Relative gene expression analysis of human pterygium tissues and UV radiation-evoked gene expression patterns in corneal and conjunctival cells.

A sight threatening, pterygium is a common ocular surface disorders identified by fibrovascular growth of the cornea and induced by variety of stress factors, like ultraviolet (UV) exposure. However, the genes involved in the etiopathogenesis of this disease is not well studied. Herein, we identified the gene expression pattern of pterygium and examined the expression of pterygium-related genes in UV-B-induced human primary cultured corneal epithelial cells (HCEpCs), telomerase immortalized human corneal epithelial (hTCEpi), primary conjunctival fibroblast (HConFs) and primary pterygium fibroblast cells (HPFCs). A careful analysis revealed that the expression of 10 genes was significantly modulated (by > 10-fold). Keratin 24 (KRT24) and matrix metalloproteinase 9 (MMP-9) were dramatically upregulated by 49.446- and 24.214-fold, respectively. Intriguingly, UV-B exposure (50 J/m2) induced the upregulation of the expressions of MMP-9 in corneal epithelial cells such as HCEpCs and hTCEpi. Furthermore, UV-B exposure (100 and/or 200 J/m2) induced the upregulation of the expressions of MMP-9 in fibroblast such as HConFs and HPFCs. The exposure of HCEpCs to 100 and 200 J/m2 UV-B induced significant expressions of KRT24 mRNA. Nevertheless, no expression of KRT24 mRNA was detected in HConFs and HPFCs. The findings provide evidence that the progression of pterygium may involve the modulation of extracellular matrix-related genes and vasculature development and the up-regulation of KRT24 and MMP-9 by UV stress. UV radiation may promote the modulation of these pterygium-related genes and induce the initiation and progression of human pterygium.

K31 as a novel marker for clear secretory cells in human eccrine sweat glands.

K31 was previously considered as one of the hair keratins. During a study on differential markers between hair follicles and eccrine sweat glands, we observed that K31 was expressed in eccrine sweat gland cells in a scattered pattern, similar to the distribution of dark or clear secretory cells. To investigate the precise cell localization of K31 in human eccrine sweat glands and find new marker for eccrine sweat gland cells, human skin samples were fixed, paraffined and sectioned. The serial sections were stained for K31, dark secretory cell marker gross cystic disease fluid protein 15 (GCDFP15) and clear secretory cell marker carbonic anhydrase II (CAII). The exact cell localization of K31 was detected by double immunofluorescence staining of K31 and a serial of cell-specific markers, and further by dual stain using a combination of periodic acid-Schiff (PAS) and immunofluorescence for K31 and GCDFP15. The expression pattern of K31-positive cells was similar to that of CAII-positive cells but was different from that of GCDFP15-positive staining in serial sections. Double immunofluorescent staining showed that K31-positive cells co-expressed K7 and CAII, but not S100P, α-SMA or GCDFP15. Dual stain by combined PAS and immunofluorescence showed that K31-positive cells are negative for PAS staining. We conclude that K31 is a previously unreported eccrine clear cell marker that allows for distinction between clear and dark secretory cells, as well as between secretory coils and ducts of eccrine sweat glands in human eccrine sweat glands.

The expression pattern of keratin 24 in tissue-engineered dermo-epidermal human skin substitutes in an in vivo model.

AIMS AND OBJECTIVES: The use of autologous tissue-engineered skin substitutes is a promising approach to cover large skin defects in patients. Preclinical investigation is pivotal to test and improve the quality of these bio-engineered substitutes. In the skin, the epidermis, formed mainly by keratinocytes, provides the first physical barrier protecting from the environment. Proper keratinocyte differentiation and, thus, formation of a stratified epidermis is essential for this function. Keratins, the main structural support of keratinocytes, play a vital role regarding differentiation of keratinocytes. Here, we examined the expression pattern of a recently described keratinocyte differentiation marker, namely Keratin 24, in our skin substitutes. MATERIALS AND METHODS: Human epidermal keratinocytes, melanocytes, dermal fibroblasts, palmar fibroblasts or sweat gland cells were used to prepare skin substitutes. Fibroblast-containing collagen hydrogels were prepared, and keratinocytes or sweat gland cells and melanocytes were seeded onto the hydrogels. The generated tissue-engineered dermo-epidermal skin analogs were transplanted onto full-thickness skin wounds created on the back of immuno-incompetent rats. The skin substitutes were excised at different time points and histologically examined with regard to Keratin 24 expression. RESULTS: We observed the expression of Keratin 24 in keratinocytes of the upper stratum spinosum of the epidermis. In particular, we observed an intensified expression of Keratin 24 13 weeks after transplantation compared to 4 weeks after transplantation. Importantly, we noticed a markedly higher presence of Keratin 24 in more spinous layers if we used palmar fibroblasts or sweat gland cells in our skin substitutes compared non-palmar fibroblasts or epidermal keratinocytes. CONCLUSION: Our observations prove that the keratinocyte differentiation marker Keratin 24 is expressed in our dermo-epidermal skin substitutes in a normal pattern. This highlights that our bio-engineered skin analogs mature and reach homeostasis in an in vivo assay. These findings harbor favorable implications regarding future clinical application.

