"Attraction Fields" between Growing Tissue Cultures

Long-range mechanical signaling in biological systems

Cells can respond to signals generated by other cells that are remarkably far away. Studies from at least the 1920's showed that cells move toward each other when the distance between them is on the order of a millimeter, which is many times the cell diameter. Chemical signals generated by molecules diffusing from the cell surface would move too slowly and dissipate too fast to account for these effects, suggesting that they might be physical rather than biochemical. The non-linear elastic responses of sparsely connected networks of stiff or semiflexible filament such as those that form the extracellular matrix (ECM) and the cytoskeleton have unusual properties that suggest multiple mechanisms for long-range signaling in biological tissues. These include not only direct force transmission, but also highly non-uniform local deformations, and force-generated changes in fiber alignment and density. Defining how fibrous networks respond to cell-generated forces can help design new methods to characterize abnormal tissues and can guide development of improved biomimetic materials.

Stiffness Sensing by Cells

Physical stimuli are essential for the function of eukaryotic cells, and changes in physical signals are important elements in normal tissue development as well as in disease initiation and progression. The complexity of physical stimuli and the cellular signals they initiate are as complex as those triggered by chemical signals. One of the most important, and the focus of this review, is the effect of substrate mechanical properties on cell structure and function. The past decade has produced a nearly exponentially increasing number of mechanobiological studies to define how substrate stiffness alters cell biology using both purified systems and intact tissues. Here we attempt to identify common features of mechanosensing in different systems while also highlighting the numerous informative exceptions to what in early studies appeared to be simple rules by which cells respond to mechanical stresses.

Lateral boundary mechanosensing by adherent cells in a collagen gel system

Cell adhesion responses to in-depth physical properties such as substrate roughness and topography are well described but little is known about the influence of lateral physical cues such as tissue boundaries on the function of adherent cells. Accordingly, we developed a model system to examine remote cell sensing of lateral boundaries. The model employs floating thin collagen gels supported by rigid grids of varying widths. The dynamics, lengths, and numbers of cell extensions were regulated by grid opening size, which in turn determined the distance of cells from rigid physical boundaries. In smaller grids (200 μm and 500 μm wide), cell-induced deformation fields extended to, and were resisted by, the grid boundaries. However, in larger grids (1700 μm wide), the deformation field did not extend to the grid boundaries, which strongly affected the mean length and number of cell extensions (∼60% reduction). The generation of cell extensions in collagen gels required expression of the β1 integrin, focal adhesion kinase and actomyosin activity. We conclude that the presence of physical boundaries interrupts the process of cell-mediated collagen compaction and fiber alignment in the collagen matrix and enhances the formation of cell extensions. This new cell culture platform provides a geometry that more closely approximates the native basement membrane and will help to elucidate the roles of cell extensions and lateral mechanosensing on extracellular matrix remodeling by invasion and degradation.

Effects of non-linearity on cell-ECM interactions

Filamentous biopolymers such as F-actin, vimentin, fibrin and collagen that form networks within the cytoskeleton or the extracellular matrix have unusual rheological properties not present in most synthetic soft materials that are used as cell substrates or scaffolds for tissue engineering. Gels formed by purified filamentous biopolymers are often strain stiffening, with an elastic modulus that can increase an order of magnitude at moderate strains that are relevant to cell and tissue deformation in vivo. This review summarizes some experimental studies of non-linear rheology in biopolymer gels, discusses possible molecular mechanisms that account for strain stiffening, and explores the possible relevance of non-linear rheology to the interactions between cell and extracellular matrices.

Fibers in the extracellular matrix enable long-range stress transmission between cells

Cells can sense, signal, and organize via mechanical forces. The ability of cells to mechanically sense and respond to the presence of other cells over relatively long distances (e.g., ∼100 μm, or ∼10 cell-diameters) across extracellular matrix (ECM) has been attributed to the strain-hardening behavior of the ECM. In this study, we explore an alternative hypothesis: the fibrous nature of the ECM makes long-range stress transmission possible and provides an important mechanism for long-range cell-cell mechanical signaling. To test this hypothesis, confocal reflectance microscopy was used to develop image-based finite-element models of stress transmission within fibroblast-seeded collagen gels. Models that account for the gel's fibrous nature were compared with homogenous linear-elastic and strain-hardening models to investigate the mechanisms of stress propagation. Experimentally, cells were observed to compact the collagen gel and align collagen fibers between neighboring cells within 24 h. Finite-element analysis revealed that stresses generated by a centripetally contracting cell boundary are concentrated in the relatively stiff ECM fibers and are propagated farther in a fibrous matrix as compared to homogeneous linear elastic or strain-hardening materials. These results support the hypothesis that ECM fibers, especially aligned ones, play an important role in long-range stress transmission.

Mechanisms of mechanical signaling in development and disease

The responses of cells to chemical signals are relatively well characterized and understood. Cells also respond to mechanical signals in the form of externally applied force and forces generated by cell-matrix and cell-cell contacts. Many features of cell function that are generally considered to be under the control of chemical stimuli, such as motility, proliferation, differentiation and survival, can also be altered by changes in the stiffness of the substrate to which the cells are adhered, even when their chemical environment remains unchanged. Many examples from clinical and whole animal studies have shown that changes in tissue stiffness are related to specific disease characteristics and that efforts to restore normal tissue mechanics have the potential to reverse or prevent cell dysfunction and disease. How cells detect stiffness is largely unknown, but the cellular structures that measure stiffness and the general principles by which they work are beginning to be revealed. This Commentary highlights selected recent reports of mechanical signaling during disease development, discusses open questions regarding the physical mechanisms by which cells sense stiffness, and examines the relationship between studies in vitro on flat substrates and the more complex three-dimensional setting in vivo.

