The hypoxia inducible factor-1 (HIF-1), a heterodimer composed of HIF-1alpha and HIF-1beta, is activated in response to low oxygen tension and serves as the master regulator for cells to adapt to hypoxia. HIF-1 is usually considered to be regulated via degradation of its a-subunit. Recent findings, however, point to the existence of alternative mechanisms of HIF-1 regulation which appear to be important for down-regulating HIF-1 under prolonged and severe oxygen depletion. The aims of my Ph.D. thesis, therefore, were to further elucidate mechanisms involved in such down-regulation of HIF-1. The first part of the thesis addresses the impact of the severity and duration of oxygen depletion on HIF-1alpha protein accumulation and HIF-1 transcriptional activity. A special focus was put on the influence of the transcription factor p53 on HIF-1. I found that p53 only accumulates under prolonged anoxia (but not hypoxia), thus limiting its influence on HIF-1 to severe hypoxic conditions. At low expression levels, p53 inhibits HIF-1 transactivity. I attributed this effect to a competition between p53 and HIF-1alpha for binding to the transcriptional co-factor p300, since p300 overexpression reverses this inhibition. This assumption is corroborated by competitive binding of IVTT-generated p53 and HIF-1alpha to the CH1-domain of p300 in vitro. High p53 expression, on the other hand, affects HIF-1alpha protein negatively, i.e., p53 provokes pVHL-independent degradation of HIF-1alpha. Therefore, I conclude that low p53 expression attenuates HIF-1 transactivation by competing for p300, while high p53 expression negatively affects HIF-1alpha protein, thereby eliminating HIF-1 transactivity. Thus, once p53 becomes activated under prolonged anoxia, it contributes to terminating HIF-1 responses. In the second part of my study, I intended to further characterize the effects induced by prolonged periods of low oxygen, i.e., hypoxia, as compared to anoxia, with respect to alterations in HIF-1alpha mRNA. Prolonged anoxia, but not hypoxia, showed pronounced effects on HIF-1alpha mRNA. Long-term anoxia induced destabilization of HIF-1alpha mRNA, which manifests itself in a dramatic reduction of the half-life. The mechanistic background points to natural anti-sense HIF-1alpha mRNA, which is induced in a HIF-1-dependent manner, and additional factors, which most likely influence HIF-1alpha mRNA indirectly via anti-sense HIF-1alpha mRNA mediated trans-effects. In summary, the data provide new information concerning the impact of p53 on HIF-1, which might be of importance for the decision between pro- and anti-apoptotic mechanisms depending upon the severity and duration of hypoxia. Furthermore, the results of this project give further insights into a novel mechanism of HIF-1 regulation, namely mRNA down-regulation under prolonged anoxic incubations. These mechanisms appear to be activated only in response to prolonged anoxia, but not to hypoxia. These considerations regarding HIF-1 regulation should be taken into account when prolonged incubations to hypoxic or anoxic conditions are analyzed at the level of HIF-1 stability regulation.