The opioid growth factor, [Met5]-enkephalin, inhibits DNA synthesis during recornification of mouse tail skin

Opioid peptides serve as tonically active negative growth regulators in renewing and regenerating epithelia. To examine the involvement of opioids in renewal of the stratum corneum after tape stripping of tail skin, C57BL/6 J mice were given systemic injections of the potent opioid antagonist, naltrexone (NTX, 20 mg/kg i.p.) following injury. Blockade of opioidreceptor interaction by NTX for 4 h resulted in an elevation of 36–;66% in basal cell DNA synthesis measured 24 h after injury. Injection of the endogenous opioid peptide, [Met⁵]-enkephalin (OGF, 10 mg/kg i.p.) 4 h before termination, suppressed radiolabelled thymidine incorporation in the basal cell layer by 37–46%at 24 h after wounding. The magnitude of the effects on DNA synthesis of OGF, but not NTX, depended on the timing of administration with respect to injury. OGF maximally depressed basal cell labelling (72%) when given 16 h after tape stripping. Concomitant administration of naloxone (10 mg/kg) with OGF blocked the inhibition of DNA synthesis; naloxone alone at the dosage utilized had no effect on cell labelling. Both OGF and its receptor, OGFr, were detected by immunocytochemistry in the basal and suprabasal cell layers, but not the cornified layer of tape stripped and uninjured tail skin. These results indicate: (a) a native opioid peptide and its receptor are expressed in epidermal cells of injured and uninjured mouse tail skin; (b) removal of the stratum corneum by tape stripping does not disrupt the function of the endogenous opioid growth system; (c) the proliferative response to wounding of the tail is tonically inhibited by the receptor-mediated action of an endogenous opioid peptide; and (d) DNA synthesis by basal cells can be elevated by disrupting opioid peptidereceptor interactions.     

Localization of sites of lipid biosynthesis in mammalian epidermis

The end-product of epidermal differentiation is a stratified layer of corneocytes whose extracellular lipid bilayers provide a permeability barrier. It is generally accepted that the epidermis synthesizes most if not all of the lipids found in this tissue and that extra-epidermal tissues contribute very little to this lipid content. Moreover, the individual epidermal strata in which epidermal lipid biosynthesis occurs are not known. To address this question, we examined [3H]H2O incorporation into nonsaponifiable and saponifiable lipids in individual epidermal cell layers 3 hr after intraperitoneal injection into neonatal mice, and compared this to protein and DNA synthesis using intraperitoneal [3H]leucine and [3H]thymidine incorporation, respectively. Lipid biosynthesis was also assessed by [14C]acetate incorporation into lipid fractions in organ cultured skin and in epidermal subpopulations. The in vivo studies demonstrated that the biosynthetic activity of both saponifiable and nonsaponifiable lipids was comparable to, if not greater, in the stratum granulosum (SG) than in basal/spinous (SB + SS) layer, despite significantly lower levels of both protein and DNA synthesis in the SG. On a mass basis, the SG accounts for about four times the biosynthetic activity of the combined SB + SS layers. The lipid biosynthetic activity in vitro also was two- to fivefold higher in the SG, regardless of whether the epidermis was separated into individual cell layers before or after incubations with radiolabel. Moreover, this difference could not be ascribed to increased acetate pools or to elevated metabolism in the SG versus the SB + SS since the rates of CO2 production were much lower in the SG fraction. The increase in lipid biosynthesis in SG over SB + SS was greatest for phospholipids, followed by glycosphingolipids, and free sterols but was observed in almost all lipid classes. These studies show not only that mammalian epidermis is an active site of de novo lipid biosynthesis, but also that this activity remains high in the stratum granulosum, while other forms of metabolic activity are diminishing. These observations are consistent with the knowledge that lipids extruded from the stratum granulosum layer provide the hydrophobic permeability barrier, and further suggest that elevated synthetic activity in the stratum granulosum would allow rapid replenishment in the event that the barrier is damaged.     