Inhibition of enriched stem cells in vivo and in vitro by the hemoregulatory peptide SK&F108636

Replacement of the labile sulfhydryl group (-SH) of the hemoregulatory peptide monomer pyroGluGluAspCysLys (HP5b) with an isosteric methylene group yields a chemically stable compound, SK&F108636. In this study, we describe the effects of SK&F108636 on highly enriched Lin-Sca1+ hematopoietic stem cells. SK&F108636 significantly reduced the fraction of cycling progenitor cells, granulocyte macrophage colony-forming cells (GM-CFC), in vitro and in vivo. There was no effect on GM-CFC or Mix-CFC colony formation. SK&F108636 significantly inhibited proliferation of high proliferative potential (HPP)-CFC in semisolid agar cultures stimulated by stem cell factor + interleukin 3 (IL-3) + IL-1, but had no effect in cultures stimulated with M-CSF + IL-3 + IL-1. SK&F108636 was shown to act directly on the stem cells since SK&F108636 inhibited proliferation of Lin-Sca1+ cells in single cell assays. Administration of SK&F108636 to lethally irradiated mice transplanted with 2000 Lin-Sca1+ cells significantly inhibited proliferation/differentiation of cells developing into colony forming units-spleen (CFU-S) (preCFU-S) and the reconstitution of HPP-CFC and GM-CFC. There was no effect of SK&F108636 on CFU-S colony formation or mature cell regeneration in bone marrow, spleen and blood. Hence, the hemoregulatory peptide monomer SK&F108636 is a potent primitive stem cell inhibitor in vivo and in vitro. Inhibition of stem cell proliferation by small specific inhibitors may protect hematopoiesis from myelotoxic side effects during chemotherapy treatment.

Growth-inhibitory protein present in rabbit serum, which is more effective on tumorigenic rat liver epithelial cells than on non-tumorigenic ones: its species, and mode of existence

We have previously reported that in culture, rabbit serum inhibits the growth of the epithelial cell line from Buffalo rat liver (BRL) lower than that of the tumorigenic one transformed by Rous sarcoma virus (RSV-BRL). Here, the serum was fractionated by several different methods. The findings are: 1) the growth inhibitor present (GI) existed as large complexes with non-inhibitory proteins; 2) the complexes were dissociated by 1 M NaCl plus 6 M urea; 3) the dissociated GI did not pass through membrane filter with Mr cutoff 10k; 4) it was stable in 8.5 M urea and 1 M acetic acid (pH 2.5), but labile against either dithiothreitol and trypsin; 5) it was separable into two species with pI 7.5 and 9.5; 6) both species were more effective on RSV-BRL than on BRL.

Increase of mitosis in the tubular epithelium following intrarenal doses of various kidney homogenates and hemogenate fractions in the rat

Earlier investigations about the consequences of experimental kidney ischemia raised the question, if there exists a substance in the renal tissue which is liberated by cell death or during regeneration of cells and which might stimulate mitosis of other cells. Therefore in recent experiments we directly injected into the left kidney parenchyma of receiver animals, homogenates, or their separated fractions from infarcted or regenerated kidneys of adult donors and from kidneys of juvenile donors. These are the results" 1. A small dose of kidney homogenate already produces a clear increase of mitoses in the tubular epithelium of the renal cortex 17-19 h after injection in the adult recipient of the same breed. The increase of proliferation is of short-duration, kidney-specific, and not to reproduce in different controls. 2. The mitogenetic effect of a unilateral intrarenal dose of kidney homogenate does not favor a special area. Without a recognizable principle of cellular selection it occurs everywhere in the kidney parenchyma. It must be understood as a "simple increase" of normal growth. The proliferation stimulus is humorally transmitted to the untouched contralateral kidney. Yet the mitotic acitivty is significantly higher in the left than in the right kidney. 3. The experiments demonstrate a much better efficiency of the sediment, especially of the mitochondrial and microsomal fraction, than of the supernatant. 4. Our results indicate that in the complicated regulation system of cell growth there must be taken into account different factors and signalizing ways for induction and termination of mitosis.

[Bilateral renal hypoplasia with oligomeganephronie. A morphometric, light- and electronmicroscopic study (author's transl)]

Kidney biopsy specimens of three patients with a special form of hypoplasia, the oligomeganephronic hypoplasia (Oligomeganephronie) were studied with light- and electron-microscopy as well as morphometric methods. The morphometric measurements demonstrated that there were no quantitative differences of the glomerular components between normal and oligomeganephronic glomeruli of patients of the same age. All of the structures measured--glomerular capillary surface, glomerular volume, volume of the glomerular capillary lumina and volume of Bowman's capsular space--were increased about 5.4 times. The volume of the proximal and distal tubules per mum tubular length in oligomeganephronic patients was disproportionally increased. The total number of glomeruli was more diminuished than mentionned in the literature until this time. The secondary glomerular sclerosis, initially focal, was progressive and supposed to be caused by "chronic overwork".

Influenza Del Glucagone Sulla Crescita Dei Fibroblasti Di Cuore Di Embrione Di Pollo « in Vitro »

The influence of glucagone on the growth of « in vitro » explants from chick embryo heart has been studied by « roller-tubes » technique. Aim of the present paper is the identification of an eventual promoting action of glucagone on growth. The « in vitro » growth was evaluated by micrometric determination of the explants migration area in a 4 days old culture. Glucagone in concentration 1/1 100 000 was observed to be inactive; in concentration 1/200 000 it exerted a growth activation of the 28,65 per cent and in concentration 1/100 000 an activation of the 44,15 per cent. A certain parallelism may be found with « in vivo » observations according to which glucagone would represent a mediation of the somatotropic hormone effects.