Method for Human Eccrine Sweat Gland Isolation from the Scalp by Means of the Micropunch Technique and Vital Dyes.

The isolation of eccrine sweat glands from human skin has always been a difficult task. The human scalp contains thousands of eccrine glands. Recently, the close anatomic relationship of the eccrine gland with the scalp hair follicle has been described. Taking advantage of this anatomic relationship as well as of the availability of follicular units (FUs) obtained in hair transplant procedures, we describe here a simple and efficient method to isolate eccrine sweat glands from the human scalp. This method is identical to the micropunch hair graft harvesting method known as follicular unit excision (FUE), used in modern hair transplantation. Once the FU has been extracted, it needs to be stained with methylene blue or neutral red in order to make the sweat gland visible for stereoscopic microdissection. Only the secretory (coiled) portion of the sweat gland can be obtained with this method. The efficiency of this isolation method should encourage further research into human eccrine sweat glands and opens possibilities for new translational applications.

EGFR inhibitor AG1478 blocks the formation of 3D structures mainly through ERK signaling pathway in Matrigel-induced 3D reconstruction of eccrine sweat gland-like structures.

EGFR signaling plays important roles in the development of eccrine sweat glands. We previously demonstrate that Matrigel induces eccrine sweat gland cells to reconstruct the three-dimensional (3D) structures of eccrine sweat glands, but the mechanisms are still unknown. In the study, eccrine sweat gland cells were cultured within a 3D Matrigel, and EGFR inhibitor AG1478, or MEK1/2 inhibitor U0126, were added to the medium respectively. The morphology of the 3D-reconstructed eccrine sweat gland-like structures was observed, the localization of phospho-EGFR was detected, and protein levels of EGFR, phospho-EGFR, phospho-JAK, phospho-AKT and phospho-ERK were examined. The results showed that cells treatment with AG1478 from Day 0 of 3D cultures blocked formation of spheroid-like structures. AG1478 administration caused reduced phospho-EGFR, concomitant with downregulation of phospho-ERK1/2, but not phospho-JAK or phospho-AKT. Phospho-EGFR and phospho-ERK were reduced, and only a small number of 3D-structures were formed following treatment with U0126. We conclude that EGFR plays important roles in Matrigel-induced 3D structures of eccrine sweat gland-like structures, and ERK1/2 signaling is responsible, at least in part, for the effect of EGFR.

K31 as a novel marker for clear secretory cells in human eccrine sweat glands.

K31 was previously considered as one of the hair keratins. During a study on differential markers between hair follicles and eccrine sweat glands, we observed that K31 was expressed in eccrine sweat gland cells in a scattered pattern, similar to the distribution of dark or clear secretory cells. To investigate the precise cell localization of K31 in human eccrine sweat glands and find new marker for eccrine sweat gland cells, human skin samples were fixed, paraffined and sectioned. The serial sections were stained for K31, dark secretory cell marker gross cystic disease fluid protein 15 (GCDFP15) and clear secretory cell marker carbonic anhydrase II (CAII). The exact cell localization of K31 was detected by double immunofluorescence staining of K31 and a serial of cell-specific markers, and further by dual stain using a combination of periodic acid-Schiff (PAS) and immunofluorescence for K31 and GCDFP15. The expression pattern of K31-positive cells was similar to that of CAII-positive cells but was different from that of GCDFP15-positive staining in serial sections. Double immunofluorescent staining showed that K31-positive cells co-expressed K7 and CAII, but not S100P, α-SMA or GCDFP15. Dual stain by combined PAS and immunofluorescence showed that K31-positive cells are negative for PAS staining. We conclude that K31 is a previously unreported eccrine clear cell marker that allows for distinction between clear and dark secretory cells, as well as between secretory coils and ducts of eccrine sweat glands in human eccrine sweat glands.

Differential antigen expression between human eccrine sweat glands and hair follicles/pilosebaceous units.

