Novel mitochondria-targeted antioxidants, "Skulachev-ion" derivatives, accelerate dermal wound healing in animals

It is shown that the novel mitochondria-targeted antioxidant SkQ1, (10-(6'-plastoquinonyl) decyltriphenylphosphonium) stimulates healing of full-thickness dermal wounds in mice and rats. Treatment with nanomolar doses of SkQ1 in various formulations accelerated wound cleaning and suppressed neutrophil infiltration at the early (7 h) steps of inflammatory phase. SkQ1 stimulated formation of granulation tissue and increased the content of myofibroblasts in the beginning of regenerative phase of wound healing. Later this effect caused accumulation of collagen fibers. Local treatment with SkQ1 stimulated re-epithelization of the wound. Lifelong treatment of mice with SkQ1 supplemented with drinking water strongly stimulated skin wounds healing in old (28 months) animals. In an in vitro model of wound in human cell cultures, SkQ1 stimulated movement of epitheliocytes and fibroblasts into the "wound". Myofibroblast differentiation of subcutaneous fibroblasts was stimulated by SkQ1. It is suggested that SkQ1 stimulates wound healing by suppression of the negative effects of oxidative stress in the wound and also by induction of differentiation. Restoration of regenerative processes in old animals is consistent with the "rejuvenation" effects of SkQ1, which prevents some gerontological diseases.

Mitochondria as source of reactive oxygen species under oxidative stress. Study with novel mitochondria-targeted antioxidants--the "Skulachev-ion" derivatives

Production of reactive oxygen species (ROS) in mitochondria was studied using the novel mitochondria-targeted antioxidants (SkQ) in cultures of human cells. It was shown that SkQ rapidly (1-2 h) and selectively accumulated in mitochondria and prevented oxidation of mitochondrial components under oxidative stress induced by hydrogen peroxide. At nanomolar concentrations, SkQ inhibited oxidation of glutathione, fragmentation of mitochondria, and translocation of Bax from cytosol into mitochondria. The last effect could be related to prevention of conformational change in the adenine nucleotide transporter, which depends on oxidation of critical thiols. Mitochondria-targeted antioxidants at nanomolar concentrations prevented accumulation of ROS and cell death under oxidative stress. These effects required 24 h or more (depending on the cell type) preincubation, and this was not related to slow induction of endogenous antioxidant systems. It is suggested that SkQ slowly accumulates in a small subpopulation of mitochondria that have decreased membrane potential and produce the major part of ROS under oxidative stress. This population was visualized in the cells using potential-sensitive dye. The possible role of the small fraction of "bad" mitochondria in cell physiology is discussed.

Marginal blebbing during the early stages of TNF-induced apoptosis indicates alteration in actomyosin contractility

Dynamics of alterations of cell surface topography during TNF-induced apoptosis of HeLa cells was examined by phase-contrast videomicroscopy and immunomorphological analysis. The final stage of apoptosis accompanied by cell rounding and general blebbing of the cell surface became after 4-6 h of incubation but much earlier, after 1.5-3 h, essentially flattened lamellipodia at the active edges transformed into the small blebs that were continuously extended and retracted during the next 1-2 h. This phenomenon was called "marginal blebbing". It took place before the cytochrome c release from mitochondria to cytosol. Marginal blebbing was inhibited by drugs that depolymerized actin microfilaments (cytochalasin, latrunculin) or decreased Rho-kinase-dependent contractility of actin-myosin cortex (H7, HA-1077, Y27632). A pancaspase inhibitor, zVAD-fmk, completely prevented marginal and general blebbing, and TNF-induced apoptosis. DEVD-fmk, a specific inhibitor of caspase-3, inhibited both marginal and general blebbing but not cell rounding and death. Thus, marginal blebbing is an early microfilament-dependent apoptotic event. It is suggested that it is initiated by minimal activation of caspase-3 and the following local Rho-kinase-dependent stimulation of actin-myosin cortex contractility. Localization of marginal blebs at the active edge may be associated with special organization of cortex in that zone.

