Effects of an arginine-glycine-aspartic acid peptide-containing artificial matrix on epithelial migration in vitro and experimental second-degree burn wound healing in vivo.

Cells central to dermal tissue repair such as dermal fibroblasts and keratinocytes interact with arginine-glycine-aspartic acid (RGD)-containing proteins of the extracellular matrix such as fibronectin. It has been shown that synthetic peptides containing this RGD sequence can also support cell attachment and migration in vitro. We therefore set out to test whether the use of these peptides, when formulated as a synthetic RGD-peptide matrix consisting of peptide complexed with hyaluronic acid, would have an effect on the rate of epithelial migration and healing of experimental wounds. Evaluation consisted of measuring he extent of epithelial outgrowth from human dermal explants and the epithelization of experimental second-degree burn wounds in pigs. We show here that the RGD-peptide matrix supports epithelial sheet migration from explants in a dose-dependent manner. In second-degree burn wounds in pigs, wounds treated with daily applications of the RGD-peptide matrix under occlusion resurfaced at a significantly faster rate (day 7 = 57% completely epithelized) than wounds treated with hyaluronic acid under occlusion (day 7 = 13% completely epithelized, p < 0.01), occlusion alone (day 7 = 13% completely epithelized, p < 0.01), or air exposed (day 7 = 0% completely epithelized, p < 0.001). Histologic examination showed that wounds treated with the RGD-peptide matrix also had thicker epithelial covering and greater granulation tissue deposition than occluded, air-exposed, and hyaluronate-treated wounds. These data therefore show that the use of RGD-peptide matrix induces faster explant epithelial migration and results in faster healing of experimental second-degree burns.

Proliferation and differentiation of prepubertal mouse vaginal epithelial cells in vitro and the specificity of estrogen-induced growth retardation.

Mouse vaginal epithelial cells were isolated from intact 21-day-old BALB/cCrgl mice and cultured in a serum-free medium (SF20: basal medium supplemented with insulin, epidermal growth factor, transferrin, and bovine serum albumin--fraction V) to examine the proliferation, differentiation, and specificity of estrogen-induced growth retardation in vitro. Histologic and ultrastructural studies showed that vaginal epithelial cells undergo differentiative changes in vitro in the absence of estrogen, and that these changes are similar to those induced in vivo by estrogen. Addition of 17 beta-estradiol inhibited cellular proliferation in a dose-dependent manner. Whereas other estrane derivatives (17 alpha-estradiol and estriol) also significantly retarded cellular proliferation, cholesterol, testosterone, and progesterone had no effect. Keoxifene, an antiestrogen, significantly reversed estrogen-induced growth inhibition, resulting in proliferation of estrogen-treated cells equivalent to that of the untreated control. The results suggest that both proliferation and differentiation of prepubertal mouse vaginal epithelial cells in vitro are estrogen-independent, and that the growth inhibition is a specific estrogen-induced response.

Growth of mouse endometrial luminal epithelial cells in vitro: functional integrity of the oestrogen receptor system and failure of oestrogen to induce proliferation.

Normal endometrial luminal epithelial cells isolated from ovariectomized approximately 40-day-old BALB/cCrgl mice were purified by Percoll density gradient centrifugation and grown as primary cultures in collagen gel matrix and serum-free medium. Cells increased threefold in number during the 9-day culture period. Deletion of insulin, epidermal growth factor or bovine serum albumin resulted in decreased growth. Addition of any single factor to the unsupplemented medium had no effect. Relatively high levels of cytosolic oestrogen receptors and progestin receptors were demonstrable in the cultures. Addition of oestrogen did not enhance epithelial cell proliferation. On the contrary, all doses of oestrogen (180 fmol/l to 218 nmol/l) were inhibitory. Continuous exposure to oestradiol-17 beta (1.8 nmol/l) for 9 days in serum-free medium resulted in a decrease in cytosolic oestrogen receptors with an associated nuclear accumulation of oestrogen receptors. A corresponding increase in cytosolic progestin receptors was also observed, indicating that no qualitative modification of the oestrogen receptor system had occurred. Thus, as previously reported for vaginal epithelial cells, oestrogen, despite its stimulation of specific product synthesis (progestin receptors), did not increase proliferation of endometrial luminal epithelial cells in this culture system.

Effects of early exposure to diethylstilbestrol on cellular protein expression by mouse vaginal epithelium and fibromuscular wall.

