Donald K. MacCallum

HYALURONAN BOUND TO CD44 ON KERATINOCYTES IS DISPLACED BY HYALURONAN DECASACCHARIDES AND NOT HEXASACCHARIDES

Abundant hyaluronan is present between epidermal keratinocytes. However, virtually nothing is known regarding its organization in the limited extracellular space between these cells. We have used metabolic labeling with [3H]glucosamine and [35S]sulfate and a hyaluronan-specific biotinylated probe to study the metabolism of hyaluronan and its localization in monolayer cultures of a rat epidermal keratinocyte cell line. Hyaluronan (∼20 fg/cell) was present on the apical and lateral surfaces of the cells in two nearly equal pools, either in patches (∼160/cell) or diffusely spread. The hyaluronan in the patches is bound to CD44 as indicated by co-localization with an antibody to CD44, and by displacement with hyaluronan decasaccharides as well as with an antibody that blocks hyaluronan binding to CD44. The inability of hyaluronan oligomers shorter than 10 monosaccharides to displace hyaluronan suggests that CD44 dimerization or cooperative interactions are required for tight binding. The diffuse hyaluronan pool is likely bound to hyaluronan synthase during its biosynthesis.

Organ Cultures of Embryonic Rat Tongue Support Tongue and Gustatory Papilla Morphogenesis In Vitro Without Intact Sensory Ganglia

Taste buds on the mammalian tongue are confined to the epithelium of three types of gustatory papillae: the fungiform, circumvallate, and foliate. The gustatory papillae are composed of an epithelium that covers a broad connective tissue core, with extensive innervation to taste bud and nongustatory epithelial locations. Although the temporal sequence of gustatory papilla development is known for several species, factors that regulate initiation, growth, and maintenance of the papillae are not understood. We tested the hypothesis that sensory innervation is required for the initial formation and early morphogenesis of fungiform papillae in a patterned array. An organ culture of the embryonic rat tongue was developed to provide an in vitro system for studying mechanisms involved in fungiform papilla morphogenesis in patterns on the anterior tongue. Tongues were dissected from embryos at 13 days of gestation (E13), a time when the tongue has not yet fully formed and gustatory papillae have not yet appeared, and at 14 days of gestation (E14), when the tongue is well formed and papillae make their initial morphological appearance. Dissected tongues were maintained at the gas/liquid interface in standard organ culture dishes, fed with DMEM/F12 plus 2% B‐27 supplement and 1% fetal bovine serum. After 1, 2, 3, or 6 days in culture, tongues were processed for scanning electron or light microscopy, or immunocytochemistry. Tongues cultured from E13 or E14 underwent extensive morphogenesis and growth in vitro. Furthermore, fungiform papillae developed on these tongues on a culture day equivalent to E15 in vivo; that is, after 2 days for cultures begun at E13 and 1 day for those begun at E14. Because E15 is the characteristic time for gustatory papilla formation in the intact embryo, results demonstrate that the cultured tongues retain important temporal information related to papilla development. In addition, fungiform papillae formed in the tongue cultures in the stereotypic pattern of rows. The papillae were large structures with epithelial and mesenchymal cell integrity, and an intact epithelial basement membrane was indicated with laminin immunoreactivity. The cultures demonstrate that gustatory papilla morphogenesis can progress in the absence of an intact sensory innervation. To exclude a potential developmental role for autonomic ganglion cells that are located in the posterior rat tongue, cultures consisting of only the anterior half of E14 tongues were established. Fungiform papilla development progressed in half tongues in a manner directly comparable to whole tongue cultures. Therefore, robust, reproducible development of fungiform papillae in patterns is supported in rat tongue cultures from E13 or E14, without inclusion of intact sensory or major, posterior tongue autonomic ganglia. This is direct evidence that papillae will form and develop further in vitro without sensory ganglion support. The data also provide the first detailed account of in vitro development of the entire embryonic tongue. J. Comp. Neurol. 377:324–340, 1997.

Fine structure of subcultivated stratified squamous epithelium grown on collagen rafts.

Abstract Subcultivated rat lingual epithelial cells when grown on collagen gels at a liquid-gas interface achieve a highly ordered state that closely resembles the parent tissue. Three distinct cell layers are present; basal, spinous, and keratinized. Basal cells are cuboidal in shape and form a complex interface with the underlying collagen fibrils. Spinous cells form a layer 5–10 cells thick and, with the exception of keratohyalin granules, possess an organellar complement identical with native cells, including membrane-coating granules. The keratinized cell layer increases in thickness as a function of time spent in culture. Forty or more plies of terminally differentiated cells are observed following a 30-day culture period. Terminally differentiated cells while retaining pycnotic nuclei and some other organellar debris are principally envelope-enclosed squames filled with tonofilaments. Keratinization is a continuing process which occurs simultaneously across the full expanse of the culture surface. The high degree of tissue organization observed appears to be the result of feeding the cultures from the undersurface.

