Indoleamine dioxygenase and tryptophan dioxygenase activities are regulated through control of cell heme allocation by nitric oxide

“…In all cases examined so far, there is a relatively narrow window of very low NO concentration that stimulates cell heme allocation, and as the NO concentration goes above this range it increasingly has a negative impact that ultimately overcomes the positive effect and even can lead to a net loss of heme from the heme proteins. [ 8,22,31,37 ] In all cases tested, the NO‐driven heme allocations require the participation of GAPDH and Hsp90, indicating that the NO‐driven mechanism involves the same cellular machinery as does normal heme allocation. One mechanism (among several) for NO‐driven cell heme allocation that is consistent with the results to date is shown in Figure 2, using sGC as an example heme protein.…”

“…Trp dioxygenase Cells and tissues [7,8,14,15] Indoleamine dioxygenase Cells [7,8,60] Hemoglobin α, β, γ Cells and tissues [23,37,71] Myoglobin Cells and tissues [23,37,71] Cytochrome P450 Cells and tissues [59] Myeloperoxidase Cells [37] NADPH oxidase 5 Cells [72] Ascorbate peroxidase a Cells [13] Horseradish peroxidase a Cells [13] a Plant enzymes were expressed in mammalian cells.…”

“…[39] The different impacts of the NO synthase isoforms on cell heme allocation as described above have been borne out in cell culture experiments. [8,22] Several fascinating questions arise within this context:…”

“…The easiest and oldest method is to measure the heme-dependent functional activity of a given heme protein of interest in a biological sample in the absence or presence of added heme. This has been used for example to indicate the percentage heme saturation in TDO, IDO-1, sGC, and cytochromes P450 in homogenates of various cells or tissues, [8,[14][15][16]59,60] but its usefulness depends on the ability of the given heme protein of interest to be amenable to in vitro heme reconstitution. Another way would be to determine the heme levels in the heme proteins by mass spectrometry.…”

A natural heme deficiency exists in biology that allows nitric oxide to control heme protein functions by regulating cellular heme distribution

“…In all cases examined so far, there is a relatively narrow window of very low NO concentration that stimulates cell heme allocation, and as the NO concentration goes above this range it increasingly has a negative impact that ultimately overcomes the positive effect and even can lead to a net loss of heme from the heme proteins. [ 8,22,31,37 ] In all cases tested, the NO‐driven heme allocations require the participation of GAPDH and Hsp90, indicating that the NO‐driven mechanism involves the same cellular machinery as does normal heme allocation. One mechanism (among several) for NO‐driven cell heme allocation that is consistent with the results to date is shown in Figure 2, using sGC as an example heme protein.…”

“…Trp dioxygenase Cells and tissues [7,8,14,15] Indoleamine dioxygenase Cells [7,8,60] Hemoglobin α, β, γ Cells and tissues [23,37,71] Myoglobin Cells and tissues [23,37,71] Cytochrome P450 Cells and tissues [59] Myeloperoxidase Cells [37] NADPH oxidase 5 Cells [72] Ascorbate peroxidase a Cells [13] Horseradish peroxidase a Cells [13] a Plant enzymes were expressed in mammalian cells.…”

“…[39] The different impacts of the NO synthase isoforms on cell heme allocation as described above have been borne out in cell culture experiments. [8,22] Several fascinating questions arise within this context:…”

“…The easiest and oldest method is to measure the heme-dependent functional activity of a given heme protein of interest in a biological sample in the absence or presence of added heme. This has been used for example to indicate the percentage heme saturation in TDO, IDO-1, sGC, and cytochromes P450 in homogenates of various cells or tissues, [8,[14][15][16]59,60] but its usefulness depends on the ability of the given heme protein of interest to be amenable to in vitro heme reconstitution. Another way would be to determine the heme levels in the heme proteins by mass spectrometry.…”

A natural heme deficiency exists in biology that allows nitric oxide to control heme protein functions by regulating cellular heme distribution

“…Specifically, relatively low level NO exposure promoted cell heme allocation and thus caused the heme content of several heme proteins to increase by a process that also depended on GAPDH and Hsp90. In contrast, at higher NO exposure levels the promoting effect of NO was quickly lost and instead it widely prevented cellular heme allocation to proteins (17,18) and even caused some to lose their heme (17). NO displayed this hormetic effect when it was released from small molecule NO donors or when it was naturally generated in cells via NO synthases (17,(19)(20)(21).…”

Visualizing Mitochondrial Heme Flow through GAPDH to Targets in Living Cells and its Regulation by NO

Heme metabolism in nonerythroid cells