Evidence that microtubule depolymerization early in the cell cycle is sufficient to initiate DNA synthesis

Microtubule disrupting drugs initiated DNA synthesis in serum-free cultures of nonproliferating fibroblast-like cells. The addition of colchicine to chick, mouse and human fibroblasts in serum-free medium stimulated thymidine incorporation at least twofold, with a half-maximal concentration of 1 X 10(-7) M. This stimulation represented up to 75% of the maximal stimulation by thrombin and was paralleled by an increase in the percentage of labeled nuclei. Other microtubule disrupting drugs showed similar stimulation, whereas lumicolchicine had no effect. Indirect immunofluorescent staining of tubulin showed a correlation between microtubule depolymerization and initiation of DNA synthesis by these drugs. A 2 hr treatment with 10(-6) M colchicine caused complete disruption of the microtubular network and stimulated thymidine incorporation (measured 28 hr later) to an even greater extent than continuous colchicine exposure. A similar 2 hr exposure to 10(-6) M colcemid also stimulated thymidine incorporation and led to a 50% increase in cell number. Taxol, a drug which stabilizes cytoplasmic microtubules, blocks initiation of DNA synthesis by colchicine, indicating that microtubule depolymerization is necessary for this initiation. To determine if microtubule depolymerization is involved in stimulation of DNA synthesis by other growth factors, highly purified human thrombin was added to cells with or without colchicine. In no case did colchicine plus thrombin increase DNA synthesis above that of the maximal stimulation by thrombin alone. Furthermore, pretreatment of cultures with taxol (5 micrograms/ml) inhibited approximately 30% of the stimulation of thymidine incorporation by thrombin. Together, these studies demonstrate that microtubule depolymerization is sufficient to initiate both DNA synthesis and events leading to cell division and suggest that microtubule depolymerization may be a required step in initiation of cell proliferation by growth factors such as highly purified human thrombin.     

The epidermal permeability barrier. Comparison between in vivo and in vitro lipid structures

The epidermal permeability barrier is established by the lamellar contents of membrane-coating granules which are discharged into the intercellular space of the stratum granulosum and form continuous lipid layers in the stratum corneum. Artificial lipid systems, prepared with a composition similar to that found in stratum granulosum and stratum corneum, were able to form a lamellar phase. These systems show dense line thickness and center-to-center spacing comparable to those found in membrane-coating granules and intercellular layers. The significance of lipid composition in relation to barrier function is discussed and a model showing the molecular arrangement of the lipid structures in the epidermal barrier is proposed.     

Protein phosphorylation in anti-actin IgG and [(IgG)2protein A]2 complex-stimulated L cells

Phosphorylation of cellular proteins was stimulated in a dose-dependent manner by the surface binding of IgG antibodies to antigens on L cells. Most prominent among the phosphorylated cellular proteins were Mr = 115,000, 93,000, 58,000, 38,000, and 33,000 proteins. Stimulation of protein phosphorylation was maximal at 48 hr of incubation and was preceeded by maximal stimulated uridine incorporation into RNA (0-24 hr) and thymidine incorporation into DNA (24-48 hr), and followed by maximal stimulated cell proliferation occurring at 72 hr (P less than 0.001 for all differences). Modification of the ligand IgG molecule by formation of complexes with protein A (PA) altered the stimulation patterns of protein phosphorylation: [(IgG)2(PA)]2, Mr = 716,000, enhanced and (IgG)(PA), Mr = 200,000, inhibited phosphorylation. The nature of the cell surface antigen(s) was partially clarified by the demonstration that affinity-purified antibodies to cytoskeletal proteins (principally a surface actin molecule) accounted for a significant part of the stimulation effect. Thus, perturbation of the L-cell membrane by certain molecular forms of anti-actin IgG antibody produces a transmembrane signal resulting in an orderly series of metabolic events including enhanced protein phosphorylation at 48 hr occurring just prior to enhanced cell growth.     