Cyclopamine and jervine in embryonic rat tongue cultures demonstrate a role for Shh signaling in taste papilla development and patterning : fungiform papillae double in number and form in novel locations in dorsal lingual epithelium

From time of embryonic emergence, the gustatory papilla types on the mammalian tongue have stereotypic anterior and posterior tongue locations. Furthermore, on anterior tongue, the fungiform papillae are patterned in rows. Among the many molecules that have potential roles in regulating papilla location and pattern, Sonic hedgehog (Shh) has been localized within early tongue and developing papillae. We used an embryonic, tongue organ culture system that retains temporal, spatial, and molecular characteristics of in vivo taste papilla morphogenesis and patterning to study the role of Shh in taste papilla development. Tongues from gestational day 14 rat embryos, when papillae are just beginning to emerge on dorsal tongue, were maintained in organ culture for 2 days. The steroidal alkaloids, cyclopamine and jervine, that specifically disrupt the Shh signaling pathway, or a Shh-blocking antibody were added to the standard culture medium. Controls included tongues cultured in the standard medium alone, and with addition of solanidine, an alkaloid that resembles cyclopamine structurally but that does not disrupt Shh signaling. In cultures with cyclopamine, jervine, or blocking antibody, fungiform papilla numbers doubled on the dorsal tongue with a distribution that essentially eliminated inter-papilla regions, compared with tongues in standard medium or solanidine. In addition, fungiform papillae developed on posterior oral tongue, just in front of and beside the single circumvallate papilla, regions where fungiform papillae do not typically develop. The Shh protein was in all fungiform papillae in embryonic tongues, and tongue cultures with standard medium or cyclopamine, and was conspicuously localized in the basement membrane region of the papillae. Ptc protein had a similar distribution to Shh, although the immunoproduct was more diffuse. Fungiform papillae did not develop on pharyngeal or ventral tongue in cyclopamine and jervine cultures, or in the tongue midline furrow, nor was development of the single circumvallate papilla altered. The results demonstrate a prominent role for Shh in fungiform papilla induction and patterning and indicate differences in morphogenetic control of fungiform and circumvallate papilla development and numbers. Furthermore, a previously unknown, broad competence of dorsal lingual epithelium to form fungiform papillae on both anterior and posterior oral tongue is revealed.

Bovine corneal endothelium in vitro: Elaboration and organization of a basement membrane

Abstract Bovine corneal endothelial cells can be easily grown in culture using conventional techniques. The cultured cells closely resemble the parent, native endothelium. In culture the endothelium synthesizes and deposits, in a polar fashion, a well organized basement membrane that contains molecules which are characteristic of all basement membranes. Membrane deposition continues for at least a year and, during that time, it begins to acquire the unique, ordered substructure characteristic of the native membrane.

Collagen structure: evidence for a helical organization of the collagen fibril.

The collagen fibrils of human or guinea pig dermis when exposed to the denaturing agents, urea or guanidine—HCl, dissociated into smaller, disparate subunits, probably aggregates of microfibrils. The process of dissociation demonstrates that the fibrils are assembled helically. Initially, diagonal clefts appear on the surface of the fibril. These clefts are surface manifestations of a spirally oriented, internal space. Continued exposure to these denaturants resulted in progressive dissociation of the fibril into helically oriented subunits. It is suggested that water-miscible compounds such as glycols or hydroxypropyl methacrylate, in addition to the urea—guanidinium class of denaturants used in this study, affect the observed fbrillar changes through the disruption of hydrogen bonds between the microfibrils making up the fibril. Such a mode of action may explain why freeze-fractured or “inert embedded” collagen demonstrates helical organization while other, more conventional methods of tissue processing do not. Further support for the proposed mode of action of these dissociative agents was provided by the observation that mature collagen, in which extensive intra- and intermolecular covalent crosslinks are present, is more resistant to dissociation than newly formed collagen.

Fine structure of subcultivated stratified squamous epithelium

Abstract Subcultivated rat lingual epithelium derived from primary expiants remains mitotically active, possesses an organellar complement similar to the parent tissue, and undergoes terminal differentiation. Successful growth of primary cultures requires an incubation temperature below 34 °C and the addition of dimethyl sulfoxide (DMSO) to the medium. The subcultures retain a stable morphological phenotype through a minimum of 15 passages. Cultures are long-lived and may be maintained for one year or more in any passage.