Eccrine sweat glands and hair follicles are two primary skin appendages that serve different functions. Although the two appendages exhibit unique morphological patterns in adults, it is difficult to distinguish them morphologically in the early stages of development and regeneration. To research and compare the development, differentiation and regeneration between eccrine sweat glands and hair follicles/pilosebaceous units, specific antigen markers must be found first. Human skin samples were fixed, paraffin-embedded, and cut. The expression of K5, K7, K8, K14, K27, K31, K73, AE13, α-smooth muscle actin (α-SMA), epithelial membrane antigen (EMA), carcinoembryonic antigen (CEA), Na+/K+-ATPase α and Na+-K+-2Cl cotransporter 1 (NKCC1) in eccrine sweat glands, hair follicles and sebaceous glands was detected by immunofluorescence staining. The results showed that eccrine sweat glands expressed K5, K7, K8, K14, K31, α-SMA, CEA, EMA, Na+/K+-ATPase α and NKCC1, but did not express K27, K73 or K31. Hair follicles expressed K5, K8, K14, K27, K31, K73, α-SMA and AE13, but did not express K7, CEA, Na+/K+-ATPase α or NKCC1. Sebaceous glands expressed K5, K14, K73, and EMA, but did not express K7, K8, K31, α-SMA, CEA, EMA, Na+/K+-ATPase α or NKCC1. We concluded that K7, CEA, Na+/K+-ATPase and NKCC1 can be used as specific markers for eccrine sweat glands, K27 and AE13 can be used as specific markers for hair follicles, and K73 can be used as a specific marker for pilosebaceous unit. These specific markers may contribute to differentiate between eccrine sweat glands and hair follicle/pilosebaceous units.

VEGFR-2 Is in a State of Activation in Hair Follicles, Sebaceous Glands, Eccrine Sweat Glands, and Epidermis from Human Scalp: An In Situ Immunohistochemistry Study of Phosphorylated VEGFR-2.

BACKGROUND Recent research reports that VEGFR-2 is expressed in the whole hair follicle, sebaceous glands, eccrine sweat glands, and epidermis. However, phosphorylated VEGFR-2 was not found, and it could not be ascertained whether the activated form of VEGFR-2 actually participates in the biological control of epidermal appendages. In this study we aimed to determine whether the VEGFR-2 pathway is directly involved in the daily regulation of epidermal appendages biology. MATERIAL AND METHODS In this study, we investigated the expression of phosphorylation of VEGFR-2 by immunohistochemical analysis in the epidermis and epidermal appendages in normal human scalp skin. RESULTS Immunohistochemical analysis revealed phosphorylation of VEGFR-2 in a whole hair follicle, mainly in the infundibulum basal layer, hair cortex, and medulla in the isthmus, and matrix in the hair bulb. Phosphorylated VEGFR-2 also was found in the sebaceous glands, eccrine sweat glands, and epidermis. CONCLUSIONS Therefore, we suggest that VEGFR-2 activation is involved in routine regulation of human epidermal appendages.

Time course of differentiation of different cell types in 3D-reconstructed eccrine sweat glands.

Epidermal basal cells invaginate into the dermis to form sweat ducts, which then grow downwards further to form secretory coils during the ontogenesis of eccrine sweat glands, but the time course of differentiation of different cell types in 3D-reconstructed eccrine sweat glands remain unclear. In this study, secretory cell-specific marker K7, clear secretory cell-specific marker CA II, dark secretory cell-specific marker GCDFP-15, myoepithelial cell-specific marker α-SMA, inner duct cell-specific marker S100P and outer duct cell-specific marker S100A2 were detected by immunofluorescence staining. The results showed that S100P and S100A2 were first detected at 2 weeks post implantation, K7 and α-SMA at 3 weeks, and GCDFP-15 and CA II at 4 weeks. The differentiation of ducts preceded secretory coils in 3D-reconstructed eccrine sweat glands. After 8 weeks post implantation, the distribution of these markers in 3D-reconstructed eccrine sweat glands was similar to that in native ones, and the percentage of the 3D-reconstructed glands expressing these markers maintained steady. We conclude that although the 3D-reconstructed and native eccrine sweat glands originated from different cells, the differentiation of different cell types in 3D-reconstructed eccrine sweat glands parallels the sequence observed during embryonic development.

