Fibronectin (FN) localizations in early wound healing of cultured frog skins

The wound healing process of frog skin fragments in epibolic cultures has provided information on FN localizations during the migration of keratinocytes. Mainly two FN localizations were studied by indirect immunodetections: Epidermal localization around keratinocytes which have acquired a fibroblastic shape. Dermal localizations of the sectioned collagen of the stratum spongiosum and stratum compactum detected at the beginning of the culture. Both localizations were observed in this epibolic wound healing process during 6 hr and 24 hr in culture and showed a differential sensitivity to cycloheximide (CHX). It was worth noting that fibronectin was permanently detected in the subcutaneous tissue of non-cultured or cultured skin fragments with or without CHX.     

Fibronectin (FN) in hypertrophic scars and keloids

Summary Fibronectin (FN) distribution was compared among samples of normal human dermis, hypertrophic scar, keloid, and granulation tissues from deep injuries. Localization was established by use of fibronectin antibodies and the indirect immunofluorescence method. Fresh-frozen tissue was sectioned on a cryostat and examined by epifluorescence. Hypertrophic scar and keloid demonstrated heavy deposition of FN, which conformed to the nodular characteristics of the lesions. Intense localization occurred in granulation tissue over fibroblasts which were stellate and vesiculated, and over small blood vessels. FN-staining was weak in areas over fibroblasts which were more rounded and nonvesiculated. Staining for FN was also minimal over the collagen in normal dermis and the deeper, larger collagen fascicles in the lesions. Fibroblasts cultured from normal dermis, hypertrophic scar, and keloid for 5–6 weeks were intensely stained for FN. Extracellular matrix was heavily positive in cultures from the lesions compared with those from normal dermis.Supported in part by NIH Research Grant 1 R01GM 25159     

The volume of mitochondria-rich cells of frog skin epithelium

Summary The pathway for movement of chloride ions across frog skin is not well understood. Mitochondria-rich (MR) cells have been proposed as the route for chloride across the skin. To test this hypothesis we studied the MR cells of the skin of the frog,Rana pipiens, by quantitative light microscopic determination of cell volume. MR cell volume was influenced by changes in the chloride concentration or osmolality of the outside bathing solution. MR cells shrank about 23% when all chloride was removed from the outside (mucosal) bathing solution. MR cells were also shown to be responsive to changes in the osmolality of either the mucosal or serosal bath. Osmotically-induced swelling caused by dilution of the serosal bath resulted in volume regulatory decrease. These results are consistent with the hypothesis that MR cells constitute the pathway for chloride movement across frog skin.     

Localization of chloride conductance to mitochondria-rich cells in frog skin epithelium

Summary Cell volume determinations and electrophysiological measurements have been made in an attempt to determine if mitochondria-rich (MR) cells are localized pathways for conductive movements of Cl across frog skin epithelium. Determinations of cell volume with video microscope techniques during transepithelial passage of current showed that most MR cells swell when the tissue is voltage clamped to serosa-positive voltages. Voltage-induced cell swelling was eliminated when Cl was removed from the mucosal bath solution. Using a modified vibrating probe technique, it was possible to electrically localize a conductance specifically to some MR cells in some tissues. These data are evidence supporting the idea that MR cells are pathways for conductive movements of Cl through frog skin epithelium.     

Electron microscopic research on the mitochondria-rich bladder cells of the frog

The ultrastructural peculiarities of mitochondria-rich cells of the frog urinary bladder are analysed using three electron microscopic methods: ultrathin sections, scanning electron microscopy, freeze fracture. The mitochondria and tubular and vesicular structures are most abundant in the apical region of cytoplasm. The P-face (PF) of the apical plasma membrane is characterized by the presence of rod-shaped intramembrane particles (IMP), whereas the E-face (EF) possesses complementary pits. Depending on the distribution density of the rod-shaped IMP, three types of cells are described. The apical plasma membrane has an invert distribution of the globular IMP: a great quantity of IMP on the EF and a few particles on the PF. This structure of the apical plasma membrane is supposed to correlate with its very low water permeability. Using filipin as a marker of cholesterol localization, it has been shown that the mitochondria-rich cell apical membrane contains more cholesterol than that of the granular cells. The nature of the rod-shaped IMP and their role in the transmembrane ion transport have been discussed.     