The phosphatidylinositol response and proliferation of oxidative enzyme-activated human T lymphocytes: suppression by plasma lipoproteins

The phosphatidylinositol (PI) response and DNA synthesis of neuraminidase and galactose oxidase (NAGO)-stimulated human T lymphocytes are suppressed by low density lipoproteins (LDL). To understand the mechanism of lymphocyte activation more fully, the PI response and DNA synthesis and suppression of these events by LDL in NAGO-stimulated T lymphocytes were characterized. Between 30 min and 6 hr after NAGO stimulation, there was an increase of 32Pi incorporation into PI without increased incorporation into the phosphorylated forms of PI or into other phospholipids. DNA synthesis as determined by [3H]thymidine incorporation depended on the lymphocyte-accessory monocyte ratio and total cell density. Optimal stimulation of the PI response and DNA synthesis occurred at the same concentration of neuraminidase and galactose oxidase. While the PI response was only partially suppressed by LDL with optimal suppression at 10 to 20 micrograms of protein/ml, DNA synthesis was completely suppressed although at much higher LDL concentrations, greater than 100 micrograms protein/ml. As monocyte numbers are increased, LDL suppression of DNA synthesis is decreased. The ability of NAGO to stimulate the PI response and DNA synthesis in a similar way, and the suppression of both events by LDL, suggests the PI response is important for lymphocyte activation and proliferation. Stimulation of human T lymphocytes by oxidative mitogens, neuraminidase, and galactose oxidase caused increased phosphatidylinositol metabolism and increased DNA synthesis. Both responses were suppressed by low density lipoproteins.     

Time-dependent effects of removal of the pars distalis of the pituitary gland on toad epidermal cell and tissue kinetic parameters

Abstract. Amphibian moulting and its hormonal control has been extensively studied, but the possible influence of hormones on epidermal proliferation has been less investigated. In the present contribution to studies on the control of epidermal homeostasis, the proliferative pattern of the toad epidermis following ablation of the pars distalis of the pituitary gland is analysed by an investigation of the changes in the epidermal cell number, metaphase index and [³H]thymidine incorporation at various times after the operation. During the first 24 hr after pars distalis ablation, labelling index (LI) increased concurrently with an initial decrease in the metaphase index (MI), followed by an increase. During the same period of time the mean grain count (MGC) and the grain distribution pattern also changed. From 24 hr to 7 days after operation, MI, LI, and MGC were significantly lower than those of controls, but increased to control levels at 14 days after the operation. Phase durations and their possible changes were not measured directly, but data showed that the S-phase duration (Ts) and the mitotic duration (TM) must have changed in relation to each other during the experiment. Assuming that the MGC is a rough estimate of the DNA-synthesis rate, the compatibility of a postulated change in phase duration with the observed MGC was analysed. This analysis revealed that TS and TM could have decreased up to 18 hr after the operation, whereas these phase durations, after 24 hr and during the rest of the experiment, increased compared to those of controls. Even with these possible changes in phase durations, and in the absence of direct assessment of cell division rates, the observed cell kinetic parameters appeared incompatible with an increased rate of proliferation. This was surprising since the efflux of cells from the living, subcorneal epidermis to the stratum corneum was significantly increased after pars distalis ablation, without a concurrent decrease in the stratum corneum recruitment cell pool (SCRP-number of subcorneal epidermal cells per mm surface). Possible reasons for the discrepancy between the expected increase in proliferation following pars distalis ablation, and the failure to demonstrate this, are discussed.     

