All-trans retinoic acid-induced hyaluronan production and hyperplasia are partly mediated by EGFR signaling in epidermal keratinocytes.

All-trans retinoic acid (RA) compromises epidermal differentiation and causes keratinocyte hyperproliferation through mechanisms not completely understood, but may involve the regulatory matrix molecule hyaluronan. In this work, the influences of all-trans RA on epidermal morphology and hyaluronan metabolism were examined in organotypic and monolayer cultures of rat epidermal keratinocytes (REKs). All-trans RA treatment of organotypic REK cultures (10 days) increased the synthesis of hyaluronan, the expression of hyaluronan synthases Has2 and Has3, and the CD44 receptor, with hyperplasia of the epidermis. The hyperplasia and hyaluronan production induced by all-trans RA were blocked with (1) AG1478, an inhibitor of the EGFR; (2) UO126, an inhibitor of the MAPK/ERK kinase, and (3) GM6001, an inhibitor of the matrix metalloproteinases. These effects were consistent with the findings that all-trans RA upregulated heparin-binding epidermal growth factor-like growth factor mRNA expression and increased the phosphorylation of EGFR and extracellular signal-regulated kinase 1/2 (ERK1/2). Interestingly, the activation of EGFR and ERK1/2 was seen already 30 minutes after all-trans RA treatment, suggesting that the activation of this signaling pathway is a primary response to all-trans RA. These results indicate that the effects of all-trans RA on keratinocyte proliferation and hyaluronan synthesis are partly mediated through EGFR signaling.

Sonic hedgehog exerts distinct, stage-specific effects on tongue and taste papilla development.

Taste papillae are ectodermal specializations that serve to house and distribute the taste buds and their renewing cell populations in specific locations on the tongue. We previously showed that Sonic hedgehog (Shh) has a major role in regulating the number and spatial pattern of fungiform taste papillae on embryonic rat tongue, during a specific period of papilla formation from the prepapilla placode. Now we have immunolocalized the Shh protein and the Patched receptor protein (Ptc), and have tested potential roles for Shh in formation of the tongue, emergence of papilla placodes, development of papilla number and size, and maintenance of papillae after morphogenesis is advanced. Cultures of entire embryonic mandible or tongues from gestational days 12 to 18 [gestational or embryonic days (E)12-E18] were used, in which tongues and papillae develop with native spatial, temporal, and molecular characteristics. The Shh signaling pathway was disrupted with addition of cyclopamine, jervine, or the 5E1 blocking antibody. Shh and Ptc proteins are diffuse in prelingual tissue and early tongue swellings, and are progressively restricted to papilla placodes and then to regions of developing papillae. Ptc encircles the dense Shh immunoproduct in papillae at various stages. When the Shh signal is disrupted in cultures of E12 mandible, tongue formation is completely prevented. At later stages of tongue culture initiation, Shh signal disruption alters development of tongue shape (E13) and results in a repatterned fungiform papilla distribution that does not respect normally papilla-free tongue regions (E13-E14). Only a few hours of Shh signal disruption can irreversibly alter number and location of fungiform papillae on anterior tongue and elicit papilla formation on the intermolar eminence. However, once papillae are well formed (E16-E18), Shh apparently does not have a clear role in papilla maintenance, nor does the tongue retain competency to add fungiform papillae in atypical locations. Our data not only provide evidence for inductive and morphogenetic roles for Shh in tongue and fungiform papilla formation, but also suggest that Shh functions to maintain the interpapilla space and papilla-free lingual regions. We propose a model for Shh function at high concentration to form and maintain papillae and, at low concentration, to activate between-papilla genes that maintain a papilla-free epithelium.

Expression of the inwardly rectifying K+ channel Kir2.1 in native bovine corneal endothelial cells.