The function of mitochondria-rich cells (chloride cells) in teleost gills

Summary The CCs are the site of Cl^– transport in teleosts in sea water. The gills of freshwater teleosts contain at least two types of mitochondria-rich cell, the type and the type (Pisam and Rambourg, 1991). During seawater acclimation, the cells vanish and the cells are transformed and proliferate, and accessory cells appear in addition. This gives rise to the question of the function of cells in fish living in fresh water.According to the studies reviewed here, although they deal only with extrabranchial epithelia, the majority of evidence indicates that CCs (or MRCs) function as sites of active Ca²⁺ transport in freshwater teleosts. Moreover, some experimental results suggest that CCs are the Cl^– uptake site in freshwater teleosts. The main problem in characterizing the CC function is that they have not yet been adequately described from the biochemical standpoint. This applies particularly to their metabolic pattern and the composition of their apical and basolateral membranes, including their integrated proteins and cell-cell junctions.Experiments with organ tissue cultures such as gill organ cultures from Oncorhynchus mykiss (McCormick and Bern, 1989) and opercular membrane cultures from Oreochromis mossambicus (McCormick, 1990) will almost certainly yield important results. Primary cell cultures of CCs would be even better for characterizing CCs. Such a cell culture of rainbow trout respiratory cells has already been established (Pärt et al., 1993).     

Fine structure of clear cells in frog epidermis

The fine structure of clear cells located within the frog epidermis was investigated. Characteristic features of clear cells were, the 'flask-like' shape, the sparse amount of filaments resulting in a clear cytoplasmic appearance, abundant mitochondria, numerous small vesicles, and a system of convoluted apical membranes in cells adjacent to horny cells. These features were suggestive of a secretory function for the clear cell. A comparison of clear cells with fully differentiated epidermal cells (functioning in protection) was made, in an attempt to discover how structural differences between the two cells were related to the basic functions of the cells.     

Immunocytochemical detection of mitochondria-rich cells in the brood pouch epithelium of the pipefish, Syngnathus schlegeli : structural comparison with mitochondria-rich cells in the gills and larval epidermis

The brood pouch of the male pipefish (Syngnathus schlegeli) is a ventral organ located on the tail, with the anterior region closely associated with the genital pore. The embryos in the pouch are attached to highly vascularized placenta-like tissue which seals the pouch folds from inside during incubation. The epithelium of the placenta-like tissue consists of mitochondria-rich cells (MRCs) and pavement cells. Differences in MRC morphology in the brood pouch epithelium, the gills and the larval epidermis of the pipefish were examined by light and electron microscopy. Transmission electron microscopy revealed that the MRCs in the brood pouch and the gills shared common characteristics: the presence of numerous mitochondria packed among a well-developed tubular system and the close association of the basal parts with the capillaries running underneath the epithelia. The size of the apical opening of the elongate, flask-shaped brood pouch MRC was about one-tenth that of the apical pit of the gill MRC. The gill and larval epidermal MRCs formed a multicellular complex, in contrast to solitary brood pouch MRCs. The brood pouch MRCs were intensively stained by immunocytochemistry with an antiserum specific for Na⁺,K⁺-ATPase. The Na⁺ concentrations in the brood pouch were maintained near those in the serum rather than seawater during incubation. We conclude that the brood pouch MRCs function as an ion-transporting cell, absorbing ions from the brood pouch lumen, perhaps to protect the embryos from the hyperosmotic environment.     

Intracellular ion concentrations in the isolated frog skin epithelium: Evidence for different types of mitochondria-rich cells

Summary Intracellular ion concentrations were determined in split skins of Rana pipiens using the technique of electron microprobe analysis. Under control conditions, principal cells and mitochondria-rich cells (MR cells) had a similar intracellular ion composition, only the Cl concentration in MR cells was significantly lower. Inhibition of transepithelial Na transport by low concentrations of ouabain (2 × 10^–6 m, innerbath) resulted in a Na concentration increase of principal cells from 10.9 to 54.3 mmol/kg wet wt. The increase was completely abolished by simultaneous application of amiloride (10^–4 m, outer bath). Amiloride alone resulted in a significant decrease of the Na concentration to 6.1 mmol/kg. w. w. Among MR cells, two different groups of cells could be distinguished; cells that showed a Na increase after ouabain which was even larger than that in principal cells and cells that did not respond to ouabain. In about half of all ouabain-sensitive MR cells the Na increase could be prevented by amiloride. According to these results, a subpopulation of MR cells displays the transport characteristics expected for a transepithelial Na transport compartment, an apical amiloride-sensitive Na influx and abasal ouabain-inhibitable Na efflux. Given the small number of cells, however, it is unlikely that this subtype of MR cells contributes significantly to the overall rate of transepithelial Na transport.I wish to thank Cathy Langford, Cindy Partain, and Ray Whitfield for their excellent technical assistance. Financial support was provided by NIH grants DK35717 and 1S10-RR0-234501.     

