Quarto R, Campanile G, Cancedda R, Dozin B
Laboratorio Differenziamento Cellulare, Istituto Nazionale per la Ricerca sul Cancro, Genova, Italy.
J Cell Biol. 1992 Nov;119(4):989-95. doi: 10.1083/jcb.119.4.989.
Chondrocytes from chicken embryo tibia can be maintained in culture as adherent cells in Coon's modified Ham's F-12 medium supplemented with 10% FCS. In this condition, they dedifferentiate, losing type II collagen expression in favor of type I collagen synthesis. Their differentiation to hypertrophy can be obtained by transferring them to suspension culture. Differentiation is evidenced by the shift from type I to type II and type IX collagen synthesis and the following predominant expression of type X collagen, all markers of specific stages of the differentiation process. To identify the factors required for differentiation, we developed a serum-free culture system where only the addition of triiodothyronine (T3; 10(-11) M), insulin (60 ng/ml), and dexamethasone (10(-9) M) to the F-12 medium was sufficient to obtain hypertrophic chondrocytes. In this hormonal context, chondrocytes display the same changes in the pattern of protein synthesis as described above. For proper and complete cell maturation, T3 and insulin concentrations cannot be modified. Insulin cannot be substituted by insulin-like growth factor-I, but dexamethasone concentration can be decreased to 10(-12) M without chondrogenesis being impaired. In the latter case, the expression of type X collagen and its mRNA are inversely proportional to dexamethasone concentration. When ascorbic acid is added to the hormone-supplemented medium, differentiating chondrocytes organize their matrix leading to a cartilage-like structure with hypertrophic chondrocytes embedded in lacunae. However, this structure does not present detectable calcification, at variance with control cultures maintained in FCS. Accordingly, in the presence of the hormone mixture, the differentiating chondrocytes have low levels of alkaline phosphatase activity. This report indicates that T3 and insulin are primary factors involved in the onset and progression of chondrogenesis, while dexamethasone supports cell viability and modulates some differentiated functions.
鸡胚胫骨软骨细胞可作为贴壁细胞,在添加10%胎牛血清的库恩改良哈姆F - 12培养基中进行培养。在此条件下,它们会去分化,失去II型胶原蛋白表达,转而合成I型胶原蛋白。将它们转移至悬浮培养可使其分化为肥大细胞。从I型胶原蛋白合成转变为II型和IX型胶原蛋白合成,随后X型胶原蛋白占主导性表达,这些都证明了分化过程,而这些都是分化过程特定阶段的标志物。为了确定分化所需的因子,我们开发了一种无血清培养系统,在F - 12培养基中仅添加三碘甲状腺原氨酸(T3;10⁻¹¹ M)、胰岛素(60 ng/ml)和地塞米松(10⁻⁹ M)就足以获得肥大软骨细胞。在此激素环境下,软骨细胞在蛋白质合成模式上表现出与上述相同的变化。为实现细胞正常且完全成熟,T3和胰岛素浓度不能改变。胰岛素样生长因子-I不能替代胰岛素,但地塞米松浓度可降至10⁻¹² M而不影响软骨形成。在后一种情况下,X型胶原蛋白及其mRNA的表达与地塞米松浓度呈反比。当向添加激素的培养基中添加抗坏血酸时,分化的软骨细胞会组织其基质,形成类似软骨的结构,肥大软骨细胞嵌入腔隙中。然而,与在胎牛血清中培养的对照培养物不同,该结构未出现可检测到的钙化。因此,在激素混合物存在的情况下,分化的软骨细胞碱性磷酸酶活性水平较低。本报告表明,T3和胰岛素是软骨形成起始和进展过程中的主要因子,而地塞米松支持细胞活力并调节一些分化功能。