PURPOSE: To determine the presence of Kir2.1 channels in native bovine corneal endothelial (BCE) cells and assess their contribution to the resting membrane potential. METHODS: RT-PCR and Western blot analysis were used to detect the expression of Kir2.1 mRNA and protein in native BCE cells. Whole-cell patch-clamp recording was used to characterize Kir2.1 currents in freshly isolated, single BCE cells, as well as in BCE cell clusters. The contribution of Kir2.1 channels to the membrane potential (V(m)) was assessed by whole-cell recording in the zero-current clamp mode in the absence and presence of Ba(2+). RESULTS: RT-PCR analysis confirmed that Kir2.1 was expressed in the native BCE cells. Western blot analysis with native BCE cell protein and a polyclonal anti-Kir2.1 antibody revealed a approximately 60-kDa band that was blocked by the corresponding synthetic Kir2.1 peptide. Both single BCE cells and BCE cell clusters exhibited an inwardly rectifying K(+) (Kir) current that was dependent on the extracellular K(+) concentration. The Kir current was blocked by external Ba(2+) or Cs(+) in a voltage- and concentration-dependent manner. In 5 mM K(+) Ringer's, the V(m) of cell clusters averaged -40.0 +/- 4.1 mV (n = 14) and in 140 mM K(+) Ringer's it depolarized to -7.4 +/- 1.8 mV. Application of Ba(2+) in 5 mM K(+) Ringer's produced a concentration-dependent depolarization of V(m), with 10 mM Ba(2+) depolarizing V(m) from -53.4 +/- 4.8 mV to -27.8 +/- 6.3 mV (n = 6). CONCLUSIONS: Native BCE cells express functional Kir2.1 channels that help determine the membrane potential and probably also play a role in transendothelial transport.

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.

Distinctive neurophysiological properties of embryonic trigeminal and geniculate neurons in culture.

Neurons in trigeminal and geniculate ganglia extend neurites that share contiguous target tissue fields in the fungiform papillae and taste buds of the mammalian tongue and thereby have principal roles in lingual somatosensation and gustation. Although functional differentiation of these neurons is central to formation of lingual sensory circuits, there is little known about electrophysiological properties of developing trigeminal and geniculate ganglia or the extrinsic factors that might regulate neural development. We used whole cell recordings from embryonic day 16 rat ganglia, maintained in culture as explants for 3-10 days with neurotrophin support to characterize basic properties of trigeminal and geniculate neurons over time in vitro and in comparison to each other. Each ganglion was cultured with the neurotrophin that supports maximal neuron survival and that would be encountered by growing neurites at highest concentration in target fields. Resting membrane potential and time constant did not alter over days in culture, whereas membrane resistance decreased and capacitance increased in association with small increases in trigeminal and geniculate soma size. Small gradual differences in action potential properties were observed for both ganglion types, including an increase in threshold current to elicit an action potential and a decrease in duration and increase in rise and fall slopes so that action potentials became shorter and sharper with time in culture. Using a period of 5-8 days in culture when neural properties are generally stable, we compared trigeminal and geniculate ganglia and revealed major differences between these embryonic ganglia in passive membrane and action potential characteristics. Geniculate neurons had lower resting membrane potential and higher input resistance and smaller, shorter, and sharper action potentials with lower thresholds than trigeminal neurons. Whereas all trigeminal neurons produced a single action potential at threshold depolarization, 35% of geniculate neurons fired repetitively. Furthermore, all trigeminal neurons produced TTX-resistant action potentials, but geniculate action potentials were abolished in the presence of low concentrations of TTX. Both trigeminal and geniculate neurons had inflections on the falling phase of the action potential that were reduced in the presence of various pharmacological blockers of calcium channel activation. Use of nifedipine, omega-conotoxin-MVIIA and GVIA, and omega-agatoxin-TK indicated that currents through L-, N-, and P/Q- type calcium channels participate in the action potential inflection in embryonic trigeminal and geniculate neurons. The data on passive membrane, action potential, and ion channel characteristics demonstrate clear differences between trigeminal and geniculate ganglion neurons at an embryonic stage when target tissues are innervated but receptor organs have not developed or are still immature. Therefore these electrophysiological distinctions between embryonic ganglia are present before neural activity from differentiated receptive fields can influence functional phenotype.