Epithelial origin of cutaneous anchoring fibrils.

Anchoring fibrils are essential structural elements of the dermoepidermal junction and are crucial to its functional integrity. They are composed largely of type VII collagen, but their cellular origin has not yet been confirmed. In this study, we demonstrate that the anchoring fibrils are primarily a product of epidermal keratinocytes. Human keratinocyte sheets were transplanted to a nondermal connective tissue graft bed in athymic mice. De novo anchoring fibril formation was studied ultrastructurally by immunogold techniques using an antiserum specific for human type VII procollagen. At 2 d after grafting, type VII procollagen/collagen was localized both intracellularly within basal keratinocytes and extracellularly beneath the discontinuous basal lamina. Within 6 d, a subconfluent basal lamina had developed, and newly formed anchoring fibrils and anchoring plaques subjacent to the xenografts were labeled. Throughout the observation period of the experiment, the maturity, population density, and architectural complexity of anchoring fibrils beneath the human epidermal graft continuously increased. Identical findings were obtained using xenografts cultivated from cloned human keratinocytes, eliminating the possibility of contributions to anchoring fibril regeneration from residual human fibroblasts. Immunolabeling was not observed at the mouse dermoepidermal junction at any time. These results demonstrate that the type VII collagen of human cutaneous anchoring fibrils and plaques is secreted by keratinocytes and can traverse the epidermal basal lamina and that the fibril formation can occur in the absence of cells of human dermal origin.

Subgroups of luteinizing hormone-releasing hormone perikarya defined by computer analyses in the basal forebrain of intact female rats.

The hypothesis that the basal forebrain population of LHRH perikarya is composed of heterogeneous subgroups was examined in this study. We used three-dimensional computerized reconstruction to examine populations of LHRH-immunopositive neurons detected in noncolchicine treated cycling female rats. Perikarya were detected with two antisera capable of detecting LHRH decapeptide within larger mol wt species, i.e. Millar's (RM) 1076 and Arimura's (AA) 419. No immunopositive perikarya were detected with antiserum AA 422, which requires the fully processed decapeptide for binding. A more broadly distributed population of LHRH neurons was detected in females killed on proestrus than in females killed on estrus or the other days of the cycle. These relationships were observed with both antisera, RM 1076 and AA 419. Subgroups of cells were clearly defined when the population of LHRH neurons detected on proestrus was simultaneously displayed with the population detected on estrus. Strikingly similar subgroups were revealed by simultaneous displays of populations of LHRH neurons detected by the antisera RM 1076 and AA 419 in proestrous females. This study revealed a three-dimensional onion skin-like laminar organization of LHRH subgroups expanding from the ventricle outward laterally and from the diagonal band of Broca to the hypothalamus caudally. We propose that these subgroups vary in their metabolic activity of biosynthesis, processing, transport, or release of LHRH in relation to the proestrous preovulatory release of LH.

Ultrastructural evidence suggests variations in biosynthesis and processing within LH-RH neurons as a function of ovariectomy in rats.

We have demonstrated that populations of luteinizing hormone-releasing hormone (LH-RH)-immunopositive neuronal perikarya change following gonadectomy of male and female rats in a sex-dependent manner related to rises in plasma luteinizing hormone (LH). In this study we characterize the ultrastructural state of organelles involved in protein synthesis, primarily within perikarya of rostral preoptic area LH-RH neurons surrounding the organum vasculosum of the lamina terminalis (OVLT). One day following ovariectomy little rough endoplasmic reticulum (RER) was evident, however, the cisternae were heavily laden with ribosomes and numerous polysomes were present free in the cytoplasm. Six days and 3 weeks post-ovariectomy the cisternae of RER were progressively more abundant and dilated; the multiple Golgi apparati, located in close proximity to the RER, were composed of many lamelae and extensive associated vesicles. We propose that increased pools of messenger ribonucleic acid (mRNA) are generated by 1 day post-ovariectomy prior to increased synthesis of precursor, 6 days and 3 weeks post-ovariectomy. Axodendritic synaptic profiles in the neuropil surrounding LH-RH perikarya increased in number in the rostral medial preoptic area and lateral anterior hypothalamic area. We conclude that removal of gonadal steroids results in greater biosynthetic activity in LH-RH neurons, and suggest that the enhanced biosynthesis is related to increases in afferent activity.

Human Merkel cell regeneration in skin derived from cultured keratinocyte grafts.

Human Merkel cell regeneration in epidermis derived from cultured keratinocyte autografts was studied from 6 days to 6 years after transplantation. Cultured keratinocyte sheets derived from skin of the sole, axilla, groin, or scalp were transplanted to full-thickness wounds in 20 pediatric patients treated for massive burns or giant congenital nevi. Normal age- and site-matched skin as well as meshed split-thickness autografts from the same patients served as controls. Merkel cells were identified by immunohistochemistry using antibodies to cytokeratins #8 and #18. Cultured keratinocytes in vitro expressed no neuroendocrine markers, but nonspecific, simple-epithelial cytokeratin expression was observed in about 20% of cells. After transplantation, Merkel cells were identified only in cultured grafts derived from sole skin and appeared in the epidermis as early as 21 days postgrafting. Dermal Merkel cells were rarely observed, but their appearance invariably succeeded that of intraepidermal Merkel cells. Regenerated Merkel cells were never innervated, and their emergence was unrelated either spatially or temporally to epidermal reinnervation. In skin bridges of meshed split-thickness grafts, Merkel cells survived after degeneration of associated neurites, but no Merkel cells appeared within re-epithelialized interstices. Among the neuroendocrine markers tested, Merkel cells in cultured grafts, meshed skin grafts or normal pediatric skin expressed only neuron-specific enolase. They failed to stain for calcitonin, chromogranin A, Leu-7, synaptophysin, bombesin, or vasoactive intestinal polypeptide by immunohistochemistry. These findings suggest that: (a) Merkel cells derive from keratinocyte precursors which undergo neuroendocrine differentiation in the epidermis; (b) that keratinocyte stem cells are capable of undergoing Merkel cell differentiation postnatally; (c) that postnatal Merkel cell differentiation may be body-site dependent; and (d) that Merkel cell development and maintenance is independent of neural induction.