Expression and localization of Forkhead transcription factor A1 in the three-dimensional reconstructed eccrine sweat glands.

Previously studies showed that Forkhead transcription factor A1 (FoxA1) was associated with sweat secretion. To investigate the expression and localization of FoxA1 in the three-dimensional (3D) reconstructed eccrine sweat glands, eccrine sweat gland cells were transplanted subcutaneously into nude mice with Matrigel, and at 2, 3, 4, 5, 6, 8, 10 and 12 weeks post-transplantation, the reconstructed eccrine sweat glands were removed and immunostained for FoxA1 and co-immunostained for FoxA1 and eccrine sweat markers, K7, carbonic anhydrase II (CA Ⅱ), gross cystic disease fluid protein-15 (GCDFP-15) and α-smooth muscle actin (α-SMA), and FoxA1 and sweat secretion-related proteins, Na+-K+-ATPase α and Na+-K+-2Cl- cotransporter 1 (NKCC1). The results showed that FoxA1-positive cells weren't detected until 3 weeks post-implantation, a time point of the differntiation of secretory coil-like structures. From the fourth week on, the number of FoxA1-positive cells increased and thereafter maintained at a high number. Double immunofluorescence staining showed that FoxA1-positive cells co-expressed dark cell marker GCDFP-15 and myoepithelial cell marker α-SMA, as well as secretion-related proteins, Na+-K+-ATPase α and NKCC1 in both the native and reconstructed eccrine sweat glands. In conclusion, FoxA1 might be related to the development and differentiation of secretory coil-like structures, as well as the secretory function of the 3D reconstructed eccrine sweat glands.

Three-dimensional reconstructed eccrine sweat glands with vascularization and cholinergic and adrenergic innervation.

Functional integrity of the regenerated tissues requires not only structural integrity but also vascularization and innervation. We previously demonstrated that the three-dimensional (3D) reconstructed eccrine sweat glands had similar structures as those of the native ones did, but whether the 3D reconstructed glands possessing vascularization and innervation was still unknown. In the study, Matrigel-embedded eccrine sweat gland cells were implanted under the inguinal skin. Ten weeks post-implantation, the vascularization, and innervation in the 10-week reconstructed eccrine sweat glands and native human eccrine sweat glands were detected by immunofluorescence staining. The results showed that the fluorescent signals of general neuronal marker protein gene product 9.5, adrenergic nerve fiber marker tyrosine hydroxylase, and cholinergic nerve fiber markers acetylcholinesterase and vasoactive intestinal peptide embraced the 3D reconstructed glands in circular patterns, as the signals appeared in native eccrine sweat glands. There were many CD31- and von Willebrand factor-positive vessels growing into the plugs. We demonstrated that the 3D reconstructed eccrine sweat glands were nourished by blood vessels, and we for the first time demonstrated that the engineering sweat glands were innervated by both cholinergic and adrenergic fibers. In conclusion, the 3D reconstructed eccrine sweat glands may have functions as the native ones do.

Cells in 3D-reconstitutued eccrine sweat gland cell spheroids differentiate into gross cystic disease fluid protein 15-expressing dark secretory cells and carbonic anhydrase II-expressing clear secretory cells.

