The mammalian D-type cyclins promote progression through a G1 checkpoint by phosphorylating the retinoblastoma protein (pRB), and can contribute to oncogenesis via their deregulated expression achieved through gene amplification, chromosomal rearrangement, or retroviral integration. We now report a novel mechanism of tumour-associated D-cyclin over-abundance, resulting from enhanced protein stability. In two human cell lines established from a single uterine sarcoma biopsy, pRB-positive SK-UT-1B and pRB-deficient SK-UT-1, aberrant accumulation of functional cyclins D1, and D2 and D3 occurred in the absence of gene amplification and/or elevated mRNA expression. The abundance of D-cyclin proteins remained elevated throughout the cell cycle, and pulse-chase experiments revealed six to 10-fold prolongation of their protein half-lives as compared with either diploid fibroblasts or control U-2-OS sarcoma cells. These results point to a critical regulatory role of D-type cyclin turnover, and contribute to refinement of current views of the role played by the cyclin D-CDK-p16-pRB pathway in cell cycle control and tumorigenesis.