Modified distribution of epidermal glycoproteins in the nude mouse

The nude mouse is an athymic mutant whose immunological deficiency has been exploited for transplantation of normal and diseased xenogeneic tissue. Histologically, its skin has no unusual features apart from the absence of hair. We report here a biochemical study of its epidermis, with comparison to the hairless mouse (which is devoid of hair but otherwise functionally normal). The epidermal glycoproteins were probed with the lectin, concanavalin A (Con A). Fluorescein isothiocyanate (FITC)-Con A overlays of cryostat skin sections gave a similar fluorescent pattern for both mouse strains: all the viable epidermal cell layers were labeled but not the stratum corneum. In contrast, when different populations of keratinocytes that were separated on Percoll gradients were analyzed by gel electrophoresis, and the gels then overlaid with iodinated Con A, all the epidermal layers, including the stratum corneum, were labeled. For all the epidermal cell layers there are substantial differences between the two mouse strains. We observe changes in the glycoprotein distribution with the stage of differentiation. Comparison with our earlier data for human epidermis indicates that the discrepancies between the nude mouse and the hairless mouse are much greater than those between the latter and man. The most striking difference is the absence in the stratum corneum of the nude mouse of a 40 K glycoprotein which is the dominant feature for the hairless mouse and for man. The gel patterns point to functional discrepancies in the epidermis of the nude mouse, particularly in the stratum corneum, not evident histologically or with FITC-Con A.     

1,25-Dihydroxyvitamin D3 stimulates specifically the last steps of epidermal differentiation of cultured human keratinocytes

Human keratinocytes grown on deepidermized dermis (DED) are able to reconstruct a morphologically normal stratified and keratinized epidermis. This culture system is suitable for studying in vitro the effects of various hormones and factors on epidermal differentiation, and the goal of the present work was to study the effect of vitamin D. We found that the hormonal form of vitamin D3, 1,25-dihydroxyvitamin D3, produced very specific alterations in epidermal architecture in a dose-dependent manner, consisting of significant reduction of the nucleated layers of the epithelium, but not of the stratum corneum, which was instead slightly thickened. The study of stage-specific differentiation markers showed that the two extreme layers of epidermis, i.e. the basal layer and the stratum corneum, were unaffected by the hormone, but that the reduction involved specifically the intermediate differentiation compartment, i.e. the spinous and granular layers. It was shown that the reduction of the intermediate compartment provoked by 1,25-dihydroxyvitamin D3 is not due to a block in the proliferation of basal cells or to inhibition of their differentiation into suprabasal cells, but to stimulation of the terminal differentiation of suprabasal cells into corneocytes.     

Lipokeratinocytes of the epidermis of a cetacean (Phocena phocena)

Summary Biochemical and ultrastructural analysis of epidermis from the porpoise, Phocena phocena, revealed certain similarities and differences between cetaceans and terrestrial mammals. The predominant cell of cetacean epidermis, not found in normal terrestrial mammals, is a lipoker-atinocyte, which elaborates not only keratin filaments, but also two types of lipid organelles: first, lamellar bodies, morphologically identical to those of terrestrial mammals, are elaborated in great abundance in all suprabasal epidermal layers, forming intercellular lipid bilayers in the stratum corneum interstices: and second, non-membrane-bounded droplets appear and persist in all epidermal layers. Although the porpoise lipokeratinocyte morpologically resembles the sebokeratocyte of avians in certain respects, nonmembrane-bounded lipid droplets are not released into the intercorneocyte space as they are in avian stratum corneum. Whereas phospholipid/neutral lipid gradients are similar in porpoise and terrestrial mammals, PAS-positive glycoconjugates, specifically glycosphingolipids, are retained in porpoise stratum corneum, but lost from these layers in terrestrials. The novel, non-polar acylglucosyl-ceramides, which also are lost during cornification in terrestrial mammals, are retained in porpoise stratum corneum. The lipid components of porpoise lipokeratinocytes appear to subserve not only barrier function in a hypertonic milieu, but also underlie the unique buoyancy, streamlining, insulatory, and caloric properties exhibited as adaptations to the cetacean habitat.     

Limitations in the use of [3H]thymidine incorporation into DNA as an indicator of epidermal keratinocyte proliferation in vitro

The validity of using the incorporation of [3H]thymidine into DNA as an indicator of epidermal keratinocyte proliferation in vitro has been investigated. Other parameters of cell proliferation, direct count of cell number and measurement of DNA content, consistently fail to correlate with changes in [3H]thymidine incorporation into DNA in primary and first passage cultures of rabbit and human epidermal keratinocytes. Maximum incorporation of [3H]thymidine precedes the active growth period by three days. Incorporation declines markedly during the proliferative period. Thymidine kinase activity decreases during the proliferative growth phase. Incorporation of another pyrimidine nucleotide precursor, [14C]aspartic acid, suggests that in epidermal keratinocytes in vitro the extent of utilization of the salvage and the de novo pathways may be inversely related. In such cases [3H]thymidine incorporation into TCA precipitable material fails to reflect accurately cell proliferation.     

