Shape changes and polarization of cells migrating through tissue. A high-voltage electron microscope and computer graphics study of serial thick sections

Changes in the shape and orientation of periodontal ligament fibroblasts in the continuously erupting rat incisor following removal of the occlusal load

One of the main theories which attempts to explain the phenomenon of tooth eruption suggests that periodontal ligament (PDL) fibroblasts move actively and pull the tooth with them out of its socket. To find further support for this theory, we determined the changes in the shape and orientation of PDL fibroblasts induced by a transition from impeded to unimpeded eruption. We measured nuclear area, elongation (length-to-width ratio), and orientation (angulation in relation to the eruption axis) of PDL fibroblasts in impeded (functionally loaded) and unimpeded (hypoloaded) rat incisors. The mean cross-sectional nuclear area did not differ between fibroblasts in the two groups. In contrast, unimpeded eruption resulted in a marked increase in the mean nuclear elongation (from about 2 to 2.56) and a significant increase in the mean nuclear orientation (from 25.6 to 14.0 degrees). Bivariate analysis suggested that these changes occurred in the same cells. Analysis of nuclear elongation and orientation at various distances from the cementum toward the alveolar bone revealed a profile of both parameters, such that cells located 20 to 80 microns away from the cemental surface were more elongated and more frequently oriented toward the eruption axis, while cells at 0 to 20 and 80 to 100 microns were more round/oval and had a greater angulation with the eruption axis. These findings, together with other observations of changes in cell number, number of microtubules, and migration velocity which occur on the shift to unimpeded eruption, support the theory of active movement of PDL fibroblasts as an important component of tooth eruption.

Organelle rearrangement and cell volume changes during squeezing invasion of peritoneal elastic lamina by targeted murine breast carcinoma cells

Murine breast cancer cell lines were developed to selectively invade the peritoneum while they proliferated in ascites form in the abdominal cavity. In a dominant form of invasion, tumor cells showed special affinity for elastin fibers and squeezed through narrow gaps in the elastic fiber meshwork of the stroma. Even in fixed tissue, such cells could be recognized as being in the process of invasive migration because of their dumbbell shape. This appearance was similar to that of diapedetic blood cells traversing bone marrow sinus endothelium. Three-dimensional STERECON graphics reconstruction from serial thick sections of 44 such cells was carried out. The reconstructions showed that, in mid-penetration, the cells spread extensively over the exterior surface of the elastic fiber meshwork. The cell surface contact of these forward projections was mainly with the elastic fiber outer coat of microfibrils, but small areas of the cell surface also fused directly to inner-core elastin. The morphological rearrangement of the cytoskeleton was minimal in both types of attachment areas. The location of these forward facing attachments is consistent with mechanisms for pulling the invasive cell through the gap. Lamellopodia formation and clustering of cytoplasmic organelles occurred more commonly at the forward-facing part of the cell. Morphometry of the reconstructions showed that a contraction of the whole cell occurred during the squeezing/migration process suggestive of an additional pushing process. However, our invasive cell lines showed marked differences in the degree of cell shrinkage. The process of adhesion and squeezing of tumor cells through elastin meshworks in vivo is clearly a complex phenomenon. Changes in cell surface activity appear to play a significant role in establishing the necessary 'foothold' component of invasion and, possibly, in the generation of tractive force as well.

The relative merits of direct morphometry of reconstructions of whole cells, and statistical morphometry by stereology of random sections of cells

Stereology, or the derivation of quantitative, three-dimensional (3-D) data about cells by statistical analysis of the structures of random sections, is widely used in cytology and pathology. However, there are situations where this approach is inadequate, and only an analysis of a homogeneous population of whole cells will give the required results. This involved 3-D reconstruction from physical or optical sections, or tomography or photogrammetry of whole-cell mounts. Use of stereo views of individual sections or projections adds considerably to the information available for both contouring and reconstruction. Recent image-processing advances in clinical radiography have shown, for the first time, that rapid, high-resolution digitization and contrast enhancement enable nearly all structural details to be routinely extracted from the micrographs and adequately portrayed. Three-D whole-cell reconstructions provide the digital data for many kinds of morphometric measurements on both whole cells and their individual organelles and membranes. Rapid fixation or freezing allows improved quantitative structure/function correlations of organelles with disturbances in cell metabolism or gene expression.

Targeting of peritoneum by the small numbers of isogeneic and allogeneic ascites carcinoma cells that infiltrate or attach to peritoneum during ascites growth

In the course of development of an in vivo invasion model, sublines of a series of allogenic and isogeneic carcinoma cell lines have been selected that show enhanced invasion of the peritoneum. It was found that, during the proliferation of tumor cell lines in ascitic form in the abdominal cavity, small numbers of cells infiltrated or firmly adhered to the peritoneum in at least 8/12 of the tumor-host combinations tried. After thorough washing of the peritoneum it was disaggregated by an enzyme mixture, and the resulting mixture of normal and tumor cells was inoculated intraperitoneally. Peritoneal isolations were made serially for 3 to 12 times. In 6 of 8 cases where the isolation produced a stable ascites, the cells showed enhanced peritoneal invasion compared with the parent cell line. The invasion of some of the cell lines was tested in another invasion model consisting of cultured mouse buccal mucosa (9/10 cell lines invaded the explant). In 3/3 cell lines showing enhanced peritoneum invasion in vivo, there was no enhanced invasion of the buccal mucosa. The enhanced peritoneum invasion appears to be tissue specific rather than a general increase in invasion potential. Pairs of high- and low-invasive cell lines were obtained that should be useful for screening for invasion modulating agents using the mouse ascites/peritoneum in vivo model. It is suggested that the method might be generalized to produce various tumor cell lines that target for the normal tissues that are adjacent to proliferating solid or circulating tumors.