Secretory coils of eccrine sweat glands are composed of myoepithelial cells, dark secretory cells and clear secretory cells. The two types of cells play important roles in sweat secretion. In our previous study, we demonstrated that the 3D-reconstituted eccrine sweat gland cell spheroids differentiate into secretory coil-like structures. However, whether the secretory coil-like structures further differentiate into dark secretory cells and clear secretory cells were is still unknown. In this study, we detected the differentiation of clear and dark secretory cells in the 3D-reconstituted eccrine sweat gland cell spheroids using the dark secretory cell-specific marker, GCDFP-15, and clear secretory cell-specific marker, CAII by immunofluorescence staining. Results showed that there were both GCDFP-15- and CAII-expressing cells in 12-week-old 3D spheroids, similar to native eccrine sweat glands, indicating that the spheroids possess a cellular structure capable of sweat secretion. We conclude that the 12-week 3D spheroids may have secretory capability.

Serum is an indispensable factor in the maintenance of the biological characteristics of sweat gland cells.

The tolerance of sweat gland cells for in vitro amplification and subcultivation is low as they are somatic cells. The present study aimed to formulate an optimal medium for the culture of human eccrine sweat gland cells (HESGCs) and to establish a method for induction of HESGCs proliferation, whilst maintaining the characteristics of sweat gland cells. HESGCs cultured in sweat gland (SG):keratinocyte growth medium­2 (KGM­2) (1:1) medium had a higher proliferation rate and a stable morphology compared with cells cultured in SG and KGM­2 medium only. Reverse transcription­quantitative polymerase chain reaction indicated that cells cultured in the SG:KGM­2 (1:1) medium exhibited higher expression levels of α­smooth muscle actin, keratin (K)77, carcinoembryonic antigen, K8, K18, ectodysplasin A receptor, c­Myc, Kruppel­like factor 4 and octamer­binding transcription factor 4 compared with cells cultured in SG only or KGM­2 only medium. Three­dimensional culture analysis revealed that HESGCs cultured in SG:KGM­2 1:1 medium differentiated into sweat gland­like structures, whereas cells cultured in KGM­2 only medium underwent cornification. The present study also determined that the maintenance of the biological characteristics of HESGCs occurred due to the presence of fetal bovine serum (FBS). Cells cultured in medium without FBS differentiated into keratinocytes. Therefore, the SG:KGM­2 (1:1) medium may be a suitable culture medium for HESGCs. In conclusion, this mixed medium is a valuable compound and should be considered to be a potential supplemental medium for HESGCs.

Cell proliferation and differentiation during the three dimensional reconstitution of eccrine sweat glands.

The aim of this study is to characterize the cell proliferation and proliferating cell types during three-dimensional reconstitution of eccrine sweat glands. Eccrine sweat gland cells suspended in Matrigel were injected subcutaneously into the inguinal regions of nude mice. At 1, 2, 4, 6, 8, 14, 21, 28, 35 and 42 days post-implantation, Matrigel plugs were immunostained for Ki67, to detect cycling cells, and the Ki67 labeling index at different time points was calculated. Three pairs of antibodies, Ki67/K7, Ki67/K14 and Ki67/α-SMA, were used to identify proliferating cell types in the plugs, on days 28, 35 and 42, by immunofluorescence double staining. The Ki67 labeling index on the first day of implantation was 30.53%, rapidly reached a peak value of 81.43% at 2 days post-implantation, and then decreased gradually to a low of 2.87% at 42 days. Double immunofluorescence staining showed that K14/Ki67 double-stained cells accounted for 80% of the Ki67-positive cells, whereas K7/Ki67 and α-SMA/Ki67 double-stained cells each accounted for 10% of the Ki67-positive population on days 28, 35, or 42 post-implantation. We conclude that eccrine sweat gland cells rapidly enter the cell cycle after implantation, but quickly show decreased cell proliferation and increased cell differentiation.

Stage-specific embryonic antigen-4 as a novel marker of ductal cells of human eccrine sweat glands.

