Genetic reference populations in model organisms are critical resources for systems genetic analysis of disease related phenotypes. The breeding history of these inbred panels may influence detectable allelic and phenotypic diversity. The existing panel of common inbred strains reflects historical selection biases, and existing recombinant inbred panels have low allelic diversity. All such populations may be subject to consequences of inbreeding depression. The Collaborative Cross (CC) is a mouse reference population with high allelic diversity that is being constructed using a randomized breeding design that systematically outcrosses eight founder strains, followed by inbreeding to obtain new recombinant inbred strains. Five of the eight founders are common laboratory strains, and three are wild-derived. Since its inception, the partially inbred CC has been characterized for physiological, morphological, and behavioral traits. The construction of this population provided a unique opportunity to observe phenotypic variation as new allelic combinations arose through intercrossing and inbreeding to create new stable genetic combinations. Processes including inbreeding depression and its impact on allelic and phenotypic diversity were assessed. Phenotypic variation in the CC breeding population exceeds that of existing mouse genetic reference populations due to both high founder genetic diversity and novel epistatic combinations. However, some focal evidence of allele purging was detected including a suggestive QTL for litter size in a location of changing allele frequency. Despite these inescapable pressures, high diversity and precision for genetic mapping remain. These results demonstrate the potential of the CC population once completed and highlight implications for development of related populations.
The morphology of supported planar bilayers has been investigated below phase transition temperature by atomic force microscopy in contact and tapping mode. The bilayers were formed by the vesicle-spreading technique. In contact mode at low scanning forces of about 1 nN true molecular resolution could be achieved for supported phosphatidylcholine bilayers. The resolution was confirmed by experiments that captured the location, average area of individual lipid headgroups and the manipulation of the bilayer surface. Repeated scanning in contact mode shifted the random topology of the surface consecutively to a striped pattern. Height profiles of defect-containing bilayers were analyzed. The shape of the defects became smooth by repeated scanning. The height profiles allowed the estimation of the indentation of the tip into the surface-adsorbed membrane. In tapping mode a disordered pattern of headgroups became visible. Our morphological data at molecular resolution suggest that the native arrangement of the choline head-groups is disordered, free of large packing defects and becomes ordered in Schallamach waves by scanning in contact mode.
Cells from a variety of tissues regulate their volume when exposed to anisotonic conditions. After exposure of cells to hypotonic conditions, the rapid phase of cell swelling is followed by a slower phase of cell shrinkage towards the initial volume. The present study investigates morphological alterations of adherent and fully spread cells after exposure to hypotonic conditions and the reorganization of cytoskeletal components such as F-actin, actin-binding proteins, microtubules and intermediate-sized filaments. We used cells of a continuous epithelial cell line from the opossum kidney (OK cells), which were exposed to hypotonic conditions for a period of 60 min at 25 degrees C. The osmolarity was reduced by 40% from 320 mosmol/l (isotonic conditions) to 192 mosmol/l (hypotonic conditions). The initial swelling after exposure of OK cells to hypotonic conditions caused enhanced ruffling membrane activity, formation of lamellipodia and an extended space between adjacent cells which was caused by a more rounded cell shape. Moreover, the height of cells located in the centre of cell clusters increased by 32 +/- 8% (mean value +/- SEM) as checked by morphometric analysis of the vertical distance between the apical and basolateral F-actin domain. Although the fluorescence intensity and organization of F-actin in a horizontal direction remained unaltered during cell swelling, we observed a loss of periodicity and irregular distribution of myosin aggregates and a partial rearrangement of vimentin filaments in the form of short fragments. In all experiments the organization of microtubles was observed to be unaltered.(ABSTRACT TRUNCATED AT 250 WORDS)
The atomic force microscope was used to image peritoneal macrophages after phagocytosis of latex beads with 0.45 microns in diameter and of zymosan particles. The rigidity of the phagocytosed material allowed to image the live membrane at forces below 2 nN. Repeated scanning of the membrane unavoidably caused the protrusion of the beads and increased their virtual height. The influence of fixation by glutaraldehyde on the image and the corresponding force vs. distance curves were analyzed and compared. Short treatment with Triton X-100 enabled us to identify intracellular components, such as embedded latex beads, cell nucleus and cytoskeletal strands. The data demonstrate that it is possible to image living cells if they are bolstered by stiff material.
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