Mucus cells in koi (Cyprinus carpio) scale epidermis

Morphological and dynamic characteristics of epidermal mucus cells were examined in intact scales of Cyprinus carpio. Mucus cells were identified by alcian blue staining and live mucus cells characterized with differential interference contrast microscopy. Mucus cell pores were shown to be narrow slits or triangular‐shaped openings which are invariably situated at cell‐cell junctions. Small granules were often located at or just below the openings with larger granules positioned deeper into the cell. The large granules were observed to undergo a bubbling‐like activity, where a granule suddenly appears, enlarges and then abruptly disappears. Situated below the large granules is a dense matrix of quiescent small, tightly packed mucin granules. The findings suggest that mature epidermal mucus cells are structurally ordered with respect to secretory activity, where small numbers of initially basally located, densely packed granules rapidly expand in a location proximal to the pore and presumably prior to mucus release through the pore.     

Ion transport by mitochondria-rich cells in toad skin

Summary The optical sectioning video imaging technique was used for measurements of the volume of mitochondria-rich (m.r.) cells of the isolated epithelium of toad skin. Under short-circuit conditions, cell volume decreased by about 14% in response to bilateral exposure to Cl-free (gluconate substitution) solutions, apical exposure to ouabain resulted in a large increase in volume, which could be prevented either by the simultaneous application of amiloride in the apical solution or by the exposure of the epithelium to bilateral Cl-free solutions. Unilateral exposure to a Cl-free solution did not prevent ouabain-induced cell swelling. It is concluded that m.r. cells have an amiloride-blockable Na conductance in the apical membrane, a ouabain-sensitive Na pump in the basolateral membrane, and a passive Cl permeability in both membranes. From the initial rate of ouabain-induced cell volume increase the active Na current carried by a single m.r. cell was estimated to be 9.9±1.3 pA. Voltage clamping of the preparation in the physiological range of potentials (0 to –100 mV, serosa grounded) resulted in a cell volume increase with a time course similar to that of the stimulation of the voltage-dependent activation were prevented by exposure of the tissue to a Cl-free apical solution. The steady-state volume of the m.r. cells increased with the clamping voltage, and at –100 mV the volume was about 1.15 times that under short-circuit conditions. The rate of volume increase during current passage was significantly decreased by lowering the serosal K concentration (K _i ) to 0.5mm, but was independent of whether K _i was 2.4, 5, or 10mm. This indicates that the K conductance of the serosal membrane becomes rate limiting for the uptake of KCl when K _i is significantly lower than its physiological value. It is concluded that the voltage-activated Cl currents flow through the m.r. cells and that swelling is caused by an uptake of Cl ions from the apical bath and K ions from the serosal bath. Bilateral exposure of the tissue to hypo- or hypertonic bathing solutions changed cell volume without detectable changes in the Cl conductance. The volume response to external osmotic perturbations followed that of an osmometer with an osmotically inactive volume of 21%. Using this value and the change in cell volume in response to bilateral Cl-free solutions, we calculated an intracellular steady-state Cl concentration of 19.8±1.7mm (n=6) of the short-circuited cell.     

Branchial mitochondria-rich cells in the dogfish Squalus acanthias

In marine teleost fishes, the gill mitochondria-rich cells (MRCs) are responsible for NaCl elimination; however, in elasmobranch fishes, the specialized rectal gland is considered to be the most important site for salt secretion. The role of the gills in elasmobranch ion regulation, although clearly shown to be secondary, is not well characterized. In the present study, we investigated some morphological properties of the branchial MRCs and the localization, and activity of the important ionoregulatory enzyme Na(+)/K(+)-ATPase, under control conditions and following rectal gland removal (1 month) in the spiny dogfish, Squalus acanthias. A clear correlation can be made between MRC numbers and the levels of Na(+)/K(+)-ATPase activity in crude gill homogenates (r(2)=-0.69). Strong Na(+)/K(+)-ATPase immunoreactivity is also clearly associated with the basolateral membrane of these MRCs. In addition, the dogfish were able to maintain ionic balance after rectal gland removal. These results all suggest a possible role of the dogfish gill in salt secretion. MRCs were, however, unresponsive to rectal gland removal in terms of changes in number, fine structure and Na(+)/K(+)-ATPase activity, as might be expected if they were compensating for the loss of salt secretion by the rectal gland. Thus, the specific role that these MRCs play in ion regulation in the dogfish remains to be determined     

Hydroxylating activity of frog epidermis tyrosinase.