BACKGROUND: Different populations of unipotent or multipotent stem cells have been identified in human epidermis and its appendages. It is well documented that these cells maintain tissue homeostasis and actively participate in epidermal regeneration after injury. However, there is no evidence of the presence of pluripotent stem cells in human epidermis. OBJECTIVES: In this study we investigated whether cells positive for embryonic stem cell marker stage-specific embryonic antigen-4 (SSEA-4) are present in adult human epidermis and, if so, whether they are pluripotent and correspond to the population of primitive stem cells. METHODS: The expressions of SSEA-4 and pluripotency transcription factors were analysed using flow cytometry. By means of immunohistochemical staining, we studied the exact localization of these cells in sections of human skin. RESULTS: We show that a population of SSEA-4+ cells is present in human epidermis. In contrast to the commonly accepted belief, the expression of SSEA-4 is not connected with the pluripotent character of isolated cells. We found that these SSEA-4+ cells are localized in the ducts of eccrine sweat glands. CONCLUSIONS: Our results indicate that SSEA-4 is a novel marker identifying the ductal cells of human sweat glands. The surface character of the antigen provides for a simple method of isolating this cell population and suggests applications of SSEA-4 for future cell therapy research.

Identification of a new sweat gland progenitor population in mice and the role of their niche in tissue development.

Sweat gland cells are responsible for the regulation of body temperature and are critical for wound repair. Furthermore, they have the regenerative potential in response to injury, and show a substantial turnover during both wound healing and homeostasis. However, as a usual research model of sweat gland, mice have not too much glandular cells for experiments. In this study, we identify previously unreported sweat gland progenitor population in mice and characterize them. The progenitor characteristics of sweat gland were confirmed using cellular immunofluorescence assay and quantitative real-time PCR assay. K8 and K18 expression was barely detected in the early stage of skin development (Embryo 17.5d) and increased to a high level at P5d (postnatal 5d), then showed reduction at adult stage (P28d). Further investigation of K8 and K18 positive cells using tissue immunofluorescence revealed the presence of sweat gland progenitors in back epidermis of mice at early stage of sweat gland development and continuous reduction during the developmental process. In vivo transplantation assay with animal models elucidated that sweat gland specific niche in paw pads was critical for the development of sweat gland cells. Although the relationship between new sweat gland progenitors and their niche still needs to be further investigated, the presence of these cells implicates that there is more source ascribed to sweat glands in addition to serving as progenitors in mice.

Human eccrine sweat gland cells reconstitute polarized spheroids when subcutaneously implanted with Matrigel in nude mice.

Increasing evidence indicates that maintenance of cell polarity plays a pivotal role in the regulation of glandular homeostasis and function. We examine the markers for polarity at different time points to investigate the formation of cell polarity during 3D reconstitution of eccrine sweat glands. Mixtures of eccrine sweat gland cells and Matrigel were injected subcutaneously into the inguinal regions of nude mice. At 2, 3, 4, 5 and 6 weeks post-implantation, Matrigel plugs were removed and immunostained for basal collagen IV, lateral ß-catenin, lateroapical ZO-1 and apical F-actin. The results showed that the cell polarity of the spheroids appeared in sequence. Formation of basal polarity was prior to lateral, apical and lateroapical polarity. Collagen IV was detected basally at 2 weeks, ß-catenin laterally and ZO-1 lateroapically at 3 weeks, and F-actin apically at 4 weeks post-implantation. At week 5 and week 6, the localization and the positive percentage of collagen IV, ß-catenin, ZO-1 or F-actin in spheroids was similar to that in native eccrine sweat glands. We conclude that the reconstituted 3D eccrine sweat glands are functional or potentially functional.

BrdU-label-retaining cells in rat eccrine sweat glands over time.

