OBJECTIVETo explore the relationship between epidermal stem cells and the developing process of sweat gland in human fetal skin, so as to obtain a hint for future induction of epidermal stem cells to differentiate into sweat gland cells.

METHODSTotal layer of human skin from the back of fetus at gestational ages from 11 to 31 weeks, obtained from spontaneous abortion was routinely examined. The expressions of beta1 integrin and keratin 19 in sweat gland cords or buds and mature sweat gland cells were dynamically observed with SP immunohistochemical technique. The development and maturation of sweat gland were identified by the positive staining of keratin 8 with immunohistochemistry.

RESULTSIt was revealed by histologic observation that basal layer cells of the primary epidermal ridge exhibited focal aggregation and formed hillocks at 16 gestational weeks. The hillocks of cells then migrated downward as cords into the dermis during 18 - 20 gestational weeks. Then, the end part of the cell cord developed into a round lump of twining cords assuming the mature sweat gland. The expressions of beta1 integrin and keratin 19 were found not only in sweat gland cords and buds but also in the mature cells and lasted throughout the total period of sweat gland development. The expression of keratin 8 in sweat gland buds started since 14 - 16 gestational weeks and maintained thereafter.

CONCLUSIONThe sweat gland started to develop during 14 - 16 gestational weeks and matured at 24 weeks. During the development process of sweat gland, epidermal stem cells were considered to be the key source.

Aborted Fetus ; Epidermis ; chemistry ; cytology ; embryology ; Humans ; Immunohistochemistry ; Integrin beta1 ; analysis ; Keratin-8 ; Keratins ; analysis ; Skin ; chemistry ; embryology ; Stem Cells ; chemistry ; cytology ; Sweat Glands ; chemistry ; embryology

One of the differences between fetal and adult skin healing is the ability of fetal wounds heal without contraction and scar formation. Extracellular matrix (ECM) provides a substratum for cells adhesion, migration, and proliferation and can directly influence the form and function of cells. As motility is essential for many important biological events, including wound healing, inflammatory response, embryonic development, and tumor metastasis, this study was designed to compare the motilities cultured dermal fetal and neonatal fibroblasts in the extracellular matrix. The motility of cultured fetal and neonatal fibroblasts was compared using a video-microscopy system that was developed in combination with a self-designed CO2 mini-incubator. To determine migration speed, cells were viewed with a 4X phase-contrast lens and video recorded. Images were captured using a color CCD camera and saved in 8-bit full-color mode. We found that cultured fetal fibroblasts move faster than neonatal fibroblast on type I collagen (fetal fibroblast, 15.1 micrometer/hr; neonatal fibroblast, 13.7 micrometer/hr), and in fibronectin (fetal fibroblast, 13.2 micrometer/hr; neonatal fibroblast, 13.0 micrometer/hr) and hyaluronic acid (fetal fibroblast, 11 micrometer/hr; neonatal fibroblast, 9.8 micrometer/hr).
Cell Movement ; Cells, Cultured ; Comparative Study ; Extracellular Matrix/*physiology ; Fetus/physiology ; Fibroblasts/*physiology ; Human ; Infant, Newborn ; Skin/cytology/*embryology ; *Skin Physiology

Merkel cells are thought to function as slowly adapting mechanoreceptors and are known as targets for sensory nerves. However, the nerve-dependency of Merkel cells remains controversial. In this respect, some investigators have found interregional differences between hairy and glabrous skin and others have shown intraregional differences within denervated rat touch domes. Differences between species have also been reported. This study was performed to determine whether Merkel cells proliferate in vitro in the absence of the systemic factors, blood vessels and the intact nerves in human skin. Suspension organ culture was performed using fetal digits to investigate their in vitro proliferation. Merkel cells and cutaneous nerves were identified using antibodies to cytokeratin 20 and protein gene product 9.5 (PGP 9.5), respectively. Fetal digits of 56-82 day gestational age were cultured in serum free medium in a high O2 (45%) environment. Tissues were harvested before starting culture (D0) and 1,4,7,14, 28d after culture. Merkel cells were observed in the volar pads and dorsal nail matrices at D0. After 28d of suspension organ culture, digits looked healthy structurally and the number of Merkel cells had increased. However, PGP 9.5-immunoreactive nerves were markedly diminished after 1 day of culture and almost disappeared after 4 days. Merkel cell proliferation in vitro suggested that Merkel cell development is probably nerve-independent in human fetal glabrous skin.
Cell Division ; Female ; Human ; Intermediate Filament Proteins/analysis ; Merkel Cells/*physiology ; Organ Culture ; Pregnancy ; Skin/cytology/*embryology/*innervation ; Thiolester Hydrolases/analysis

OBJECTIVETo investigate the effect of embryonic dermal signal on the hair-inductive capacity of neonatal mice dermal cells which have been amplified in vitro.