Trypsin activated in a similar way both the tyrosine hydroxylase and the dopa-oxidasa activities of frog epidermis tyrosinase. Several electron donors reduced or eliminated the lag period for the hydroxylating enzyme. 4 x 10(-5) M dopa was particularly effective, but without affecting the stationary activity after lag period. Tyrosine hydroxylase had KM = 2.6 X 10(-3) M for tyrosine and 2 x 10(-3) M dopa was a competitive inhibitor with Ki = 5 x 10(-4) M. The enzyme was inactivated during its actuation. Data on thermal denaturation were similar to other obtained from dopa oxidase. Our results tend to confirm our previous hypothesis that the activatory process of the enzyme is accompanied by a spatial unfolding of the enzyme molecule.     

Dithiothreitol inactivation of frog epidermis tyrosinase.

Frog epidermis tyrosinase inactivation by dithiothreitol (DTT), both in the proenzyme and active forms, have been studied. Upon increasing DTT:enzyme-up to 1o(6):1 ratios and depending on the incubation period, two inactivation steps both in proenzyme and enzyme were observed. Enzyme lost its activity faster than proenzyme. Oxygen favoured inactivation. After dialysis of the DTT:protein (10(6):1) incubation medium, 20% of the original enzyme activity was recovered. However it decreased to 15% if the enzyme had been incubated with substrate. Conformational changes due to loss of activity were not shown on the fluorescence spectra.     

Stimulation of Cl- uptake and morphological changes in gill mitochondria-rich cells in freshwater tilapia (Oreochromis mossambicus)

The purpose of the present article is to examine the relationships between ion uptakes and morphologies of gill mitochondria-rich (MR) cells in freshwater tilapia. Tilapia were acclimated to three different artificial freshwaters (high Na [10 mM], high Cl [7.5 mM]; high Na, low Cl [0.02-0.07 mM], and low Na [0.5 mM], low Cl) for 1 wk, and then morphological measurements of gill MR cells were made and ion influxes were determined. The number and the apical size of wavy-convex MR cells positively associated with the level of Cl(-) influx. Conversely, Na(+) influx showed no positive correlation with the morphologies of MR cells. The dominant MR cell type in tilapia gills changed from deep-hole to wavy-convex within 6 h after acute transfer from a high-Cl(-) to a low-Cl(-) environment. Deep-hole MR cells became dominant 24-96 h after acute transfer from a low-Cl(-) to a high-Cl(-) environment. We conclude that wavy-convex MR cells associate with Cl(-) uptake but not Na(+) uptake, and the rapid formation of wavy-convex MR cells reflects the timely stimulation of Cl(-) uptake to recover the homeostasis of internal Cl(-) levels on acute challenge with low environmental Cl(-).     

Adaptive changes of H+ secreting cells in the epidermis of the leopard frog Rana pipiens

1. Mitochondria-rich (MR) cells in the integument of the southern leopard frog, Rana pipiens, berlandieri, were stained with AgNO3 under a variety of environmental and metabolic treatment conditions known to increase H+ excretion rates across the skin. In this tissue AgNO3 proved to be a good stain for discriminating the MR cell populations from the granular cells. 2. High salinity adapted southern frogs showed no change in the MR cell population. The inability of the MR cell number to significantly increase suggested that the increased H+ excretion rates previously seen in these animals were not due to increased MR cell proliferation. 3. The MR cell population was found to increase in the NaNO3 adapted frogs, demonstrating the contribution of altered extracellular Cl- concentrations on the regulation of MR cell density. 4. Animals that were placed in chronic metabolic acidosis or pre-treated with ibuprofen demonstrated an increased MR cell population. The current observations are consistent with previous findings that these treatment regimes increase H+ excretion, suggesting that one of the cellular adaptive mechanisms responsible for increasing H+ excretion involves increasing the MR cell density. 5. The results further suggest that prostaglandins may play a role in regulating H+ excretion in MR cells, and that either changes in intracellular pH or prostaglandin formation regulates cell proliferation.