The incorporation of thymidine into deoxyribonucleic acid in mouse fibroblasts infected with polyoma virus

1. Mouse-fibroblast cultures in the stationary phase of growth show an increased rate of [(3)H]thymidine incorporation into DNA from 12 to 44hr. after infection with polyoma virus. 2. Intracellular virus progeny is first detected at about 24hr. after infection. 3. Calculations based on the [(3)H]thymidine-incorporation data and direct measurements of the DNA content of the cell cultures indicate that the amount of the excess of DNA synthesized by the infected cell cultures corresponds to about 10% of their total DNA. 4. The mitotic index of the cell cultures at 40hr. after infection was significantly higher than that of non-infected control cells. 5. Possible interpretations of the stimulation of DNA synthesis observed in polyoma-infected cell cultures are discussed.     

Changes in structure of ventral epidermis of Rana ridibunda during metamorphosis

Summary The organisation of the ventral epidermis organisation was followed throughout ontogenesis in Rana ridibunda. Epidermis of tadpoles with 2–3 limbs was organised into two layers: a stratum germinativum consisting of elongated columnar cells, and an outer stratum corneum consisting of two types of cuboid cells. Two types of cells can be distinguished; they are a light (clear) cell and a dark (dense) cell. In the 4-legged tadpoles the stratum corneum cells start to flatten and a replacement layer appeared underneath. A well-defined stratum germinativum is found and within it, epidermal glands. Moulting took place for the first time in tadpoles just before metamorphosis, and a well-organised stratum granulosum was formed still containing the two main types of epidermal glands. The flask cells appear in the juveniles for the first time, greatly increasing in numbers in the adult epidermis.     

Biosynthetic pathways of filaggrin and loricrin--two major proteins expressed by terminally differentiated epidermal keratinocytes

We have used immunoelectron microscopy to map the biosynthetic pathways of loricrin and filaggrin in epidermal keratinocytes at successive stages of differentiation in newborn mouse skin. The filaggrin epitope is first detected in large, irregularly shaped, keratohyalin granules (F-granules) in the stratum granulosum, and then distributed throughout the cytoplasms of the innermost layers of stratum corneum cells. We conclude that the poly-protein filaggrin precursor is first accumulated in F-granules, from which it is subsequently released and processed into filaggrin, and becomes associated with the densely packed bundles of keratin filaments inside stratum corneum cells. Its diminished visibility in the outer layers correlates with the known degradation of filaggrin to free amino acids. Loricrin is first detected in small round keratohyalin granules (L-granules), and subsequently at the periphery of cells throughout the stratum corneum. Labeling of purified keratinocyte envelopes establishes that this loricrin epitope is exposed only at their inner (cytoplasmic) surface. Thus loricrin is initially accumulated in L-granules, to be released at a specifically programmed stage of keratinocyte maturation, and incorporated into the covalently cross-linked lining of the cell envelope. Since loricrin is rich in cysteine, L-granules account for the sulfur-rich keratohyalin granules described earlier. Proposals are made to rationalize why, subsequent to synthesis, filaggrin precursor and loricrin should be segregated both from each other and from the rest of the cytoplasm.     

beta-Glucocerebrosidase activity in murine epidermis: characterization and localization in relation to differentiation.

