The impact of N-nitrosomelatonin as nitric oxide donor in cell culture experiments.

N-nitrosomelatonin (NOMela) is well-known for its capabilities of transnitrosating nucleophiles such as thiols and ascorbate, thereby generating nitric oxide (NO)-releasing compounds. It is unknown, however, whether NOMela can be successfully applied as a precursor of NO in a complex biological environment like a cell culture system. NO donors may be useful to induce the transcription factor hypoxia inducible factor 1 (HIF-1), which coordinates the protection of cells and tissues from the lack of oxygen (hypoxia). In this study, the effects of NOMela in an in vitro cell-free assay [NO-release, inhibition of prolylhydroxylase1 (PHD1)] and in living cells (upregulation of HIF-1, reduction of HIF-1 hydroxylation, upregulation of the HIF-1-target gene PHD2) were compared with those of the frequently applied NO donor S-nitrosoglutathione (GSNO) under normoxic and hypoxic conditions. In contrast to GSNO, NOMela released NO in a predictable manner and this release in vitro was found to be independent of the composition of the buffer system. The NOMela-mediated effects in oxygenated cells were in all cases comparable to the hypoxic response, whereas unphysiological strong effects were observed with GSNO. Probably, because of the antioxidative power of the NOMela-dependent formation of melatonin, cells were completely protected against the attack of reactive nitrogen oxygen species, which are generated by autoxidation of NO. In conclusion, NOMela had to be an excellent NO precursor for cells in culture and potentially tissues.

Nuclear oxygen sensing: induction of endogenous prolyl-hydroxylase 2 activity by hypoxia and nitric oxide.

The abundance of the transcription factor hypoxia-inducible factor is regulated through hydroxylation of its alpha-subunits by a family of prolyl-hydroxylases (PHD1-3). Enzymatic activity of these PHDs is O2-dependent, which enables PHDs to act as cellular O2 sensor enzymes. Herein we studied endogenous PHD activity that was induced in cells grown under hypoxia or in the presence of nitric oxide. Under such conditions nuclear extracts contained much higher PHD activity than the respective cytoplasmic extracts. Although PHD1-3 were abundant in both compartments, knockdown experiments for each isoenzyme revealed that nuclear PHD activity was only due to PHD2. Maximal PHD2 activity was found between 120 and 210 microm O2. PHD2 activity was strongly decreased below 100 microm O2 with a half-maximum activity at 53 +/- 13 microm O2 for the cytosolic and 54 +/- 10 microm O2 for nuclear PHD2 matching the physiological O2 concentration within most cells. Our data suggest a role for PHD2 as a decisive oxygen sensor of the hypoxia-inducible factor degradation pathway within the cell nucleus.

Nitric oxide modulates oxygen sensing by hypoxia-inducible factor 1-dependent induction of prolyl hydroxylase 2.

The transcription factor complex hypoxia-inducible factor 1 (HIF-1) plays a crucial role in cellular adaptation to low oxygen availability. O(2)-dependent HIF prolyl hydroxylases (PHDs) modify HIF-1alpha, which is sent to proteasomal degradation under normoxia. Reduced activity of PHDs under hypoxia allows stabilization of HIF-1alpha and induction of HIF-1 target gene expression. Like hypoxia, nitric oxide (NO) was found to inhibit normoxic PHD activity leading to HIF-1alpha accumulation. In contrast under hypoxia, NO reduced HIF-1alpha levels due to enhanced PHD activity. Herein, we studied the role of NO in regulating PHD expression and the consequences thereof for HIF-1alpha degradation. We report a biphasic response of HIF-1alpha and PHDs to NO treatment both under normoxia and hypoxia. In the early phase, NO inhibits PHD activity that leads to HIF-1alpha accumulation, whereas in the late phase, increased PHD levels reduce HIF-1alpha. NO induces expression of PHD2 and -3 mRNA and protein under normoxia and hypoxia in a strictly HIF-1-dependent manner. NO-treated cells with elevated PHD levels displayed delayed HIF-1alpha accumulation and accelerated degradation of HIF-1alpha upon reoxygenation. Subsequent suppression of PHD2 and -3 expression using small interfering RNA revealed that PHD2 was exclusively responsible for regulating HIF-1alpha degradation under NO treatment. In conclusion, we identified the induction of PHD2 as an underlying mechanism of NO-induced degradation of HIF-1alpha.

Chelation of cellular calcium modulates hypoxia-inducible gene expression through activation of hypoxia-inducible factor-1alpha.

Hypoxia-Inducible Factor-1 (HIF-1) is the key transcription factor in control of the expression of hypoxia-inducible genes needed by cells to adapt to decreased oxygen availability. Herein, we investigated the HIF-1alpha-mediated gene expression of carbonic anhydrase 9 (CA9) in response to hypoxia and changes of intracellular calcium levels in the neuroblastoma cell line SH-SY5Y. Decreasing the intracellular calcium level by BAPTA (1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid) induced HIF-1alpha nuclear accumulation and enhanced HIF-1 DNA binding within 1 h of incubation. Like hypoxia, BAPTA stimulated HIF-1-dependent transcription by increasing the activity of the C-terminal transactivation domain of HIF-1alpha and greatly enhanced expression of the HIF-1 target gene CA9. Detailed analysis of HIF-1alpha accumulation revealed that BAPTA attenuated the interaction of HIF-1alpha with von-Hippel-Lindau protein thus decreasing proteasomal degradation of HIF-1alpha. Knock down of HIF-1alpha mRNA and protein by small interference RNA for HIF-1alpha revealed that both hypoxia and the BAPTA-induced gene expression of CA9 were strictly dependent on HIF-1alpha. In contrast, elevation of cytosolic calcium level by thapsigargin reduced the BAPTA-mediated effects. Measurements of intracellular calcium under hypoxia revealed a change in the cellular calcium distribution. BAPTA-dependent induction of HIF-1 activity was not caused by its in vitro capability to chelate iron. Instead, effective chelation of cellular calcium caused the accumulation of HIF-1alpha protein through inhibition of HIF-prolyl hydroxylases and activated HIF-1-dependent gene expression under normoxic conditions.