Kinetics of the reaction of yolk cell surface in the loach to puncture and mechanic deformation

Circumferential and radial components of the yolk cell surface movements were measured in the loach embryos at the late blastula stage within 40–50 min after puncture or indentation by an obliquely directed glass rod. The yolk cell surface was preliminarily marked by coal particles. It was shown that even closely located regions of the surface differed markedly in the rate and direction of their movements. In the vicinity of puncture, the yolk cell surface at first contracted in both circumferential and radial directions and then widened, but did not reach the initial values. In more remote areas, this surface continued to contract in the circumferential direction, but was extended in the radial direction. The degree of its contraction along different radii was unequal. The reaction to oblique indentation was anisotropic: the closest area of the yolk cell surface, located along the direction of indentation, contracted in both circumferential and radial directions and formed a fold “leaking” onto the rod, while the opposite area contracted in the circumferential direction, but extended in the radial direction. A conclusion was drawn that the yolk cell surface is a multivariant mechanosensitive system. Its active responses to mechanical influences obey the same patterns as multicellular embryonic tissues.     

In vitro dynamics of chromatin organization and migration

The organization of eukaryotic chromatin is not static but changes as a function of cell status during processes such as proliferation, differentiation, and migration. DNA quantification has not been used extensively to investigate chromatin dynamics in combination with cellular migration. In this context, an optimized DNA-specific, nonperturbant method has been developed for studying chromatin organization, using the fluorescent vital bisbenzimidazole probe Hoechst 33342: this property has been described by Hamori et al. (1980). Computer-assisted image analysis was used to follow migratory activity and chromatin organization of L929 fibroblasts during in vitro wound healing. Cell movements were analyzed using an optical flow technique, which consists in the calculation of the velocity field of cells and nuclear movements in the frame. This system allows the correlation of cell migration and position in the cell cycle. It makes it possible to study chromatin dynamics using a quantitative analysis of nuclear differentiation reorganization (nuclear texture) and to correlate this with migration characteristics. The present system would be of interest for studying cell-extracellular matrix interactions using differing substrates, and also the migratory response to chemotactic factors. Such a model is a prerequisite for gaining better understanding of drug action.     

Nerve growth factor. A structural relationship between its proteolytic and leukocyte-chemotactic active sites

Summary High molecular weight mouse nerve growth factor(H M W-NGF), in addition to its effects on certain neural elements, is also chemotactic for human polymorphonuclear leukocytes. One of the subunits of H M W-NGF is a protease of the serine family and its active site contains a serine residue and a closely-neighboring histidine residue that are both essential for proteolysis. Elimination of enzyme activity by irreversibly blocking the single serine has no effect on leukotaxis, but blocking the histidine abolishes leukotaxis. These results suggest the possibility that part of the proteolytic active site of this enzyme may have evolved to perform more than one, completely different, biologic function — proteolysis as well as nonproteolytically mediated chemotaxis.Abbreviations HMW-NGF mouse submandibular gland nerve growth factor, purified as in Ref. 1 - DFP diisopropyl-phosphofluoridate - DIP-NGF diisopropyl-phosphoryl-NGF; phe-pro-arg-CH₂C1, D-phenylalanyl-L-propyl-L-argininyl chloromethyl ketone; TLCK, N-p-tosyl-L-lysine chloromethyl ketone - TAME N-p-tosyl L-arginine methyl ester - EDTA ethylenediamine tetraacetic acid     

Morphological appearance of epidermal cells cultured on fibroblast-reorganized collagen gels

Summary Human foreskin fibroblasts were used to reorganize hydrated collagen gels into a dermal-like matrix, after which freshly isolated keratinocytes isolated from rabbit ear skin were placed on the surfaces of the matrices and cultured for up to 12 days. Transmission electron microscopy revealed 8–12 cell layers of epidermal cells organized in three distinct strata. The basal stratum consisted of cuboidal to columnar cells with typical complement of organelles, oval nuclei, and prominent tonofilaments inserting into desmosomes. Mitotic cells often were found at this level. There was no well-defined basement membrane region; rather, many of the cells appeared to be in close contact with collagen fibrils. The intermediate stratum of suprabasal cells consisted of elongated cells that had reduced organelles, but still were connected to each other by desmosomes. Finally, the superficial stratum of suprabasal cells contained cells that were completely flattened and often appeared to be sloughing off the apical surfaces of the cultures. Indirect immunofluorescence studies carried out on frozen sections revealed bullous pemphigoid antigen associated with basal epidermal cells; pemphigus vulgaris antigen around the epidermal cells of all strata, and keratin present in the epidermal cells of all strata. Filaggrin was observed in punctate and fibrillar arrangements in suprabasal cells. Fibronectin was found in a linear deposit at the dermal-epidermal junction and around the fibroblasts in the reorganized collagen gels. Type-IV collagen and laminin, however, were not detected.     

