The FixL proteins are biological oxygen sensors that restrict the expression of specific genes to hypoxic conditions. FixL's oxygen-detecting domain is a heme binding region that controls the activity of an attached histidine kinase. The FixL switch is regulated by binding of oxygen and other strong-field ligands. In the absence of bound ligand, the heme domain permits kinase activity. In the presence of bound ligand, this domain turns off kinase activity. Comparison of the structures of two forms of the Bradyrhizobium japonicum FixL heme domain, one in the ''on'' state without bound ligand and one in the ''off'' state with bound cyanide, reveals a mechanism of regulation by a heme that is distinct from the classical hemoglobin models. The close structural resemblance of the FixL heme domain to the photoactive yellow protein confirms the existence of a PAS structural motif but reveals the presence of an alternative regulatory gateway.
Neuronal PAS domain protein 2 (NPAS2) is a mammalian transcription factor that binds DNA as an obligate dimeric partner of BMAL1 and is implicated in the regulation of circadian rhythm. Here we show that both PAS domains of NPAS2 bind heme as a prosthetic group and that the heme status controls DNA binding in vitro. NPAS2-BMAL1 heterodimers, existing in either the apo (heme-free) or holo (heme-loaded) state, bound DNA avidly under favorably reducing ratios of the reduced and oxidized forms of nicotinamide adenine dinucleotide phosphate. Low micromolar concentrations of carbon monoxide inhibited the DNA binding activity of holo-NPAS2 but not that of apo-NPAS2. Upon exposure to carbon monoxide, inactive BMAL1 homodimers were formed at the expense of NPAS2-BMAL1 heterodimers. These results indicate that the heterodimerization of NPAS2, and presumably the expression of its target genes, are regulated by a gas through the heme-based sensor described here.
A direct sensor of O(2), the Dos protein, has been found in Escherichia coli. Previously, the only biological sensors known to respond to O(2) by direct and reversible binding were the FixL proteins of Rhizobia. A heme-binding region in Dos is 60% homologous to the O(2)-sensing PAS domain of the FixL protein, but the remainder of Dos does not resemble FixL. Specifically, the C-terminal domain of Dos, presumed to be a regulatory partner that couples to its heme-binding domain, is not a histidine kinase but more closely resembles a phosphodiesterase. The absorption spectra of Dos indicate that both axial positions of the heme iron are coordinated to side chains of the protein. Nevertheless, O(2) and CO bind to Dos with K(d) values of 13 and 10 microM, respectively, indicating a strong discrimination against CO binding. Association rate constants for binding of O(2) (3 mM(-)(1) s(-)(1)), CO (1 mM(-)(1) s(-)(1)) and even NO (2 mM(-)(1) s(-)(1)) are extraordinarily low and very similar. Displacement of an endogenous ligand, probably Met 95, from the heme iron in Dos triggers a conformational change that alters the activity of the enzymatic domain. This sensing mechanism differs from that of FixL but resembles that of the CO sensor CooA of Rhodospirillum rubrum. Overall the results provide evidence for a heme-binding subgroup of PAS-domain proteins whose working range, signaling mechanisms, and regulatory partners can vary considerably.
FixL's are chimeric heme protein kinases from symbiotic nitrogen-fixing Rhizobia. We have overexpressed three FixL variants in Escherichia coli. Bradyrhizobium japonicum FixL, a soluble dimeric protein, is the first full-length FixL to be purified. The other two proteins are soluble truncations of Rhizobium meliloti FixL, which is a membrane protein. One contains both heme and kinase domains and is dimeric; the other has only the heme domain and is monomeric. We find that all the FixL's bind oxygen and carbon monoxide non-cooperatively, with very low affinities due entirely to slow association rates. FixL P50's for oxygen are 17-76 mmHg. FixL's may sense nitric oxide and carbon monoxide in addition to oxygen, especially at the low oxygen pressures encountered in vivo. Autoxidation rates are about 50 times faster than that of sperm whale myoglobin. The carbon monoxide affinity of FixL's is about 300 times lower than that of myoglobin, resulting in the unusually low values of 7.5-17 for the partition constant, M = P50(O2)/P50(CO), between carbon monoxide and oxygen. Met-FixL's have their Soret absorption maximum at 395 nm instead of the typical 408 nm and a steep hydroxymet transition at pH > or = 9.3; these properties indicate a pentacoordinated high-spin ferric heme and suggest a sterically hindered hydrophobic heme pocket lacking a distal (E7) histidine. FixL is the first member of a new class of heme proteins, the heme-based sensors, distinct from the oxygen carriers and electron transporters. We expect that some of the novel properties of FixL will be characteristic of the class.
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