The ultrastructure of monkey eccrine sweat glands

Summary The ultrastructure of monkey eccrine sweat glands is described. The secretory portion of the sweat gland is discussed in detail. The morphological differences in the secretory coil using three different fixatives and fixative combinations are emphasized. The secretory product of dark cells is seen to have three distinct appearances depending upon the fixative used. The biochemical significance of the latter finding is discussed. The appearance of clear cell cytoplasmic processes is described using the different fixatives. The similarity of adjacent clear cell processes to those of avian salt glands is pointed out and discussed. Evidence is presented to indicate that dark cells arise from clear cells via an intermediate cell type. The appearance of the clear cell plasma membrane is described and the necessity for the use of the general term multilaminar plasma membrane is discussed.Supported by U.S.P.H.S. grant 5 T 1-GM-29 F-04 AS. The author would like to express his gratitude to the Lederle Laboratories and in particular to Dr.James Vickers for providing the tissue. Sincere thanks is given to Mrs.Dagmar Graham and Mrs.Ditza Springer for technical assistance and also to MissMary Lorenc for preparation of the diagram. In addition, I would like to thank Dr.J. A. G. Rhodin for his criticism and advice.     

Lectin binding pattern and proteoglycan distribution in human eccrine sweat glands

The distribution pattern of glycoconjugates in human eccrine sweat glands has been studied by the binding of newly discovered lectins and by antibodies against a chondroitin sulphate proteoglycan and chondroitin sulphate glycosaminoglycans. Mannose-specific lectins labelled large intracellular granules, part of which could be extended cisternae of the endoplasmic reticulum or Golgi apparatus. In contrast, lectins specific for terminal mannose/glucose residues predominantly labelled basement membranes and the glycocalyx. Lectins recognizing terminal N-acetylgalactosamine groups left most parts of the glands unstained, but stained some dark cells intensely. These last cells were also intensively labelled by N-acetylglucosamine-specific and by fucose-specific lectins. Sialic acid residues were preferentially located in luminal borders of secretory coils. No terminal galactose residues were detected. All antibodies against chondroitin glycoconjugates stained large granules similar to those revealed by the mannose-specific lectins in the secretory cells. The basement membrane is only stained by the proteoglycan antibody and the chondroitin-6-sulphate antibody.Thus, a complex composition of glycoconjugates exists not only in matrix elements but also in the cells of eccrine glands of the human skin. A possible secretion of glycoconjugates is discussed.     

Catecholamine-containing nerve terminals of the eccrine sweat glands of macaques

Summary A loose network of catecholamine-containing nerves was demonstrated with a fluorescence histochemical method (Falck-Hillarp) in the coiled portion of eccrine sweat glands in the digital pads of macaques after the injection of nialamide and noradrenaline. In the skin of untreated control animals, fluorescent fibers appear only in some of the glands. A systemic administration of reserpine and a local injection of 6-hydroxydopamine (6-OHDA) or 5-hydroxydopamine (5-OHDA) into the digital pad cause a complete disappearance of fluorescent fibers around the glands and blood vessels. Electron micrographs reveal many unmyelinated varicose axon profiles outside the basement membrane of secretory tubules. Most of these profiles contain many small agranular vesicles and a few large dense-cored vesicles (cholinergic terminal), and some have numerous small granular and a few large densecored vesicles (adrenergic terminal).The local injection of 6-OHDA causes various degenerative changes in the adrenergic terminals but the cholinergic ones and the rest of the cellular structure remain intact. The injection of 5-OHDA induces a significant increase of electron-dense granules in the vesicles of adrenergic terminals.The presence of catecholamine and the effects of 6-OHDA and 5-OHDA in the nerve terminals indicate that the innervation of the eccrine sweat glands of macaques consists of cholinergic as well as adrenergic terminals.Publication No. 783 of the Oregon Regional Primate Research Center supported in part by Public Health Service, National Institutes of Health Grant RR 00163 of the Animal Resources Branch, Division of Research Resources.We acknowledge the excellent assistance of Tsutomu Yoshida, Tsuneka zu Fuse, John Ochsner, and Nickolas Roman.     

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.     

The metabolism and hormonal responses of human eccrine sweat glands isolated by collagenase digestion.