Modulation of gap junction-mediated intercellular communication in embryonic chick mesenchyme during tissue remodeling in vitro

Gap junction-mediated intercellular communication was analyzed in a model system in which tissue necrosis and remodeling could be modulated. This in vitro system, previously used for analysis of epithelial-mesenchymal tissue interaction, was modified to permit analysis of the presence and extent of intercellular communition by monitoring intercellular transfer of the micro-injected fluorescent dye, Lucifer Yellow. Light and transmission electronmicroscopy were employed to correlate the presence and degree of gap junctional communication (coupling) with tissue morphology. Digital image analysis was used to determine cell density and mitotic indices within the outgrowths of explants. Our results indicated that cell communication in outgrowths adjacent to necrotic foci within an explant was minimal or absent. Cell-coupling in outgrowths adjacent to a compartment of viable mesenchyme was significantly higher-equivalent to unseparated control cultures. A time-course study demonstrated correlation of increased levels of cell-coupling in outgrowths with the level of tissue remodeling within an explant. Our conclusions from these studies are that embryonic mesenchymal cell populations may be selectively uncoupled as a result of alterations in the microenvironment produced by a proximate impaired cell population. It is proposed that endogenous factors in the microenvironment (wound signals), emanating from impaired cell populations, regulate gap junction-mediated intercellular communication in adjacent viable tissue. Normal, unimpaired populations of cells surrounding an area of injury are thereby isolated from the effects of a potentially toxic environment. This could serve as a protective function in development and may represent, in a more general sense, part of the repertoire of events associated with tissue repair and remodeling.     

Transformation of fibroblasts into endothelial cells during angiogenesis

Light-and electron-microscopic autoradiography have been used to study fibroblast transformation into endothelial cells in the formation of new blood vessels during wound healing in rabbit ear chambers. When cultured fibroblasts labeled with tritium thymidine were transplanted autologously into the chambers, newly formed blood vessels contained endothelial cells labeled with tritium thymidine. This result suggests that fibroblasts play a pivotal role in angiogenesis, as progenitors of endothelial cells in newly formed blood vessels.     

A SIGNAL GLYCOPROTEIN WITH α-d-MANNOSYL RESIDUES IS INVOLVED IN THE WOUND-HEALING RESPONSE OF ANTITHAMNION SPARSUM (CERAMIALES,RHODOPHYTA)1

A variety of fluorescein isothiocyanate-labeled lectins specific for different sugar moieties were examined as probes for the wound-healing response in the filamentous red alga Antithamnion sparsum Tokida. Among them, only concanavalin A (ConA) and Lens culrinaris agglutinin (LCA), which have specificity to α-D-mannosyl residues, bound specifically to repair cells during the wound-healing process. When ConA or LCA was added at various time intervals after wounding, it first bound (3 h post-wounding) as a thin layer at the tips of the adjacent cells. Later (4–5 h post-wounding) labeling also appeared at the tips of the repair cells. Intense labeling at these sites continued throughout the healing process until repair cell fusion, at which time the lectin labeling was reduced to a narrow ring around the area of fusion. When added to plants prior to wounding and continually monitored, these same lectins acted as inhibitors to the wound-healing response. Other control lectins showed no inhibitory effects. A crude extract solution obtained from decapitated filaments stimulated the wound-healing response, and a lectin-binding component bound strongly to a protein-binding transfer membrane. These results suggest that the labeled compound is a glycoprotein that has α-D-mannosyl residues and is similar to the repair hormone rhodomorphin found in Griffithsia pacifica Kylin.     

LEP and LEPR are possibly a double-edged sword for wound healing

Wound healing is a complex and error-prone process. Wound healing in adults often leads to the formation of scars, a type of fibrotic tissue that lacks skin appendages. Hypertrophic scars and keloids can also form when the wound-healing process goes wrong. Leptin (Lep) and leptin receptors (LepRs) have recently been shown to affect multiple stages of wound healing. This effect, however, is paradoxical for scarless wound healing. On the one hand, Lep exerts pro-inflammatory and profibrotic effects; on the other hand, Lep can regulate hair follicle growth. This paper summarises the role of Lep and LepRs on cells in different stages of wound healing, briefly introduces the process of wound healing and Lep and LepRs, and examines the possibility of promoting scarless wound healing through spatiotemporal, systemic, and local regulation of Lep levels and the binding of Lep and LepRs.