Scatter factor induces segregation of multinuclear cells into several discrete motile domains

The effects of scatter factor, HGF/SF, on multinuclear MDCK epitheliocytes were examined. Multinuclear cells were obtained by blocking cytokinesis by low concentration of cytochalasin D; these large cells had discoid shape and did not move much on the substrate. Incubation of these cells with HGF/SF induced their profound reorganization: their cytoplasm was reversibly segregated into several individually moving motile flattened domains, termed lamelloplasts and connected with one another by cylindrical domains termed cables. One or several nuclei were present in many lamelloplasts, but some lamelloplasts were anuclear. Nuclei were absent from the cables. Lamelloplasts continuously formed actin-rich ruffles at their edges; their cytoplasm contained small actin bundles and numerous focal adhesions. In contrast, cable, had no ruffles or focal adhesions. Dense networks of vimentin and keratin intermediate filaments were present in lamelloplasts; bundles of filaments of both types were seen in the cables. Segregation was accompanied by redistribution of centrosomes from perinuclear zone into lamelloplasts. As a result each lamelloplast in segregated cell acquired individual complex of centrosome and radiating microtubules. The cables contained numerous parallel microtubules but never had centrosomes. This reorganization of microtubular system was essential for segregation as alterations of shape and actin cytoskeleton were prevented by microtubule specific drugs: colcemid and Taxol (paclitaxel). It is suggested that mechanism of segregation is based on activation of two types of opposite actin reorganization: formation of actin networks in lamelloplasts and their dismantlement in the cables. Spatial distribution of the domains in which these opposite types of reorganizations occur may be regulated by microtubular system. It is also suggested that mechanisms of HGF/SF-induced segregation may be closely related to the mechanisms of important physiological reorganizations of cells, such as polarization of pseudopodial activities in motile cells and cytokinesis.

Locomotory behaviour of epitheliocytes and fibroblasts on metallic grids

Behaviour of epitheliocytes and fibroblasts on special discontinuous substrata (metallic grids with square openings of 45x45 microm2) was examined in order to compare the ability of these cells to spread in two mutually perpendicular directions and to stretch over the void spaces. Two cell types with typical fibroblastic morphology, the AGO 1523 line of human foreskin fibroblasts and secondary cultures of mouse embryo fibroblasts, and three cell types with typical epithelial morphology, primary mouse hepatocytes, the IAR-2 line of rat liver cells and the MDCK line of canine kidney epithelial cells (clone 20) were used. We also examined the epitheliocytes (MDCK cells, clone 20) transformed to fibroblast-like morphology by treatment with hepatocyte growth factor/scatter factor (HGF/SF). Time-lapse video microscopy, scanning electron microscopy and immunofluorescence microscopy were used to examine cell reorganizations at various stages of spreading. It was found that early stages of spreading of fibroblasts and epitheliocytes were similar: the cell spread along two bars, perpendicular to each other (bar and crossbar), with the formation of a small triangular lamellar cytoplasm stretched over the opening. Later central parts of the bodies of the fibroblasts retracted from the bars so that the cells remained attached only by their polar lamellae. Successive expansions and partial retractions of these lamellae led to elongation of the cell body crossing several openings of the grid. Epitheliocytes, in contrast to fibroblasts, at the late stages of spreading did not retract their bodies and did not contract polar lamellae. As a result, their central lamellae stretched progressively over the openings. As a result of the treatment of MDCK epitheliocytes with HGF/SF the behaviour of the cells on the grids became similar to that of fibroblasts. It is suggested that these distinct spreading patterns of epitheliocytes and fibroblasts are due to the type-specific differences in the actin-myosin cortex. Experiments with microtubule-specific drugs, colcemid and taxol, indicate that the organization of this cortex is under microtubular control.

Effect of microtubule-specific drugs upon spatial organization of extracellular matrix in fibroblastic cultures

The aim of this investigation was to study the effects of microtubule-specific drugs, taxol and colcemid, on the distribution of cell-associated extracellular matrix in dense cultures of fibroblasts. Immunomorphological examination of human seven-day cultures revealed a dense network of fibronectin and tenascin matrix filaments preferentially oriented in parallel with the long axes of cell bodies. Depolymerization of the microtubular system by colcemid and its disorganization by taxol led to rapid and drastic changes in the organization of matrix network: fibronectin and tenascin filaments became disordered and, in particular, lost any orientation. These data show that the microtubular system controls the morphological organization, not only of intracellular cytoskeletal systems, but also of extracellular matrix structures.

