We have examined integrin expression during the remodeling of the epidermis that takes place during wound healing, using a suction blister model in which the epidermis is detached from the dermis, leaving the basement membrane intact. By immunofluorescence microscopy, we found that the same integrin subunits were expressed during wound healing as in normal epidermis with very little change in the relative intensity or distribution of staining at the leading edge of the migrating epidermis. However, at the time of wound closure, when the epidermis is still hyperproliferative, a2, a3, a6, and t3, were no longer confined to the basal layer, as in normal epidermis, but were also found in all the living suprabasal cell layers, coexpressed with the terminal differentiation markers involucrin, keratin 10, and keratin 16. Strong suprabasal staining for a, was also found in one specimen. 4, which normally forms a heterodimer with a6, and a5 remained predominantly basal. Three of the integrin ligands, fibronectin, type IV collagen, and laminin, remained largely confined to the basement membrane zone and dermis. By 14 d after wounding, the integrins were once more restricted to the basal layer. Suprabasal integrin expression was also observed in involved psoriatic lesions. Thus, in two situations in which the epidermis is hyperproliferative, there is a failure to downregulate integrin expression on initiation of terminal differentiation. The functional consequences of this aberrant integrin expression remain to be explored. (J. Clin. Invest. 1992.
In order to study the kinetics of inactivation and recovery of the slow inward current in the mammalian ventricular myocardium voltage clamp experiments using the double sucrose gap technique were performed on isolated trabeculae and papillary muscles of cats. The separation of the slow inward current from the fast Na current was achieved by use of the conditioning clamp procedure. 1. The decay of the Ca current reflects the inactivation which develops due to depolarization. The rate of inactivation depends upon the membrane potential. Excess Ca (8.8 mM) accelerates the inactivation speed indicating that Ca ions not only act as charge carrier of the slow inward current but might influence in addition the kinetics of the slow membrane channel. In the presence of a lowered temperature a deceleration of inactivation (Q10 2.3) occurs. 2 If the membrane is repolarized a recovery process takes place restoring the availability of the slow membrane channel. As the inactivation the recovery rate depends upon the membrane potential. Excess Ca causes an acceleration whereas a decrease in temperature diminishes the recovery speed (Q10 2.3). Consequently, the Ca supply to the myocardial cell can be modified not only by changes of the transmembrane Ca concentration gradient or by an alteration of the Ca conductance of the slow channel but also by changes in the degree of recovery after a preceding Ca current. 3. Compared with the inactivation the recovery proceeds very slowly. Assuming that this slow recovery represents an inherent kinetic feature of the slow channel the kinetics of inactivation and removal of inactivation are not describable by a single inactivation variable (called as f by Reuter, 1973) which is of the Hodgkin-Huxley type. If a second inactivation variable (called as l) would be introduced additionally a formulation of the inactivation-recovery process of the slow membrane channel on the basis of the Hodgkin-Huxley model becomes feasible.
Several extracellular matrix components (procollagen type III, fibronectin, collagen type IV, laminin and nidogen) and microfilament constituents (actin, α-actinin and vinculin) were localized by indirect immunofluorescence microscopy in frozen sections of embryonic mouse molars. Nidogen was present at the epithelio-mesenchymal junction during polarization and initial steps of functional differentiation of odontoblasts. Nidogen disappeared at a stage where direct contacts between preameloblasts and predentin were required to allow the initiation of ameloblast polarization. Our observations concerning the distribution of procollagen type III and fibronectin during odontoblast differentiation add to current knowledge. Procollagen type III and fibronectin surrounding preodontoblasts accumulated at the apical part of polarizing and functional odontoblasts secreting "initial" predentin. Procollagen type III, but not fibronectin, disappeared in front of functional odontoblasts synthesizing "late" predentin and dentin. Fibronectin, present in "initial" predentin, was no longer detected in "late" predentin and dentin but was found between odontoblasts secreting "late" predentin and dentin. Actin, α-actinin and vinculin were concentrated in the peripheral cytoplasm of preameloblasts and accumulated at the apical and basal poles of functional ameloblasts. During differentiation of odontoblasts, the three proteins accumulated at the apical pole of these cells. Time and space correlations between matrix and microfilament modifications during odontoblast and ameloblast differentiation are documented. The possibility is discussed that there is transmembranous control of the cytoskeletal activities of odontoblasts and ameloblasts by the extracellular matrix.
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