Thyroid Hormone Inhibits Growth and Stimulates Terminal Differentiation of Epiphyseal Growth Plate Chondrocytes

Abstract

As a continuation of our studies on mineralization in epiphyseal growth plate (GP) chondrocyte cultures, the effects of tri-iodothyronine (T₃) in both β-glycerophosphate-containing, serum-free (HL-1) and β-glycerophosphate-free, serum-containing medium (DATP5) were studied. The GP cells responded to T₃ in a serum-, stage-, and dosage-dependent manner. Added at graded levels (0.1–10.0 nM) to preconfluent cultures (from day 7) in both HL-1 and DATP5, T₃ caused progressive decreases in protein, collagen, and DNA synthesis but increased mineral deposition. In postconfluent cultures, these effects of T₃ were generally muted. In preconfluent cultures, proteoglycan (PG) levels were not significantly affected in DATP5, although in HL-1 they were decreased by ∼50%. In postconfluent cultures, T₃ increased PG levels in DATP5 but had no effect in HL-1. In HL-1, alkaline phosphatase (ALP) activity was progressively increased by 200–500% in both pre- and postconfluent cultures. In DATP5 in preconfluent cultures, T₃ initially stimulated but later suppressed ALP; in postconfluent cultures, T₃ also transiently increased ALP but did not suppress activity upon longer exposure. The inhibitory effects of T₃ on protein, PG, and DNA levels of GP chondrocytes suggest that in vivo its effects on bone growth must occur primarily after cellular proliferation. Apparently by binding to the 50 kDa thyroxine-binding globulin, which cannot penetrate the PG barrier, accessibility of T₃ to GP chondrocytes is limited until the time of vascular penetration when its stimulatory effects on ALP and mineral deposition become critical for continued bone development.