Cell proliferation and turnover are fueled by stem cells. In a previous study, we demonstrated that rat eccrine sweat glands contained abundant bromodeoxyuridine (BrdU)-label-retaining cells (LRCs). However, morphological observations showed that eccrine sweat glands usually show little or no signs of homeostatic change. In this study, we account for why the homeostatic change is rare in eccrine sweat glands based on cytokinetic changes in BrdU-LRC turnover, and also determine the BrdU-labeled cell type. Thirty-six newborn SD rats, were injected intraperitoneally with 50mg/kg BrdU twice daily at a 2h interval for 4 consecutive days. After a chase period of 4, 6, 8, 12, 24 and 32 weeks, rats were euthanized, and the hind footpads were removed and processed for BrdU immunostaining, and BrdU/α-SMA and BrdU/K14 double-immunostaining. BrdU-LRCs were observed in the ducts, secretory coils and mesenchymal cells at all survival time points. The percentage of BrdU(+) cells in rat eccrine sweat glands averaged 4.2±1.2% after 4 weeks of chase, increased slightly by the 6th week, averaging 4.4±0.9%, and peaked at 8 weeks, averaging 5.3±1.0%. Subsequently, the average percentage of BrdU(+) cells declined to 3.2±0.8% by the 32nd week. There was no difference in the percentage of BrdU-LRCs among the different survival time points except that a significant difference in the percentage of BrdU-LRCs detected at 24 weeks versus 8 weeks, and 32 weeks versus 8 weeks, was observed. We concluded that the BrdU-LRCs turnover is slow in eccrine sweat glands.

Autofluorescence of eccrine sweat glands.

BACKGROUND/PURPOSE: The monitoring of autofluorescence in skin tissue samples can have diagnostic and therapy significance. In this study, we are the first to describe autofluorescence of eccrine sweat glands, which is important and helpful for the diagnosis and therapy of diseases that involve the eccrine sweat glands. METHODS: Eccrine sweat gland autofluorescence in haematoxylin-eosin (HE) stained skin tissue sections was observed under a fluorescence microscope, which was compared to the immunofluorescence of keratin 19 and 15 in the skin tissue sections. The single eccrine sweat glands from five volunteers including three males and two females were isolated and also observed under a fluorescence microscope. The autofluorescence intensity of the single eccrine sweat gland was measured using a laser confocal scanning microscope system. RESULTS: Eccrine sweat gland autofluorescence in HE stained skin tissue sections appears green under GFP fliter system (470/40 nm) and red under N2.1 fliter system (515-560 nm). Furthermore, the single eccrine sweat gland showed various autofluorescence colours, including green under wide blue and red under wide green. The autofluorescence intensity of the single eccrine sweat gland was measured. The spectrum excited at 488 nm exhibited two peaks located at approximately 530 nm (11.54 ± 4.66) and 590 nm (10.38 ± 4.33). The results suggest flavin and lipopigment as the endogenous fluorophores. CONCLUSION: The autofluorescence of the HE stained eccrine sweat gland sections is simple and helpful for easily determining the structure of eccrine sweat glands. The autofluorescence of the single eccrine sweat gland may be due to the existence of flavin and lipopigment.

Skin-Derived C-Terminal Filaggrin-2 Fragments Are Pseudomonas aeruginosa-Directed Antimicrobials Targeting Bacterial Replication.

Soil- and waterborne bacteria such as Pseudomonas aeruginosa are constantly challenging body surfaces. Since infections of healthy skin are unexpectedly rare, we hypothesized that the outermost epidermis, the stratum corneum, and sweat glands directly control the growth of P. aeruginosa by surface-provided antimicrobials. Due to its high abundance in the upper epidermis and eccrine sweat glands, filaggrin-2 (FLG2), a water-insoluble 248 kDa S100 fused-type protein, might possess these innate effector functions. Indeed, recombinant FLG2 C-terminal protein fragments display potent antimicrobial activity against P. aeruginosa and other Pseudomonads. Moreover, upon cultivation on stratum corneum, P. aeruginosa release FLG2 C-terminus-containing FLG2 fragments from insoluble material, indicating liberation of antimicrobially active FLG2 fragments by the bacteria themselves. Analyses of the underlying antimicrobial mechanism reveal that FLG2 C-terminal fragments do not induce pore formation, as known for many other antimicrobial peptides, but membrane blebbing, suggesting an alternative mode of action. The association of the FLG2 fragment with the inner membrane of treated bacteria and its DNA-binding implicated an interference with the bacterial replication that was confirmed by in vitro and in vivo replication assays. Probably through in situ-activation by soil- and waterborne bacteria such as Pseudomonads, FLG2 interferes with the bacterial replication, terminates their growth on skin surface and thus may contributes to the skin's antimicrobial defense shield. The apparent absence of FLG2 at certain body surfaces, as in the lung or of burned skin, would explain their higher susceptibility towards Pseudomonas infections and make FLG2 C-terminal fragments and their derivatives candidates for new Pseudomonas-targeting antimicrobials.

