Extracellularly Extruded Syntaxin-4 Is a Potent Cornification Regulator of Epidermal Keratinocytes.

In the skin epidermis, keratinocytes undergo anchorage-dependent cornification, which gives rise to stratified multilayers, each with a distinct differentiation feature. The active formation of the cornified cell envelope (CCE), an important element in the skin barrier, occurs in keratinocytes of the upper epidermal layers and impacts their terminal differentiation. In the present study, we identified the extracellularly extruded syntaxin-4 as a potent differentiation regulator of epidermal keratinocytes. We found that differentiation stimuli led to the acceleration of syntaxin-4 exposure at the keratinocyte cell surface and that the artificial control of extracellular syntaxin-4, either by the forced expression of several syntaxin-4 mutants with structural alterations at the putative functional core site (AIEPQK), or by using antagonistic circular peptides containing this core sequence, dramatically influenced the CCE formation, with spatial misexpression of TGase1 and involucrin. We also found that the topical application of a peptide that exerted the most prominent antagonistic activity for syntaxin-4, named ST4n1, evidently prevented the formation of the hyperplastic and hyperkeratotic epidermis generated by physical irritation in HR-1 mice skin. Collectively, these results demonstrate that extracellularly extruded syntaxin-4 is a potent regulator of CCE differentiation, and that ST4n1 has potential as a clinically applicable reagent for keratotic skin lesions.

Extracellular syntaxin4 triggers the differentiation program in teratocarcinoma F9 cells that impacts cell adhesion properties.

The proteins in the syntaxin family are known to mediate fusion of cytoplasmic vesicles to the target membrane, yet subpopulations of certain syntaxins, including syntaxin4, translocate across the cell membrane in response to external stimuli. Here, we show that extracellularly presented syntaxin4 impacts cell behavior and differentiation in teratocarcinoma F9 cells. While undifferentiated F9 cells extruded a small subpopulation of extracellular syntaxin4 at the lateral cell membrane, the induction of differentiation with all-trans retinoic acid (RA) abolished this localized expression pattern. We found that the cells that were stimulated in a non-directional fashion by extracellular syntaxin4 displayed a flattened shape and retained a substrate-bound morphology even under a long-term, serum-starved cultivation. Such a cellular response was also elicited by a circular peptide composed of the potential functional core of syntaxin4 (AIEPQK; amino acid residues 103~108) (ST4n1). While the proliferation and metabolism were not affected in these cells, cell-cell interaction became weakened and the expression of vinculin, a regulator of both intercellular and cell-substrate adhesion molecules, was altered. We also found that the expressions of several differentiation markers were up-regulated in cells stimulated with extracellular syntaxin4 and that syntaxin3, another family member, was most prominent. Intriguingly, forced expression of syntaxin3 induced the spread morphology in F9 cells, indicating that syntaxin3 partly mediates the function of extracellular syntaxin4. These results demonstrate the involvement of a non-directional stimulation of extracellular syntaxin4 in the functional and morphological differentiation of F9 cells.

Effluent syntaxin3 from dying cells affords protection against apoptosis in epidermal keratinocytes.

Ultra-violet B (UVB)-induced oxidative stress crucially perturbs the epidermal homeostasis, and the skin is endowed with protective mechanisms to take action against such damage. Here, we show the possible involvement of t-SNARE protein syntaxin3, a membrane fusion mediator of cytoplasmic vesicles, and which is released from dying keratinocytes, to play a role in this response. UVB irradiation, which generates reactive oxidative stress in cells, was shown to lead to the keratinocyte cell death accompanied by a release of cytoplasmic syntaxin3. We found that such extracellularly sourced syntaxin3 completely blocked the processing of a crucial effector for apoptotic cell death, caspase-3, and thus facilitated the survival of keratinocytes damaged by oxidative stress. These results demonstrate the latent prosurvival function of syntaxin3 and underline the importance of intracellular molecular elements for the maintenance of homeostasis in epidermal keratinocytes.

A newly established culture method highlights regulatory roles of retinoic acid on morphogenesis and calcification of mammalian limb cartilage.

During mammalian embryogenesis, sclerotome-derived chondrocytes in the limb bud are arranged into a complicated bone shape with specific areas undergoing hypertrophy and calcification, creating a region-specific mineralized pattern in the cartilage. To follow chondrogenesis progression in vitro, we isolated limb cartilage from mice on embryonic day 13 (E13) and cultured it at the air-liquid interface after microsurgical removal of the ectoderm/epidermis. Explants underwent proper morphogenesis, giving rise to complete templates for limb bones in vitro. We found that region-specific calcification patterns resembling limbs of prepartum mature embryos could be induced in explants using culture medium containing high concentrations of CaCl2 (Ca), ascorbic acid (AA), and ß-glycerophosphoric acid (BGP). In this culture system, excess amounts of all-trans retinoic acid (RA) severely disrupted morphogenesis and calcification patterns in limb cartilage. These effects were more pronounced in forearms than in phalanges. Although dissociated, the nascent chondrocytes in culture did not give rise to cartilage units even though augmented calcification was induced in these cell aggregates in the presence of RA. Taken together, our newly established culture system revealed that RA independently regulates three-dimensional morphogenesis and calcification.

Krtap11-1, a hair keratin-associated protein, as a possible crucial element for the physical properties of hair shafts.

BACKGROUND: The physical properties of the hair are predominantly determined by the assembly of keratin bundles. The keratin-associated proteins (Krtaps) are thought to be involved in keratin bundle assembly, however, the functional role of the individual member still remains largely unknown. OBJECTIVE: The aim of this study is to clarify the role of a unique class of Krtaps, Krtap11-1, in the development and physical properties of the hair. METHODS: The expression regulation of Krtap11-1 was analyzed and its binding partners in the hair cortex were determined. Also, the effects of the forcible expression of this protein on the hair follicle development were analyzed in culture. RESULTS: The expression pattern of Krtap11-1 was concentrically asymmetric in the faulty hair that develops in Foxn1nu mice. In cultured keratinocytes, the expression of Krtap11-1 transgene product was strictly regulated by the keratinization process and proteasome-dependent protein elimination. While the association with keratin as well as the cohesive self-assembly of Krtap11-1 appeared to be stabilized by disulfide cross-links, the biotinylated Krtap11-1 probe enabled the adherence to certain type I keratins in the hair cortex, including K31, 33 and 34, in the absence of disulfide formation. When embryonic upper lip rudiments were forcibly introduced with Krtap11-1, the hair follicles formed irregularly arranged globular hair keratin-clumps surrounded by multilayered epithelial cells in culture. CONCLUSION: Krtap11-1 may play an important role on keratin-bundle assembly in the hair cortex and this study provides insight into the physical properties of the hair shaft.