Epithelia and fibromuscular walls were dissociated from the vaginae of ovariectomized BALB/cCrgl mice (ca. 41 days old) exposed neonatally to diethylstilbestrol (DES) or sesame oil and purified by centrifugation through Percoll density gradients. Neonatal exposure to DES caused the vaginal epithelium to become permanently proliferated and partially keratinized; the control epithelium was low cuboidal. The major cellular proteins expressed in each tissue compartment were examined by two-dimensional gel electrophoresis of [35S]methionine-labeled tissues. The epithelia and fibromuscular walls displayed distinctive two-dimensional protein patterns. In the DES-exposed vaginal epithelium, the expression of two proteins (one had a molecular size of 65 kDa and a pl of 6.0, and the other had a molecular size of 38 kDa and a pl of 6.3) was increased, while the expression of three proteins with molecular sizes of 25, 30, and 140 kDa and pls of 5.6, 5.6 and 6.7, respectively, was reduced, relative to the control epithelium. In the DES-exposed vaginal fibromuscular walls, the expression of 9 proteins was increased whereas the levels of 21 specific proteins, distinct from those in the epithelium, were decreased. Thus, long-term tissue-specific alterations in the synthesis of a select number of cellular proteins occur in the DES-exposed vagina.

Permanent chondrification in the pelvis and occurrence of hernias in mice treated neonatally with tamoxifen.

Male and female C57BL/Tw mice were given 5 daily subcutaneous injections of 100 micrograms tamoxifen (Tx), starting on the day of birth (Tx mice). In untreated fetal mice on day 18 of gestation, the greater part of the pubic and ischial bones were cartilaginous. At more than 30 days of age, however, untreated mice showed completely calcified pelvic bone, whereas in age-matched Tx mice the greater part of the junctional regions in the pelvis remained cartilaginous. Treatment with Tx starting within 5 days of age caused bladder hernia with or without cecum hernia. The pubic ligament in Tx mice at ages of 30-540 days was markedly expanded as compared with that in age-matched controls. The permanent chondrification in the pelvis was found in all mice given Tx starting within 10 days of age. By contrast, neonatal treatments of mice with other antiestrogens, clomiphene and nafoxidine (100 micrograms/day), induced neither permanent chondrification in the pelvis nor expansion of the pubic ligament nor hernia. These findings suggest that Tx has a specific effect on the symphysis pubis and some junctional regions of the developing pelvis in mice when given neonatally.

Growth of mouse vaginal epithelial cells in culture: effect of sera and supplemented serum-free media.

Normal mouse vaginal epithelial cells isolated from ovariectomized ca. 35-d-old BALB/cCrgl mice were grown in primary culture using collagen gel matrix and a serum-free medium composed of a 1:1 mixture of Dulbecco's modified Eagle's medium and Ham's F12 (D:H) medium supplemented with insulin (IN), epidermal growth factor (EGF), cholera toxin, transferrin, and bovine serum albumin V (BSA). Three-dimensional cellular outgrowths occurred inside the collagen gel matrix. The contribution of each factor to cell growth was examined by individual addition to the basic D:H medium and by individual deletion from the complete serum-free medium. When added individually, only IN promoted growth. Deletion of IN from the complete serum-free medium markedly diminished growth; deletion of EGF or BSA slightly diminished growth. When horse, fetal bovine, or chicken serum was added to the basal D:H medium, only with increasing doses of horse serum was there enhanced cell growth. The effect of 17 beta-estradiol and diethylstilbestrol on the growth of cells was also tested, using a suboptimal medium of D:H supplemented with BSA and IN, or a minimal medium supplemented with IN alone. During the 8-d time period, addition of estrogen did not enhance cell growth in either medium. To date, we have been unable to demonstrate a mitogenic effect of estrogen; rather a dose-dependent inhibition of proliferation is seen.

Growth of mouse vaginal epithelial cells in culture: functional integrity of the estrogen receptor system and failure of estrogen to induce proliferation.

Normal mouse vaginal epithelial cells isolated from ovariectomized ca. 40-day-old BALB/cCrg1 mice were purified by Percoll density gradient centrifugation and grown in primary culture using a collagen gel matrix and a serum-free complete medium. During the 9-day culture period, a 6-fold increase in cell number was observed. Addition of estrogen to the medium did not enhance epithelial cell proliferation. In fact, all doses of estrogen (180 fM to 18 nM) were inhibitory, resulting in only a 3- to 4-fold increase in cell number by day 9 of culture. Continuous exposure to estradiol (1.8 nM) for 9 days in the serum-free complete medium resulted in a decrease in cytosolic estrogen receptors with associated nuclear accumulation of estrogen receptors. A corresponding increase of cytosolic progestin receptors was also observed, indicating that no qualitative modification of the estrogen receptor system had occurred. Thus, despite its effectiveness in specific product synthesis (progestin receptors), estrogen does not stimulate proliferation of vaginal cells in this culture system, but rather inhibits epithelial cell proliferation.