Shape, size, and distribution of cell structures by 3-D graphics reconstruction and stereology. I. The regulatory volume decrease of astroglial cells

This report discusses fundamental limitations in attempting to derive cell size, shape, or distribution from the two-dimensional images provided by conventional electron microscopy. Morphometric or stereologic measurement of random thin sections is a convenient way to obtain some information of this type. However, it cannot provide complete, objective information about real size, shape, or connectivity of cells containing irregular or unevenly distributed structures or nonuniform populations of cells. Anisotropic structures require analysis of a complete set of serial sections. The analysis may utilize either stereo, mono, or tilted optical slices, and subsequent integration of this information into a single 3-D computer data set. In this study, we analyze stereo pairs of high-voltage electron micrographs of serial thick sections (0.5 micron) and critical-point-dried whole-cell mounts of rat brain astroglial cell cultures. The Z-axis resolution is increased by digitizing contours at discrete levels within each stereo view. This is accomplished with a new type of stereoscopic contouring device. We calculated area and volume changes accompanying hypo-osmolar swelling and spontaneous reversal of the swelling. (Regulatory Volume Decrease-RVD). An understanding of the mechanism of swelling of astroglial cells is important for improving the treatment of brain injury. The total cell-volume results are comparable with results previously obtained using nonmetabolized, radioactively tagged compounds that diffuse into various cell compartments. Our serial-section and whole-cell data also provide new information about the relative swelling of nucleus, cytoplasm, and individual organelles such as mitochondria. The basic biological problem being approached is whether homeostasis of cell function is accompanied by surface area and volume regulation of enzyme-rich membranes and organelles. Conversely, it is proposed to explore the possibility that abnormal organelle areas and volumes are indicators of perturbations of cell division, metabolism, or gene expression.

Optimum specimen positioning in the electron microscope using a double-tilt stage

Optimal imaging of complex structures requires proper alignment relative to the optic axis of the electron microscope. This is especially important for high-voltage and intermediate-voltage microscopes, which form an in-focus image throughout the entire thickness of the object. As a result, structures at different specimen heights form overlapping and confused images that severely curtail the usefulness of these instruments. The work described here provides a generalized, flexible method for optimizing specimen orientation and eliminating or limiting image overlap by means of a commonly used double-tilt stage. Analysis of the motion about the two axes provides accurate tilting for any azimuthal direction whether or not it corresponds to a mechanical axis of the stage. An object can be positioned to minimize image overlap, to record stereopairs for any parallax axis, and to record three-dimensional data sets by the conical collection geometry. Images of muscle paracrystals are shown after tilting about an axis perpendicular to a symmetry direction. The tilted image displays higher-order symmetry, which is altered by changes of one degree. Precision double-tilting for optimizing stereopairs is shown for a desmosome recorded using different parallax axes and pretilts. A tomographic conical data-collection scheme is demonstrated by imaging a microtubule axoneme for a specific cone half-angle and arbitrary azimuthal angles.

Three-dimensional reconstruction of cells from serial sections and whole-cell mounts using multilevel contouring of stereo micrographs

A comprehensive computer-graphics-based system (STERECON) is described for tracing and digitizing contours from individual or stereopair electron micrographs. The contours are drawn in parallel planes within the micrographs. Provision is also made for tracing and digitizing in full three-dimensional (3-D) coordinates in any direction along linear structures such as cytoskeletal elements. The stereopair micrographs are viewed in combination with the contours being traced on a graphics terminal monitor. This is done either by projecting original electron micrograph (EM) negatives onto a screen and optically combining these images with contour lines being drawn on the monitor, or by first digitizing the images and displaying them directly on the monitor along with the contour lines. Prior image digitization allows computer enhancement of the structures to be contoured. Correction and alignment routines are included to deal with variable section thickness, section distortion and mass loss, variations in photography in the electron microscope, and terminal screen curvature when combining projected images with contour lines on the monitor. The STERECON system organizes and displays the digitized data from successive sections as a 3-D reconstruction. Reconstructions can be viewed in any orientation as contour stacks with hidden lines removed; as wire-frame models; or as shaded, solid models with variable lighting, transparency, and reflectivity. Volumes and surface areas of the reconstructed objects can be determined. Particular attention was paid to making the system convenient for the biological user. Users are given a choice of three different stereo-viewing methods.

Novel extracellular matrix and microtubule cables associated with pseudopodia of Astrammina rara, a carnivorous Antarctic foraminifer

Astrammina rara is a benthic foraminiferan protozoan which uses an extensive network of fine, branching, and anastomosing pseudopodia to capture and digest metazoans up to 12 mm long. During such predation the pseudopodia appear remarkably elastic and tensile. Electron microscopy has revealed a novel extracellular matrix of thin branching fibers associated with A. rara's pseudopodia, which are otherwise typical in appearance. These fibers are structurally associated with the pseudopodial glycocalyx. Cytoplasmic microtubules are often found in close juxtaposition to the plasma membrane and overlying extracellular fibers. In the main pseudopodial trunks bundles of 30-300 microtubules are surrounded by a lightly staining matrix and linked by occasional bridges. The microtubules follow straight trajectories in distal filopodia, but in pseudopodial trunks they appear to coil around one another to form cables. These microtubular cables and extracellular fibers are novel features of A. rara's pseudopodia and may provide the structural basis for their tensile strength.