Competition of contacting heterotypic epithelial sheets for the territory in culture

Co-cultured epithelial cells of various lines formed mixed cohesive sheets. Contact interactions of different cells in the sheets were studied by phase contrast and interference reflection microscopy, time-lapse microcinematography, transmission and scanning electron microscopy. It was found that heterotypic cells in the combined sheets were locked together by the complexes of specialized contacts and were metabolically coupled, as shown by the dye transfer. At the same time heterotypic cells continued to extend pseudopods at the contacting lateral surfaces and to attach these pseudopodies to substratum. Due to competition of pseudopod attachments one group of cells in the sheet often progressively pushed another group from the substratum. This competition of cells for substratum may provide an important mechanism for morphogenetic reorganisation of epithelial sheets and of other groups of interacting cells in vivo.

Cytoskeletal reorganizations responsible for the phorbol ester-induced formation of cytoplasmic processes: possible involvement of intermediate filaments

The tumor promoter phorbol 12-myristate 13-acetate (PMA) induces characteristic reversible changes of cell shape in certain fibroblastic lines: motile lamellas are transformed into noncontractile narrow processes; simultaneously, the actin microfilament network of lamellas is locally disorganized. This reaction to PMA may be regarded as a prototype of reorganizations involving formation of stable cytoplasmic processes. Specific drugs, Taxol and Colcemid, were used to study the role of microtubules and vimentin-containing intermediate filaments (IF) in the development of PMA-induced reorganizations. PMA readily induced formation of noncontractile processes in Taxol-treated fibroblasts; these cells had a profoundly altered microtubular system but noncollapsed IF. A short (1 hr) exposure to PMA induced formation of processes in control cells but not in the Colcemid-treated cells, which had depolymerized microtubules and IF that collapsed around the nucleus. Longer (3-4 hr) exposure of the Colcemid-treated cells to PMA induced partial reversal of the IF collapse; those parts of the peripheral lamellas that contained IF were transformed into narrow noncontractile processes. It is suggested that the local interaction of IF with the actin system is an essential step in the formation of processes from lamellas. The microtubular system controls distribution of IF in the cytoplasm and thus plays an indirect role in the reorganization of the actin cortex.

Migration of nuclei and perikaryal cytoplasm along the cytoplasmic processes of differentiated neuroblastoma cells

Time-lapse microcinematography of the cultures of mouse neuroblastoma C-1300 revealed several cases of directional translocation of nucleus-containing cell body along the elongated cytoplasmic processes of differentiated neuron-like cells. This unusual type of intracellular movement observed in vitro is similar to perikaryal translocation previously described in certain types of developing brain neurons in vivo. Translocation of nuclei was often accompanied by local contractions of surrounding cytoplasm. Repeated contractions and relaxations of cytoplasm were also observed in the same cultures in the course of transformation of undifferentiated well-spread neuroblast-like into differentiated neuron-like cells. Possible mechanisms of perikaryal translocations are discussed.

Effects of small doses of cytochalasins on fibroblasts: preferential changes of active edges and focal contacts

The effects of low doses of cytochalasin B (2 micrograms/ml) and cytochalasin D (0.2 microgram/ml) on the spreading of normal mouse fibroblasts in culture were investigated to find out which components of cell-substrate interactions are most sensitive to alterations of the state of actin cytoskeleton. Cytochalasin B disorganized the cortical layer of actin microfilaments and caused partial or complete disappearance of microfilament bundles; focal contacts with the substrate seen by interference-reflection microscopy also disappeared. Diffuse close contacts were apparently insensitive to cytochalasin B. Low doses of cytochalasin B did not inhibit the outgrowth and maintenance of lamellas at the cell periphery. However, in contrast to controls, these lamellas had no distal zones with convex outer edges and ruffles at the upper surfaces. The disappearance of these ruffling active edges was accompanied by loss of the ability to clear the surface of the lamellas from the concanavalin A receptors crosslinked by the corresponding ligand. The effects of cytochalasin D were similar to those of cytochalasin B. Thus, ruffling active edges and focal contacts can be regarded as specialized parts of lamellas with increased sensitivity to cytochalasins; the presence of ruffling active edges is essential for the initiation of centripetal movement of the patches of crosslinked surface receptors.