Restoration of normal morphology and estrogen responsiveness in cultured vaginal and uterine epithelia transplanted with stroma.

We have investigated the capacity of vaginal and uterine epithelia (VE and UE) to reexpress normal morphology and hormone responsiveness following cell culture. VE and UE from adult ovariectomized mice were grown in a collagen gel matrix with serum-free medium for 7-10 days. Proliferation of these cells occurs in the absence of 17 beta-estradiol and is not stimulated by 17 beta-estradiol; the VE usually does not keratinize or stratify in vitro. Cultured VE and UE were recombined with homologous vaginal or uterine stroma (VS and US, respectively) and these recombinants were grown under the renal capsule of female hosts for 4 weeks. The epithelium of the VS + VE recombinants cycled, proliferated and stratified in response to estrogen and mucified normally in response to progesterone. The UE that was grown in vivo with cultured US also showed normal morphology and estrogen responsiveness. These changes in the UE and VE were not simply a result of return to the in vivo environment, as epithelia alone in collagen gels transplanted under the renal capsule did not survive. These results indicate that both VE and UE, which are not estrogen-dependent in vitro, reexpress their estrogen dependency and normal morphology when recombined with homologous stroma and grown in vivo. Thus, the changes these cells show when grown in culture are the result of altered conditions in vitro rather than an irreversible alteration in the cells themselves or the selection of specific subpopulations that are not mitogenically or morphologically responsive to estrogen under any condition.

Estrogen and progestin receptors in mouse vaginal epithelium and fibromuscular wall.

Both sodium molybdate and Percoll density gradient stabilize the hormone-binding capacities of the estrogen and progestin receptors and individually increase the recovery of these receptors in prepared cytosols of the separated mouse vaginal epithelium and fibromuscular wall. Their effects are additive. The concentrations of estrogen receptors are similar in the epithelial and fibromuscular compartments, whereas progestin receptor concentrations are higher in the epithelium.

Growth of normal mouse vaginal epithelial cells in and on collagen gels.

Sustained growth in primary culture of vaginal epithelial cells from ovariectomized adult BALB/cCrgl mice embedded within or seeded on collagen gel matrix was achieved in a serum-free medium composed of Ham's F-12 medium/Dulbecco's modified Eagle's medium, 1:1 (vol/vol), supplemented with insulin, bovine serum albumin fraction V, epidermal growth factor, cholera toxin, and transferrin. Three-dimensional growth of vaginal epithelial cells occurred inside the collagen gel matrix. Cell numbers increased 4- to 8-fold in collagen gel and about 4-fold on collagen gel after 9-10 days in culture. The effect of 17 beta-estradiol (0.00018-180 nM in gel or 0.018-180 nM on gel) and diethylstilbestrol (DES; 0.0186-186 nM in gel) on the growth of vaginal epithelial cells was examined. The addition of estrogen did not enhance the growth of vaginal epithelial cells during this time period either in the complete medium or in a suboptimal medium. Cultures on floating collagen gels in the serum-free medium are composed of 1-3 cell layers with superficial cornification. Estrogen does not appear to be a direct mitogen for vaginal epithelial cells, at least in this system.

Exceptional characteristics of amino proton exchange in guanosine compounds.

Amino 1H NMR line width as a measure of amino proton exchange in guanosine compounds is completely unaffected by the addition of ca. 1 M tris(hydroxymethyl)-aminomethane, imidazole, 2-(N-morpholino)ethanesulfonic acid, glycine, or cacodylate, all shown to be effective buffer catalysts in adenosine and cytidine proton exchange. Line broadening, seen only with phosphate and acetate, is established by intermolecular interactions, as well as by amino to water proton exchange. This absence of buffer catalysis of exchange is accounted for by the relatively small implied effect of G(N-7) protonation on amino acidity, based on similar observations with 7-methylguanosine as a model for endocyclic protonation. The requirement for diffusion-controlled proton transfer in buffer catalysis is achieved by nucleobase protonation in adenine and cytosine, but not in guanine.