The nucleus pulposus is an aggrecan-rich, avascular tissue that permits the intervertebral disc to resist compressive loads. In the disc, nucleus pulposus cells express HIF-1 transcription factor that responds to oxygen tension and regulates glycolysis. The goal of the present study was to examine the importance of HIF-1 in rat nucleus pulposus cells and to probe the function of this transcription factor in terms of regulating aggrecan gene expression. We found that HIF-1 protein levels and mRNA stability were similar at 20% and 2% oxygen; there was a small, but significant increase in HIF-1 transactivation domain activity in hypoxia. With respect to HIF-1 target genes, GAPDH, GLUT-1 and GLUT-3, mRNA and protein levels were independent of the oxygen tension. Other than a modest increase in PFKFB reporter activity, the oxemic state did not change GAPDH, GLUT-1 and GLUT-3 promoter activities. Treatment of cells with 2-DOG, a glycolytic inhibitor, resulted in a significant suppression in ATP synthesis in normoxia, while treatment with mitochondrial inhibitors, did not affect ATP production and cell viability. However, measurement of the rate of fatty acid oxidation indicated that these cells contained functioning mitochondria. Finally, we showed that when HIF-1 was suppressed, irrespective of the oxemic state, there was a partial loss of aggrecan expression and promoter activity. Moreover, when cells were treated with 2-DOG, there was inhibition in aggrecan promoter activity. Results of this study indicate that oxygen-independent stabilization of HIF-1 in nucleus pulposus cells is a metabolic adaptation that drives glycolysis and aggrecan expression.