5174 Swedes with extensive geographical coverage, we analyzed the genetic structure of the Swedish population. We observed strong differences between the far northern counties and the remaining counties. The population of Dalarna county, in north middle Sweden, which borders southern Norway, also appears to differ markedly from other counties, possibly due to this county having more individuals with remote Finnish or Norwegian ancestry than other counties. An analysis of genetic differentiation (based on pairwise F(st)) indicated that the population of Sweden's southernmost counties are genetically closer to the HapMap CEU samples of Northern European ancestry than to the populations of Sweden's northernmost counties. In a comparison of extended homozygous segments, we detected a clear divide between southern and northern Sweden with small differences between the southern counties and considerably more segments in northern Sweden. Both the increased degree of homozygosity in the north and the large genetic differences between the south and the north may have arisen due to a small population in the north and the vast geographical distances between towns and villages in the north, in contrast to the more densely settled southern parts of Sweden. Our findings have implications for future genome-wide association studies (GWAS) with respect to the matching of cases and controls and the need for within-county matching. We have shown that genetic differences within a single country may be substantial, even when viewed on a European scale. Thus, population stratification needs to be accounted for, even within a country like Sweden, which is often perceived to be relatively homogenous and a favourable resource for genetic mapping, otherwise inferences based on genetic data may lead to false conclusions.     

Histomorphometric study of bone microstructure of primates and domestic animal with the goal of species identification with reference to the effects of domestication

Functional bone microstructure of long limb bones is a function of species-specific biomechanical properties such as locomotion and weight. Histomorphometry and statistics were used to identify various primate species (Hylobates moloch, Pongo satyrus borneensis, Pan tr. troglodytes, Gorilla g. gorilla, Homo sapiens), equid species (Equus caballus, Equus asinus, Equus mulus, Equus hemionus kulan, Equus ferus przewalskii) and also extinct horses e.g. iron age, medieval and neolithic forms on the microstructural level. Furthermore, bones from domesticated cattle, their Neolithic forms, pigs, sheep and goats (Bos taurus, Sus scrofa, Ovis aries, Capra hircus) were examined. Thin sections from proximal metacarpi or radii per species were taken in case of the domesticated animals and from distal humeri in case of the primates. Areas, perimeters, minimal and maximal axis of Haversian canals and secondary osteons were measured on digital images. Canonical discriminant analysis permits a differentiation of the species by these parameters of bone microstructure. Thus it is possible to distinguish between the different primate species, sheep and goats, horses, extinct horses, donkeys, mules and kulans on the microstructural level, however not between cattle and pig, E. f. przewalskii and Equus caballus, medieval and iron age horses. Neolithic cattle and horses do overlap, yet they are different from the modern forms.     

A rare polyglycine type II‐like helix motif in naturally occurring proteins

Common structural elements in proteins such as α‐helices or β‐sheets are characterized by uniformly repeating, energetically favorable main chain conformations which additionally exhibit a completely saturated hydrogen‐bonding network of the main chain NH and CO groups. Although polyproline or polyglycine type II helices (PP_II or PG_II) are frequently found in proteins, they are not considered as equivalent secondary structure elements because they do not form a similar self‐contained hydrogen‐bonding network of the main chain atoms. In this context our finding of an unusual motif of glycine‐rich PG_II‐like helices in the structure of the acetophenone carboxylase core complex is of relevance. These PG_II‐like helices form hexagonal bundles which appear to fulfill the criterion of a (largely) saturated hydrogen‐bonding network of the main‐chain groups and therefore may be regarded in this sense as a new secondary structure element. It consists of a central PG_II‐like helix surrounded by six nearly parallel PG_II‐like helices in a hexagonal array, plus an additional PG_II‐like helix extending the array outwards. Very related structural elements have previously been found in synthetic polyglycine fibers. In both cases, all main chain NH and CO groups of the central PG_II‐helix are saturated by either intra‐ or intermolecular hydrogen‐bonds, resulting in a self‐contained hydrogen‐bonding network. Similar, but incomplete PG_II‐helix patterns were also previously identified in a GTP‐binding protein and an antifreeze protein.     

Metamorphosis of Hydractinia echinata (Cnidaria) is caspase-dependent

Apoptotic cell death plays an important role in many developmental pathways in multicellular animals. Here, we show that metamorphosis in the basal invertebrate Hydractinia echinata (Cnidaria) depends on the activity of caspases, the central enzymes in apoptosis. Caspases are activated during metamorphosis and this activity can be measured with caspase-3 specific fluorogenic substrates. In affinity labelling experiments 23/25 kDa bands were obtained, which represented active caspase. Specific inhibition of caspase activity with caspase-3 inhibitors abolished metamorphosis completely, reversibly and in a dose-dependent manner. This suggests that caspase activity is indispensable for metamorphosis in Hydractinia echinata.     

Confocal microscopy of giant vesicles supports the absence of HIV-1 neutralizing 2F5 antibody reactivity to plasma membrane phospholipids

The broadly neutralizing anti-HIV-1 2F5 monoclonal antibody recognizes a gp41 epitope proximal to the viral membrane. Potential phospholipid autoreactivity at cell surfaces has raised concerns about the use of this antibody for development of vaccines or immunotherapy. In this study, confocal microscopy of giant unilamellar vesicles (GUVs) was used to assess 2F5 reactivity with phospholipids assembled into bilayers with surface charge and curvature stress approximating those of the eukaryotic plasma membranes. Antibody partitioning into lipid bilayers required the specific recognition of membrane-inserted epitope, indicating that 2F5 was unable to directly react with GUV phospholipids, even under fluid phase segregation conditions. Our results thus support the feasibility of raising 2F5-like neutralizing responses through vaccination, and the medical safety of mAb infusions.