Expression of cytokeratins 10, 13, 14 and 19 in oral lichen planus.

OLP is a chronic inflammatory disease of unknown etiology that may develop into squamous-cell carcinoma. Cytokeratins, which are important components of the cytoskeleton, are excellent epithelial differentiation markers used to study neoplastic and inflammatory diseases. To study the profile of cytokeratins in OLP and their possible association with dysplastic alterations, monoclonal antibodies were used for cytokeratins 10, 13, 14 and 19, in 26 samples of OLP. The streptavidin-biotin technique was employed in paraffin-embedded tissue sections. Sample analysis revealed suprabasal expression of cytokeratin 10 in 16/17 samples, 14 of them with reduced expression; suprabasal expression of cytokeratin 13 in 18/23, 16 of them with delay; basal and suprabasal expression of cytokeratin 14 in all samples; and focal basal expression of cytokeratin 19 in 4/21. Expression of cytokeratins 10, 13 and 14 was altered in OLP lesions. The inflammatory process and hyperkeratosis or parakeratosis seem to have interfered with the expression of these CKs. Cytokeratin 19 was expressed in the lesions, in a pattern similar to that mentioned in the literature for the non-keratinized oral mucosa. The presence of mild dysplasia did not change the expression of the cytokeratins studied. No differences in pattern of expression were observed between keratinized and non-keratinized areas in the lesions caused by OLP.

Transcriptional activation of a subset of hair keratin genes by the NF-kappaB effector p65/RelA.

The hair follicle is an intricate miniature organ dedicated to the production of the structural hair fiber, which is largely composed of hair keratin (HK) proteins. Many developmental pathways contribute to hair follicle development; however, the molecular control of HK genes is still far from being resolved. Because the nuclear factor (NF)-kappaB pathway is known to be involved in the morphogenesis of the hair follicle, we explored the possibility that it may also regulate HK expression. To this end, we analyzed the effect of p65/RelA, an NF-kappaB effector, on HK regulatory regions using transient transfections into tissue culture cells. Reporter assays on cells transfected with HK promoter constructs and real-time polymerase chain reaction analysis of endogenous HK gene activity demonstrated that p65 induces transcriptional activation of several HK genes of human and mouse origin, primarily that of acidic hair keratin 5 (Ha5). Focusing on the highly responsive human Ha5 gene, we defined the major NF-kappaB/RelA binding sites in its regulatory region and showed the direct binding of p65 to these sites using gel shift assays. We further show, using immunohistochemistry on human hair follicle sections, that p65 is co-expressed with HKs in the hair shaft compartment and may thus be the effector that mediates the NF-kappaB pathway's activity, which recently was genetically demonstrated to be active in the same region. Thus, we provide evidence for a previously unknown function of NF-kappaB in hair formation-direct activation of HK target genes-a function that may shed light on some of the symptoms of ectodermal dysplasias.

Phosphoprotein Keratin 23 accumulates in MSS but not MSI colon cancers in vivo and impacts viability and proliferation in vitro.

Transcript profiling of 27 normal colon mucosas and 258 adenocarcinomas showed Keratin23 to be increased in 78% microsatellite-stable tumors, while microsatellite-instable tumors showed low transcript levels, comparable to normal mucosas. Immunohistochemical analyses demonstrated that 88% of microsatellite-instable tumors were negative for Keratin23 protein, while 70% of MSS tumors and metastases derived from MSS-tumors showed high Keratin23 levels. Immunofluorescence analysis localized Keratin23 in the Golgi-apparatus. Golgi accumulation was unique for gastrointestinal adenocarcinomas. Immunoprecipitation and 2D-blot analysis revealed Keratin23 to be a 46.8 kDa phosphoprotein. Keratin23 impaired the proliferation of human colon cancer cells significantly, leading to cell death in microsatellite-instable but not microsatellite-stable cell lines, while COS7 cells experienced multiple nuclei and apoptosis. Keratin23 expression correlated significantly with transcription factor CEBPB. In conclusion, Keratin23 expression is a novel and important difference between microsatellite-stable and microsatellite-instable colon cancers.