UV irradiation-induced production of monoglycosylated biglycan through downregulation of xylosyltransferase 1 in cultured human dermal fibroblasts.

BACKGROUND: Biglycan (BGN) is a proteoglycan composed of a 42-kDa core protein and two glycosaminoglycan (GAG) chains, and known to be involved in structural, space-filling functions and many physiological regulations in the skin. OBJECTIVE: To investigate ultraviolet (UV) irradiation-induced changes of BGN protein and its GAG chain synthesis in cultured human dermal fibroblasts. METHODS: UV irradiation-induced or xylosyltransferase (XYLT) 1 siRNA-mediated smaller-sized protein bands detected by Western blot using BGN antibodies were identified as monoglycosylated forms of BGN, using BGN siRNA-mediated knockdown and chondroitinase ABC (ChABC). Differential activity of XYLT1 and 2 on BGN core protein was investigated by size shift of S42A- and S47A-BGN mutants to core protein size caused by XYLT1 siRNA transfection or UV irradiation. RESULTS: After UV irradiation, intact form of BGN protein (I-BGN) and core protein form were reduced in cultured fibroblasts, but other smaller-sized bands were observed to be increased. These smaller-sized ones were reduced by transfection of BGN siRNA, and shifted to the core protein size by treatment with ChABC, suggesting that they are defectively-glycosylated forms of BGN (D-BGN) protein. UV irradiation also decreased mRNA expression levels of XYLT1 and 2, which are responsible for initiation of GAG chain synthesis. UV-mediated reduction of XYLT1 expression was much stronger than that of XYLT2. Furthermore, siRNA-mediated down-regulation of XYLT1 resulted in the increase of D-BGN and the decrease of I-BGN, while down-regulation of XYLT2 resulted in no change of D-BGN and I-BGN, suggesting that the XYLT1 may react with both GAG-attaching serine sites of BGN; however, XYLT2 may prefer to react one of them. Another dermatan sulfate (DS) proteoglycan, decorin, showed no or a little change of its molecular weight by UV irradiation or XYLT1 siRNA transfection, suggesting that DS synthesis may not be a critical factor in formation of D-BGN. Co-transfection with XYLT1, 2 siRNAs and wild-type or mutant forms of BGN overexpression vectors revealed that S42A-BGN showed size reduction to core protein size by XYLT1 downregulation, but S47A-BGN did not, suggesting that XYLT2 can react only with S42 on BGN core protein. With UV irradiation, both S42A-BGN and S47A-BGN showed size reduction, which is probably because UV-caused downregulation of both XYLTs and overexpression condition resulted in incomplete glycosylation and secretion. CONCLUSIONS: UV irradiation-induced increase of BGN monoglycosylated forms in cultured human dermal fibroblasts is resulted from dominance of XYLT2 activity, which acts only at S42 on BGN core protein, caused by UV-mediated stronger reduction of XYLT1.

Purine metabolizing enzyme activities in radiosensitive tissues of mice after sublethal whole-body irradiation.

The activities of adenosine deaminase (ADA) and purine nucleoside phosphorylase (PNP) were determined between days 1-14 in the spleen, thymus and femoral bone marrow of mice subjected to whole-body gama irradiation with a dose of 5.5 Gy. In control animals, the highest activity of ADA (as related to 10(6) cells) was recorded in the thymus (58.9 pmol.s-1), the lowest one in the femur (34.8 pmol.s-1), the PNP activity was the lowest in the thymus (14.5 pmol.s-1) and the highest in the femur (96.0 pmol.s-1). In the spleen, an elevation of ADA activity (up to 379%) was observed during the first postirradiation days; PNP activity was reduced (to 58%) on postirradiation day 3, followed by the return and even elevation on day 14 (265%). In the thymus, a parallel reduction of the activities of both enzymes appeared during the first postirradiation days, with a subsequent increase during the regeneration phase. In the femoral bone marrow, ADA and PNP activities were increased on postirradiation day 1 (275% and 201%, respectively). Reference is made to the possible relationship between the observed characteristic changes in activities and the degree of damage and/or renewal of cell population in the hemopoietic tissues after irradiation.