Identification of four alternatively spliced transcripts of the Ucma/GRP gene, encoding a new Gla-containing protein.

The Ucma protein (Upper zone of growth plate and cartilage matrix associated protein) has recently been described as a novel secretory protein mainly expressed in cartilage and also as a novel vitamin-K-dependent protein named GRP (Gla-rich protein). This protein has the highest Gla content of any protein known to date. In this article, we identify four alternatively spliced variants of Ucma/GRP gene transcripts in mouse chondrocytes. We show that the expression of all four isoforms is associated with the early stages of chondrogenesis. The Ucma/GRP gene encodes four proteins named Ucma/GRP-F1, -F2, -F3, and -F4, which differ by exon 2, exon 4, or both. Among them, only Ucma/GRP-F1 and -F3 were secreted into the culture medium of transfected chondrocytes, while Ucma/GRP-F2 and -F4 accumulated in the cells. Using HeLa cells or freshly isolated embryonic mouse chondrocytes transfected with enhanced green fluorescent protein fusions, microscopy analysis revealed that Ucma/GRP-F1 and -F3 were localized in the Golgi complex, whereas Ucma/GRP-F2 and -F4 formed aggregates. This aggregation was microtubule-dependent since disruption of microtubules with nocodazole reduced Ucma/GRP-F2 and -F4 aggregation in a reversible manner. Using biochemical fractionation and Western blot analysis, Ucma/GRP-F1 and -F3 isoforms were detected in the soluble fraction while Ucma/GRP-F2 and -F4 were found in an insoluble-enriched fraction. We conclude that the co-expression of soluble and insoluble isoforms also Gla-rich and Gla-deleted isoforms may be finely tuned. Imbalance in isoform expression may therefore be involved in skeletal pathology.

Increased adipogenesis in cultured embryonic chondrocytes and in adult bone marrow of dominant negative Erg transgenic mice.

In monolayer culture, primary articular chondrocytes have an intrinsic tendency to lose their phenotype during expansion. The molecular events underlying this chondrocyte dedifferentiation are still largely unknown. Several transcription factors are important for chondrocyte differentiation. The Ets transcription factor family may be involved in skeletal development. One family member, the Erg gene, is mainly expressed during cartilage formation. To further investigate the potential role of Erg in the maintenance of the chondrocyte phenotype, we isolated and cultured chondrocytes from the rib cartilage of embryos of transgenic mice that express a dominant negative form of Erg (DN-Erg) during cartilage formation. DN-Erg expression in chondrocytes cultured for up to 20 days did not affect the early dedifferentiation usually observed in cultured chondrocytes. However, lipid droplets accumulated in DN-Erg chondrocytes, suggesting adipocyte emergence. Transcriptomic analysis using a DNA microarray, validated by quantitative RT-PCR, revealed strong differential gene expression, with a decrease in chondrogenesis-related markers and an increase in adipogenesis-related gene expression in cultured DN-Erg chondrocytes. These results indicate that Erg is involved in either maintaining the chondrogenic phenotype in vitro or in cell fate orientation. Along with the in vitro studies, we compared adipocyte presence in wild-type and transgenic mice skeletons. Histological investigations revealed an increase in the number of adipocytes in the bone marrow of adult DN-Erg mice even though no adipocytes were detected in embryonic cartilage or bone. These findings suggest that the Ets transcription factor family may contribute to the homeostatic balance in skeleton cell plasticity.