The intercellular lipids of the stratum corneum, which are highly enriched in ceramides, are critical for the mammalian epidermal permeability barrier. During the terminal stages of epidermal differentiation, the glucosylceramide content is dramatically reduced, while the content of free ceramides increases. To investigate whether beta-glucocerebrosidase (beta-GlcCer'ase) could be responsible for this change in lipid content, we characterized its activity in murine epidermis, compared enzyme activity to other murine tissues, and localized beta-GlcCer'ase activity within the epidermis. Epidermal extracts demonstrated linear 4-methylumbelliferyl-beta-D-glucose hydrolysis (to 3 h) with protein concentrations between 1 and 250 micrograms/ml. Whole epidermis contained comparable beta-glucosidase activity (9.1 +/- 0.4 nmol/min per mg DNA) to murine brain and liver, and 5-fold higher activity than spleen. Epidermal beta-glucosidase activity was stimulated greater than 15-fold by sodium taurocholate at pH 5.6, and inhibited at acidic pH (3.5-4.0). Bromoconduritol B epoxide (greater than or equal to 1.0 microM), inhibited epidermal enzyme activity by greater than 75%, while activity in brain, liver, and spleen was only inhibited by 6, 17, and 14%, respectively. Moreover, beta-GlcCer'ase mRNA expression in murine epidermis exceeded levels in liver, brain, and spleen. Finally, beta-GlcCer'ase activity was highest in the outer, more differentiated epidermal cell layers including the stratum corneum. In summary, mammalian epidermis contains an usually high percentage (approximately 75%) of beta-glucocerebrosidase activity, and the concentration of activity in the more differentiated cell layers may account for the replacement of glucosylceramide by ceramides in the outer epidermis.     

The stimulation of DNA synthesis by cytochalasin B in proliferative epidermal and dermal cells

Cytochalasin B influences a variety of cellular events that are associated with the contractile microfilament system and the formation of binucleate cells. Along with the formation of binucleate cells, cytochalasin B also causes an acceleration of cells from G1 to S in the cell cycle. By pulsing the cytochalasin B for 30 minutes and allowing for a previously established lag time (17.5 hours) a stimulation of thymidine incorporation into DNA of proliferative epidermal and dermal cells was found in both control and stripped epidermis. Autoradiographic analysis confirmed that the stimulation was due to an increased number of basal cells accelerated from G1 to S phase. A minimal number of binucleate basal cells, 1 in 300, was observed, which suggests that the stimulated synthesis is independent of binucleate cell formation. The amount of stimulation is maximum with cytochalasin B concentration pulse between 5gamma and 30gamma/ml. The results suggest a possible link in coupling cell membrane and surface events with subsequent increased cell nuclei synthetic activity.     

DNA polymerase, thymidine kinase and DNA synthesis in erythropoietic mouse spleen cells separated on bovine serum albumin gradients.

A single dose of erythropoietin stimulates DNA synthesis in the spleen of the polycythemic mouse with the maximum effect occurring 48 h after the hormone is administered. The increase in DNA synthesis is accompanied by morphologic evidence of increased erythropoiesis and by increases in the activities per cell of both thymidine kinase and cytoplasmic high molecular weight DNA polymerase-alpha. The activity of low molecular weight DNA polymerase-beta does not change significantly. Spleen cells from mice which had received either erythropoietin or saline 48 h previously were separated into 7 density classes on discontinuous bovine serum albumin gradients. Following the administration of erythropoietin, thymidine incorporation and thymidine kinase activity showed the greatest relative increases per nucleated cell in layers 3, 4 and 5 of the gradient. DNA polymerase-alpha showed the greatest increase in cells of the denser layers 5, 6 and 7. Each layer contained normoblasts and lymphocytes. The less well differentiated erythroid elements constituted a larger proportion of cells in layers of lower density. Increases in the rates of thymidine incorporation were better correlated with increases in thymidine kinase activity than with increases in DNA polymerase activities. Measurement of iron incorporation into heme confirm the morphological impression that the cell type responsible for increased thymidine incorporation and increased DNA polymerase-alpha activity is the young normblast.     