[Optimization of primary human eccrine sweet glands' isolation in vitro].

OBJECTIVE: To optimize the methods of isolating human eccrine sweat gland cells in vitro so as to get efficiently primary human sweat glands. METHODS: The fresh and normal skin tissue was cut into pieces of microskin about 1mm3 and the following 3 group digestion buffer was applied to isolated gland cells. The digestion buffer of group A was the equivoluminal mixture of Trypsin-Ethylene Diamine Tetraacetic Acid (EDTA) and collagenase-II (2 mg/ml). The digestion buffer of group B was collagenase-II (2 mg/ml) traditionally and group C was Trypsin-EDTA. These three groups were placed into an incubator simultaneously and the emerging time of dissociated sweat glands was calculated. Sweat glands were sorted out and then placed in culture dish. The adherence and the growth of cells were observed. The proliferation index was detected by flow cytometry. The identification of cultured cells was performed by immunocytochemical staining. RESULTS: After digesting 30 min in group A and C, a very few of dissociated sweat glands were emerging. But after digesting for 2 h, there were lots of dissociated sweat glands emerging in group A rather than in group C. The emergence of dissociated sweat glands in group B would require at least 6 hours. After seeded in culture dishes, the sweat glands in group C couldn't adhere to the wall of dish, but the sweat glands in group A and B adhered very well and even grew like paving stones after 9 days. In addition, the proliferation index were (18 ± 4) % and (17 ± 6) % respectively, there was no statistical difference. The results of immunocytochemical staining showed that the cells expressed carcino-embryonic antigen (CEA) and cytokeratin 7(CK7) in group A and B. CONCLUSION: Trypsin-EDTA combined with collagenase-II can shorten the time of isolating sweat gland cells and have no effect on cell activity and proliferation.

Three-dimensional co-culture of BM-MSCs and eccrine sweat gland cells in Matrigel promotes transdifferentiation of BM-MSCs.

Victims with extensive and deep burns are unable to regenerate eccrine sweat glands. Combining of stem cells and biomimetic ECM to generate cell-based 3D tissues is showing promise for tissue repair and regeneration. We co-cultured BrdU-labeled bone marrow-derived mesenchymal stem cells (BM-MSCs) and eccrine sweat gland cells in Matrigel for 2 weeks in vitro and then evaluated for BM-MSCs differentiation into functional eccrine sweat gland cells by morphological assessment and immunohistochemical double staining for BrdU/pancytokeratin, BrdU/ZO-2, BrdU/E-cadherin, BrdU/desmoglein-2, BrdU/Na(+)-K(+)-ATPase α, BrdU/NHE1 and BrdU/CFTR. Cells formed spheroid-like structures in Matrigel, and BrdU-labeled BM-MSCs were involved in the 3D reconstitution of eccrine sweat gland tissues, and the incorporated BM-MSCs expressed an epithelial cell marker (pancytokeratin), epithelial cell junction proteins (ZO-2, E-cadherin and desmoglein-2) and functional proteins of eccrine sweat glands (Na(+)-K(+)-ATPase α, NHE1 and CFTR). In conclusion, three-dimensional co-culture of BM-MSCs and eccrine sweat gland cells in Matrigel promotes the transdifferentiation of BM-MSCs into potentially functional eccrine sweat gland cells.