1. Collagenase digestion of biopsies of human skin yields eccrine sweat glands that can be picked out under binocular light microscopy. The glands are viable as determined by the exclusion of Trypan Blue, the uptake of Methylene Blue, electron microscopy, the rate of lactate dehydrogenase release, ATP content and the rates of glucose oxidation and lactate release. 2. It is proposed that eccrine sweat glands engage in aerobic glycolysis, which accounts for the high content of lactate in sweat (15--60 mM) and the high lactate/pyruvate ratio (100: 1) [Emrich & Zwiebel (1966) Pfluegers Arch. 290, 315--319]. 3. Acetylcholine causes a 4-fold increase in cyclic GMP content, dilatation of the intercellular canaliculi and a reversible, atropine-sensitive, 2-fold increase in the rates of glucose oxidation and lactate release. 4. Isoprenaline causes a 2.5-fold increase in cyclic AMP content. Phenylephrine does not significantly alter cyclic nucleotide metabolism.     

Three-dimensional culture and identification of human eccrine sweat glands in matrigel basement membrane matrix

Interactions between the extracellular matrix (ECM) and epithelial cells are necessary for the proper organization and function of the epithelium. In the present study, we show that human eccrine sweat gland epithelial cells cultured in matrigel, a representation of ECM components, constitute a good model for studying three-dimensional reconstruction, wound repair and regeneration and differentiation of the human eccrine sweat gland. In matrigel, epithelial cells from the human eccrine sweat gland form tubular-like structures and then the tubular-like structures coil into sphere-like shapes that structurally resemble human eccrine sweat glands in vivo. One sphere-like shape can be linked to another sphere-like shape or to a cell monolayer via tubular-like structures. Hematoxylin and eosin staining has revealed that the tubular-like structures have a single layer or stratified epithelial cells located peripherally and a lumen at the center, similar to the secretory part or duct part, respectively, of the eccrine sweat gland in sections of skin tissue. Immunohistochemical analysis of the cultures has demonstrated that the cells express CK7, CK19, epithelial membrane antigen and actin. Thus, matrigel promotes the organization and differentiation of epithelial cells from the human eccrine sweat gland into eccrine sweat gland tissues.     

Immunohistochemical localization of activated EGF receptor in human eccrine and apocrine sweat glands.

Epidermal growth factor (EGF) is secreted into sweat from secretory cells of human sweat glands. The function of EGF in sweat is poorly understood. The biological function of EGF is exerted by the binding of EGF to the receptor (EGFR) and its activation. Therefore, we immunohistochemically localized the activated form of EGFR in human eccrine and apocrine sweat glands to assess the functional importance of the EGF-EGFR system in human sweat glands. Frozen sections of human skin were stained with a monoclonal antibody (MAb) specific for tyrosine-phosphorylated (activated) EGFR and with an MAb that stains both activated and non-activated EGFR. In the secretory portion of eccrine sweat glands, nuclei of the secretory cells were stained with the anti-activated EGFR MAb. In coiled and straight portions of eccrine sweat ducts, nuclei of luminal and peripheral cells were stained with the antibody specific for activated EGFR. Luminal cell membranes and luminal cytoplasm of inner ductal cells possessed non-activated EGFR. In the secretory portion of apocrine sweat glands, activated EGFRs were present in cytoplasm and nuclei of secretory cells. These data suggest that EGF, already known to be present in the cytoplasm of secretory cells in eccrine and apocrine sweat glands, activates EGFR in the nuclei of secretory cells themselves in an intracrine manner. Because ductal cells do not express EGF, EGF in the sweat secreted from the secretory cells should activate EGFR in the ductal cells in a paracrine manner. (J Histochem Cytochem 49:597-601, 2001)     

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.     

Vacuolar-type H+ -ATPase distribution in unstimulated and acetylcholine-activated isolated human eccrine sweat glands

The presence and cellular distribution of subunits of the V₁ sector of the vacuolar-type H⁺-ATPase (V-ATPase) was investigated in isolated human eccrine sweat glands. In every instance, V-ATPase was located in the cytoplasm and apical membranes of the luminal cells of the reabsorptive duct segment. In the secretory coil, both diffuse and perinuclear staining was demonstrated in the secretory cells, with additional expression at the apical and basolateral membranes and on the intercellular canaliculi. There was no detectable difference in V-ATPase expression as a result of prior application of 100µM acetylcholine.     

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.