Induction of ornithine decarboxylase in guinea pig lymphocytes by the divalent cation ionophore A 23187. Effect of dibutyryladenosine 3',5'-monophosphate

The divalent cation ionophore, A23187, at a concentration of 0.25 microgram/ml, enhanced influx of Ca2+, activity of ornithine decarboxylase and incorporation of [3H]thymidine into DNA of guinea pig lymphocytes. Combined treatment of cells with A23187 and dibutyryladenosine 3',5'-monophosphate (Bt2cAMP) augmented these three events. A23187 at a concentration of 0.06 microgram/ml was insufficient for induction of ornithine decarboxylase stimulated neither Ca2+ influx nor [3H]thymidine incorporation, but stimulated Ca2+ efflux. A23187 (0.06 microgram/ml) in combination with Bt2cAMP caused a marked induction of ornithine decarboxylase and stimulation of [3H]thymidine incorporation into DNA. When the time of Bt2cAMP addition was delayed after A23187, the stimulation of ornithine decarboxylase activity decreased. Washout of Bt2cAMP from cell culture earlier than 4 h of incubation caused a reduction in the stimulatory effect of Bt2cAMP. These results suggest that raising concentrations of cytoplasmic Ca2+ and cellular cAMP are important to some initial events leading to induction of ornithine decarboxylase and these biochemical changes are obligatory sequential steps for stimulation of DNA synthesis.     

Transepidermal water loss: the signal for recovery of barrier structure and function

Previous studies have demonstrated that perturbations in barrier function stimulate epidermal lipid synthesis and that this increase can be prevented by occlusive membranes. These observations suggest that epidermal lipid synthesis might be related to barrier function and raised the question whether transcutaneous water flux might regulate epidermal lipogenesis. In the present study we first abrogated the barrier with acetone, and then compared the rate of repletion of stainable lipids, barrier recovery, and epidermal lipogenesis in animals covered with occlusive membranes or vapor-permeable membranes versus uncovered animals. Acetone treatment of hairless mice removed stainable neutral lipids from the stratum corneum, with repletion evident both biochemically and histochemically within 48 hr in uncovered animals. In contrast, when the animals were covered with an occlusive membrane, the usual return of stratum corneum lipids was aborted. Since application of vapor-permeable membranes allowed normal lipid repletion, occlusion alone is not responsible for the inhibition of lipid repletion. Acetone treatment also perturbed epidermal barrier function, which returned to normal in uncovered animals in parallel with the reappearance of stratum corneum lipid. However, when animals were covered with an occlusive membrane, barrier function did not recover normally. In contrast, occlusion with vapor-permeable membranes allowed barrier function to recover normally. Finally, whereas occlusive membranes prevented the characteristic increase in epidermal lipid synthesis that follows barrier perturbation, epidermal lipid synthesis was increased in animals covered with a vapor-permeable membrane. These results point to transepidermal water flux itself as the signal that regulates epidermal lipid synthesis, which is associated first with the redeposition of stratum corneum lipids and then the normalization of stratum corneum barrier function.     

DNA synthesis in cultured human fibroblasts: Regulation by 3′ : 5′-cyclic amp

The addition of serum to density-inhibited human fibroblast cultures induced a wave of DNA synthesis, measured as [³H] thymidine incorporation into acid-precipitable material, beginning after 8–12 hr and reaching maximum levels at 16–24 hr. Addition of dibutyryl-3′ : 5′-cyclic AMP (DBcAMP) together with serum inhibited [³H] thymidine incorporation by 75–95%. When DBcAMP was added for the first 4 hr of serum stimulation and then removed, the wave of DNA synthesis was not delayed. This suggested that serum could induce DNA synthesis even though cyclic AMP concentrations were maintained at high levels by DBcAMP during this initial period. These results are inconsistent with the hypothesis that it is the immediate transient reduction in 3′ : 5′-cyclic AMP concentration following the addition of serum that triggers DNA synthesis. By contrast, DBcAMP added 8 hr after serum inhibited [³H] thymidine incorporation to the same extent as DBcAMP added at the same time as serum. This indicated that a step essential for DNA synthesis and occurring late in G₁ was inhibited by high concentrations of 3′ : 5′-cyclic AMP.