Hyaluronan (HA) has an extraordinarily high turnover in physiological tissues, and HA degradation is accelerated in inflammatory and neoplastic diseases. CD44 (a cell surface receptor) and two hyaluronidases (HYAL1 and HYAL2) are thought to be responsible for HA binding and degradation; however, the role of these molecules in HA catabolism remains controversial. Here we show that KIAA1199, a deafness gene of unknown function, plays a central role in HA binding and depolymerization that is independent of CD44 and HYAL enzymes. The specific binding of KIAA1199 to HA was demonstrated in glycosaminoglycan-binding assays. We found that knockdown of KIAA1199 abolished HA degradation by human skin fibroblasts and that transfection of KIAA1199 cDNA into cells conferred the ability to catabolize HA in an endo-β-N-acetylglucosaminidase-dependent manner via the clathrin-coated pit pathway. Enhanced degradation of HA in synovial fibroblasts from patients with osteoarthritis or rheumatoid arthritis was correlated with increased levels of KIAA1199 expression and was abrogated by knockdown of KIAA1199. The level of KIAA1199 expression in uninflamed synovium was less than in osteoarthritic or rheumatoid synovium. These data suggest that KIAA1199 is a unique hyaladherin with a key role in HA catabolism in the dermis of the skin and arthritic synovium. HA is ubiquitously present as a major constituent of the extracellular matrix (ECM) in vertebrate tissues, providing structural and functional integrity to cells and organs. Although many organs maintain high concentrations of HA, skin contains approximately half the total body HA (1). HA is rapidly depolymerized within tissues, from extralarge native molecules of 1,000-10,000 kDa, to intermediate-size fragments of 10-100 kDa present in the extracellular milieu (2). Approximately one-third of total body HA is replaced daily, and the skin is a major determinant organ for HA turnover, with a metabolic half-life of 1-1.5 d (2). HA degradation is enhanced under certain pathological conditions and its lower molecular weight products are commonly detected in diseases, such as arthritis and cancers (3-5). The reduced average molecular weight of HA (as low as 200 kDa) in synovial fluids from patients with osteoarthritis (OA) or rheumatoid arthritis (RA) leads to decreased synovial viscosity and is associated with synovial inflammation (6). In addition, much lower molecular weight HA fragments (∼20 kDa) are known to stimulate neovascularization and facilitate tumor cell motility and invasion (5,7,8).There are six human hyaluronidase-related genes clustered on two chromosomal loci, 3p21.3 (HYAL1, HYAL2, and HYAL3) and 7q31.3 (HYAL4, HYALP1, and SPAM1) (9). However, because HYALP1 is a pseudogene (9), and HYAL4 and SPAM1 have restricted expression patterns, HYALP1, HYAL4, and SPAM1 are unlikely to have major roles in constitutive HA degradation in vivo. HYAL3 has a restricted expression pattern (9) and its ability to degrade HA is questionable (10). Therefore, HYAL1 and HYAL2 are most likely ...
Natural moisturizing factor (NMF) of the stratum corneum (SC) has been established to play important roles in the physical properties of the SC. Few studies, however, have investigated the specific influences of NMF components other than the amino acids. In this study, therefore, we focus on the relationship between the ion content and physical properties of the SC in 40 healthy subjects. Changes in the physical properties of the SC induced by the extraction of NMF were equivalent to the changes that took place from summer to winter, demonstrating the important role of NMF in the physical properties of the SC in healthy subjects. The seasonal changes in the physical properties of the SC from summer to winter were accompanied by significant decreases in the levels of lactate, potassium, sodium, and chloride in the SC. Lactate and potassium were the only components found to correlate significantly with the state of hydration, stiffness, and pH in the SC. Interestingly, the levels of lactate and potassium in the SC were also significantly correlated. Moreover, potassium lactate restored the SC hydration state decreased by extraction of NMF. These results suggest that lactate and potassium may play roles in maintaining the physical properties of the SC in healthy subjects.
These new results as well as our earlier results with diabetic mice suggest that patients with diabetes mellitus tend to show a reduced hydration state of the SC together with decreased sebaceous gland activity, without any impairment of the SC barrier function.
We examined in situ expression of putative hyaluronan synthase genes, Has1 and Has2, and effects of transforming growth factor-beta on their expression. In situ mRNA hybridization showed that mouse skin expressed both Has1 and Has2 mRNA in dermis and epidermis. In dermis, the number of cells expressing the Has1 mRNA was less than that of the Has2 mRNA, and in epidermis, some strong signals from both mRNA were seen in stratum granulosum. Northern blot analysis showed that cultured human skin fibroblasts expressed Has1 mRNA of 2.4 kb and Has2 mRNA of 3.2 and 4.8 kb, whereas human keratinocytes expressed Has1 mRNA of 4.8 but not 2.4 kb and a trace of Has2 mRNA. When the cultures were stimulated with transforming growth factor-beta, both Has1 and Has2 mRNA were upregulated in fibroblasts, and only Has1 mRNA of 2.4 but not 4.8 kb was induced in keratinocytes. The maximal amount of the upregulated Has1 mRNA in keratinocytes at 2 h after stimulation decreased time-dependently to the nonstimulated level at 18 h, although the stimulation for 18 h of fibroblasts was effective on the expression of both Has mRNA. Differences in expression pattern of Has and Has2 mRNA in mouse skin and a higher response of fibroblasts to transforming growth factor-beta suggest that Has1 and Has2 genes are regulated independently and synthesized hyaluronan may have a different function in epidermis and dermis.
Three human hyaluronan synthase genes (HAS1, HAS2, and HAS3) have been cloned, but the functional differences between these HAS genes remains obscure. The purpose of this study was to examine which of the HAS genes are selectively regulated in epidermis. We examined the relation of changes between hyaluronan production and HAS gene expression when cytokines were added to cultured human keratinocytes. Interferon-gamma increased hyaluronan production whereas transforming growth factor beta decreased it. Both cytokines affected preferentially high-molecular-mass (> 106 Da) hyaluronan production. Consistent with the change in hyaluronan synthesis, we found that interferon-gamma markedly upregulated HAS3 mRNA whereas transforming growth factor beta downregulated HAS3 transcript levels. The expression of HAS1 mRNA was not significantly affected by either cytokine, and HAS2 mRNA expression was undetectable under either basal or cytokine-stimulated conditions by northern blot using total RNA. Furthermore, in situ mRNA hybridization showed that mouse epidermal keratinocytes abundantly expressed HAS3 mRNA from the basal to the granular cell layers, suggesting that HAS3 functions in epidermis. These findings suggest that HAS3 gene expression plays a crucial role in the regulation of hyaluronan synthesis in the epidermis.
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