Masahiko Kinosaki

Transgenic mice overexpressing soluble osteoclast differentiation factor (sODF) exhibit severe osteoporosis

Abstract. Osteoclast differentiation factor, ODF, also called RANKL, TRANCE, or OPGL, is a key molecule for osteoclast differentiation and activation, and is thought to act as a membrane-associated molecule in bone remodeling. Recent study suggested that soluble ODF (sODF) released from T cells also has some roles in bone resorption. To investigate the physiological and pathological function of sODF, we generated two types of transgenic mice overexpressing sODF. Mice overexpressing sODF ubiquitously from the early developmental stage died at the late fetal stage. The other type of mice, expressing sODF only in the liver after birth, grew to maturity with normal body size and weight. However, they exhibited a marked decrease in bone mineral density with aging compared with their non-transgenic littermates, and in addition, the strength of their femurs was extremely reduced. Histological analysis showed that the trabecular bone mass was decreased at 6 weeks of age and was sparse at age 3–4 months. The number of osteoclasts was significantly increased, while the number of osteoblasts was not altered on the surface of young trabecular bone. These results indicate that excessive production of sODF causes osteoporosis by accelerated osteoclastogenesis. The transgenic mouse overexpressing sODF in the liver could serve as a useful animal model for studying bone remodeling and evaluating therapeutic agents for osteoporosis.

IDENTIFICATION OF HEPARIN-BINDING STRETCHES OF A NATURALLY OCCURRING DELETED VARIANT OF HEPATOCYTE GROWTH FACTOR (DHGF)

A deleted variant of hepatocyte growth factor (dHGF) is a naturally occurring major variant of HGF, which lacks five consecutive amino acid residues in the first kringle domain. While both HGF and dHGF bind to heparin, the residues involved in the binding to heparin have not been identified in either protein. To identify the residues involved in the binding, we made a series of dHGF mutants in which basic residues in the N-terminal and the first kringle domains were replaced with alanine residue. The analysis of heparin-binding ability revealed that three stretches, 42RCTRNK in the hairpin loop structure, and 2RKRR and 27KIKTKK in the N-terminal basic region, are involved in the binding. Alanine substitution of each basic residue except 3K and 27K in the stretches reduced the heparin-binding ability of dHGF, and the decrease was additive. Conversely, lysine substitution of 37D, 38Q or 64Q in the N-terminal domain increased heparin-binding ability. These results suggest that stretches distant from each other in the primary structure come into close proximity when the polypeptide folds into protein, and form a heparin-binding site with clusters of basic residues.

Bone morphogenetic protein 4 and Smad1 mediate extracellular matrix production in the development of diabetic nephropathy

Diabetic nephropathy is the leading cause of end-stage renal disease. It is pathologically characterized by the accumulation of extracellular matrix in the mesangium, of which the main component is α1/α2 type IV collagen (Col4a1/a2). Recently, we identified Smad1 as a direct regulator of Col4a1/a2 under diabetic conditions in vitro. Here, we demonstrate that Smad1 plays a key role in diabetic nephropathy through bone morphogenetic protein 4 (BMP4) in vivo. Smad1-overexpressing mice (Smad1-Tg) were established, and diabetes was induced by streptozotocin. Nondiabetic Smad1-Tg did not exhibit histological changes in the kidney; however, the induction of diabetes resulted in an ∼1.5-fold greater mesangial expansion, consistent with an increase in glomerular phosphorylated Smad1. To address regulatory factors of Smad1, we determined that BMP4 and its receptor are increased in diabetic glomeruli and that diabetic Smad1-Tg and wild-type mice treated with a BMP4-neutralizing antibody exhibit decreased Smad1 phosphorylation and ∼40% less mesangial expansion than those treated with control IgG. Furthermore, heterozygous Smad1 knockout mice exhibit attenuated mesangial expansion in the diabetic condition. The data indicate that BMP4/Smad1 signaling is a critical cascade for the progression of mesangial expansion and that blocking this signal could be a novel therapeutic strategy for diabetic nephropathy.