Spreading of fibroblasts in medium containing cytochalasin B: formation of lamellar cytoplasm as a combination of several functional different processes

Normal cultured mouse fibroblasts spreading on solid substrate extend and attach numerous pseudopods; lamellar cytoplasm is eventually formed from the attached pseudopods. Fibroblasts spreading in the presence of cytochasin B (CB) from de novo a system of arbor-like branched processes rather than lamellar cytoplasm. The growing and fully formed arbor-like processes, in contrast to normal lamellar cytoplasm, have low contractility and are unable to clear patched concanavalin A receptors from their surfaces; their attachement sites are not associated with microfilament bundles. The cells spreading in medium containing CB and Colcemid do not form well-organized branched structures but extend and attach numerous unstable pseudopods. It is suggested that normal formation of lamellar cytoplasm can be regarded as a combination of several functionally different processes: (a) of rudimentary pseudopodial reactions resistant to CB and Colcemid; (b) of CB-sensitive lamellization; and (c) of Colcemid-sensitive stabilization.

Orientation of mitosis of fibroblasts is determined in the interphase

Time-lapse films of the cultures of mouse L fibroblasts have been analyzed to find out the angles between the direction of the big axis of interphase nucleus before mitosis and the direction of the mitotic furrow in the same cell. In 41 out of 51 mitoses this angle has been found to be more than 60 degrees . Thus, the orientation of mitotic furrows depends on the internal polarity of the cell before mitosis.

Contact inhibition of movement in the cultures of transformed cells

Results of cell-cell collisions were studied with the aid of time-lapse microcinematography in primary cultures of normal mouse-embryo fibroblast-like cells and in cultures of transformed mouse cells of two types: (a) primary fibroblast-like cells transformed by Moloney mouse sarcoma virus; (b) neoplastic fibroblasts of the CIM strain. Collisions of normal fibroblast-like cells and CIM cells in mixed cultures were also analyzed. Classification of the results of collisions was based on observation of the movements of the active cell edge during the first hour after the moment when this edge had contacted another cell. Three types of collision results were detected: halt of the active edge, overlapping, and underlapping. The relative number of overlappings was not higher and that of halts not lower in the cultures of transformed cells as compared with those of normal cells. Analysis of the collisions of normal fibroblasts with transformed cells gave similar results. Thus, the altered morphology of the cultures of these transformed cells cannot be explained by loss of contact inhibition of movement leading to increased ability of cells to move over the surfaces of other cells after collision.

Defective formation of the lamellar cytoplasm by neoplastic fibroblasts (L cells-transformed cells-cell attachment-contact inhibition-scanning electron microscopy-microcinematography)

Isolated cultures of mouse L-cells are similar to those of normal cells in showing contact inhibition of movement and topoinhibition of growth. In mixed cultures with untransformed mouse embryo fibroblasts, their parent strain, however, L cells are able to form colonies above the monolayer of normal fibroblasts, i.e., they have a property characteristic of transformed cells. Analysis of microcinematographic data suggests that the behavior of L cells in mixed cultures is a result of their defective attachment to the substratum. Scanning electron microscopy showed that attachment of a normal fibroblast was accompanied by the formation of a wide ring of flattened cytoplasm spread on the substratum (lamellar cytoplasm). This structure was observed to disintegrate in newly attached L cells. The structure of the lamellar cytoplasm remained abnormal in the fully spread L cells. The mean area of lamellar cytoplasm was 3- to 4-times less in L cells than in normal fibroblasts. It is suggested that deficient formation of lamellar cytoplasm may be the basis of the inability of L cells to interact normally with embryo fibroblasts.

Effect of colcemid on the locomotory behaviour of fibroblasts

Effects of metaphase inhibitors (colcemid, colchicine, vinblastine) on mouse and human embryonic, fibroblast-like cells growing on glass and on an oriented substrate (fish scale) were studied. All three inhibitors caused similar changes in the form of interphase cells and inhibited their directional locomotion. The effects of two inhibitors (colcemid and vinblastine) were found to be completely reversible. Microcinematographic studies have shown that the most conspicuous change of locomotory behaviour induced by colcemid was the disappearance of non-active stable parts of the cell edge; in normal cells only the leading part of the edge was actively moving, while in colcemid-treated cells all parts of the edge eventually became active. Activation of the whole edge made these cells unable to perform directional translocation.

It is suggested that colcemid and other metaphase inhibitors prevent stabilization of the non-active state of the cell surface. The possible role of this suggested colcemid-sensitive stabilization mechanism in the normal locomotory behaviour of fibroblasts is discussed.

Electron-microscopic examination has shown that microtubules disappeared from the cytoplasm of colcemid-treated, mouse, fibroblast-like cells. The formation of microtubules as the possible structural basis of the stabilization of the non-active state of the cell surface is discussed.