METHODSEmbryonic mice dermal cells of embryonic day 14 were added to a chamber on the back of nude mice with neonatal mice dermal cells which had been amplified in vitro for 3 days and freshly isolated neonatal mice epidermal cells. The hair regeneration was compared between the groups with or without embryonic mice dermal cells. Meanwhile, chambers with following cells respectively were constructed as controls: embryonic mice dermal cells + neonatal mice epidermal cells; freshly isolated neonatal mice dermal cells + neonatal mice epidermal cells; amplified neonatal mice dermal cells only; embryonic mice dermal cells only; freshly isolated neonatal mice dermal cells only; neonatal mice epidermal cells only.

RESULTSThe number of regenerated hairs with the aid of embryonic mice dermal cells (207 +/- 15. 948) was significantly higher than that (67 +/- 8.963) in the group without embryonic mice dermal cells (n = 3, t = 7.653, P = 0.002).

CONCLUSIONEmbryonic dermal signal can enhance the hair-inductive capacity of neonatal mice dermal cells which have been amplified in vitro.

Animals ; Cell Transplantation ; methods ; Cells, Cultured ; Hair ; physiology ; Hair Follicle ; surgery ; Mice ; Mice, Nude ; Reconstructive Surgical Procedures ; Regeneration ; Skin ; cytology ; embryology

OBJECTIVETo observe the expression of lefty in adult normal skin (ANS), human embryonic skin (HES) and hyperplastic scar (HS), and to explore the effect of lefty on HS and the relationship between lefty and scarless wound healing in embryo.

METHODSSamples of ANS, HES and HS were collected for frozen section for immunofluorescence staining. The morphology of fibroblast and the expression of the lefty were observed by laser confocal microscopy, and the positive cell rates were calculated.

RESULTSFibroblasts in ANS and HS were long and fusiform with regularity, their nuclei were fusiform or stellate and irregular. Fibroblasts in HES were fusiform, while nuclei were elliptic or fusiform and regular. Positive cell rates of lefty protein in HS (15.38%) were lower than that in NS (67.92%) and FS (81.67%, P < 0.01), and it was lower in ANS compared with HES (P <0.05).

CONCLUSIONLefty protein may inhibit the formation of scar, its high expression may be related to the embryo scarless wound healing.

Adult ; Cicatrix, Hypertrophic ; metabolism ; Female ; Fibroblasts ; cytology ; metabolism ; Humans ; Left-Right Determination Factors ; metabolism ; Male ; Middle Aged ; Skin ; embryology ; metabolism ; Wound Healing

For parthenogenetic activation as a model system of nuclear transfer, microinjection and electroporation as activation treatments in bovine metaphase II oocytes were administered to each of three groups as follows: control group (treatments with Ca2+, Mg2+ -free PBS+100 micro M EGTA), IP3 group (control+25 micro M IP3) and IP3+ ryanodine group (control+25 micro M IP3+10 mM ryanodine). In experiments using microinjection, no significant differences were observed between any of the developmental stages of the electroporation experiment. For electroporation, cleavage rates were significantly higher in the IP3+ryanodine group than in the IP3 or control group (85.6% vs 73.7% or 67.6%, respectively). In the subsequent stages of embryonic development, such as morula and blastocyst formation, the IP3 and ryanodine group exhibited significantly higher rates of morula fomation than the IP3 or control groups (40.6% vs 24.2% or 16.7%, respectively). Similarly, the rate of blastocyst formation in the IP3+ryanodine group was significantly higher than the control group (16.3% vs 6.9%) but did not differ significantly from the IP3 group (16.3% vs 9.5%). In nuclear transfer, activation was performed at 30 hpm by microinjection and elecroporation with 25 micro M IP3+ 10 mM ryanodine followed by 6-DMAP treatment. No significant differences were observed at any stage of embryonic development and none of the embryos activated by electroporation reached either the morula or blastocyst stage. However, 3.8% and 1.9% of embryos activated by microinjection sucessfully developed to the morula and blastocyst stages, respectively. In conclusion, activation treatments using IP3 and ryanodine are able to support the development of bovine parthenogenetic and reconstructed embryos.
Adenine/administration & dosage/*analogs & derivatives/pharmacology ; Animals ; Cattle/*embryology/physiology ; Cell Fusion ; Electroporation/veterinary ; Embryonic and Fetal Development/*drug effects ; Enzyme Inhibitors/administration & dosage/pharmacology ; Female ; Inositol 1,4,5-Trisphosphate/administration & dosage/*pharmacology ; Microinjections/veterinary ; Nuclear Transfer Techniques ; Oocytes/drug effects/growth & development ; Parthenogenesis/*drug effects ; Protein Kinase Inhibitors ; Ryanodine/administration & dosage/*pharmacology ; Skin/cytology