Ultrastructure and histochemistry of the submandibular gland of the European hedgehog, Erinaceous europaeus L. I. Acinar secretory cells

The ultrastructure and histochemistry of the submandibular gland of the European hedgehog was examined. The gland was of the mixed type, consisting of approximately equal numbers of mucous and serous cells. On the basis of staining reactions, it was concluded that the mucous droplets contained only one type of mucin, a periodate-reactive sialomucin, and that the serous granules contained glycoprotein. At the ultrastructural level, it was found that the mucous droplets often contained a dense spherule, and that their matrix was responsive to variations in fixation procedures. The serous granules developed in a remarkable fashion. Small, dense rodlets in Golgi-derived vacuoles became aligned to form a series of concentric dense shells. The intervals between shells became filled with small, dense particles. These particles, coupled with condensation of the granules, led to increasing densification of the granule matrix. The contents of mature serous granules were liberated by a merocrine process into the acinar lumen, where they disintegrated.

Distinctive spatiotemporal expression patterns for neurotrophins develop in gustatory papillae and lingual tissues in embryonic tongue organ cultures.

Abstract. Brain-derived neurotrophic factor (BDNF) and neurotrophin-3 (NT-3) mRNAs are expressed in the developing rat tongue and taste organs in specific spatiotemporal patterns. BDNF mRNA is present in the early lingual gustatory papilla epithelium, from which taste buds eventually arise, prior to the arrival of gustatory nerve fibers at the epithelium, whereas NT-3 initially distributes in the mesenchyme. However, a direct test for neural dependence of neurotrophin expression on the presence of innervation in tongue has not been made, nor is it known whether the patterns of neurotrophin expression can be replicated in an in vitro system. Therefore, we used a tongue organ culture model that supports taste papilla formation while eliminating the influence from sensory nerve fibers, to study neurotrophin mRNAs in lingual tissues. Rat tongue cultures were begun at embryonic day 13 or 14 (E13, E14), and BDNF, NT-3, nerve growth factor (NGF) and neurotrophin-4 (NT-4) mRNAs were studied at 0, 2, 3 and 6 days in culture. BDNF transcripts were localized in the gustatory epithelium of both developing fungiform and circumvallate papillae after 2 or 3 days in culture, and NT-3 transcripts were in the subepithelial mesenchyme. The neurotrophin distributions were comparable to those in vivo at E13–E16. In 6-day tongue cultures, however, BDNF transcripts in anterior tongue were not restricted to fungiform papillae but were more widespread in the lingual epithelium, while the circumvallate trench epithelium exhibited restricted BDNF labeling. The NT-3 expression pattern shifted in 6-day organ cultures in a manner comparable to that in the embryo in vivo, and was expressed in the lingual epithelium as well as mesenchyme. NGF mRNA expression was subepithelial throughout 6 days in cultures. NT-4 mRNA was not detected. The neurotrophin mRNA distributions demonstrate that temporospatial localization of neurotrophins observed during development in vivo is retained in the embryonic tongue organ culture system. Furthermore, initial neurotrophin expression in the developing lingual epithelium, mesenchyme, and/or taste papillae is not dependent on intact sensory innervation. We suggest that patterns of lingual neurotrophin mRNA expression are controlled by the influence of local tissue interactions within the tongue at early developmental stages. However, the eventual loss of restricted BDNF mRNA localization from fungiform papillae in anterior tongue suggests that sensory innervation may be important for restricting the localized expression of neurotrophins at later developmental stages, and for maintaining the unique phenotypes of gustatory papillae.

Penetrating Keratoplasty in the Cat: A Clinically Applicable Model

A series of 28 consecutive penetrating keratoplasties were performed on adult cats. Donor corneas (n = 14) were maintained in culture medium for 14--24 hours prior to transplantation. Rotational autografts (n = 7) were used to control for cell loss caused by culture maintenance as well as for the effects of surgery. Additional homografts (n = 7) were transplanted following removal of the corneal endothelium to study the extent of host corneal endothelial cell regeneration. Pre- and post-operative endothelial cell counts of the homografts made from specular micrographs demonstrated an average cell loss of 30% one month following surgery. A similar 30% average cell loss was present in the rotational autografts. Clinically, both homografts and autografts remained clear and were near normal in thickness. Homografts lacking endothelium exhibited persistent, severe edema that correlated with the inability of the host corneal endothelium to resurface the graft. Clinical and morphologic evidence of mild homograft rejection as observed in 15% of the animals that received normal homografts. Corneal endothelial cell loss following penetrating keratoplasty in the cat approximates that observed following the same procedure in the human. Additionally, regenerative capacity of the corneal endothelium in the cat, like that of the human, is limited. These features suggest that this cooperative, hardy animal is an excellent model in which to study many aspects of corneal transplantation that have direct application to the treatment of human corneal disease.