Redox-dependent Ligand Switching in a Sensory Heme-binding GAF Domain of the Cyanobacterium Nostoc sp. PCC7120.

The genome of the cyanobacterium Nostoc sp. PCC7120 carries three genes (all4978, all7016, and alr7522) encoding putative heme-binding GAF (cGMP-specific phosphodiesterases, adenylyl cyclases, and FhlA) proteins that were annotated as transcriptional regulators. They are composed of an N-terminal cofactor domain and a C-terminal helix-turn-helix motif. All4978 showed the highest affinity for protoheme binding. The heme binding capability of All7016 was moderate, and Alr7522 did not bind heme at all. The "as isolated" form of All4978, identified by Soret band (λmax = 427 nm), was assigned by electronic absorption, EPR, and resonance Raman spectroscopy as a hexa-coordinated low spin Fe(III) heme with a distal cysteine ligand (absorption of δ-band around 360 nm). The protoheme cofactor is noncovalently incorporated. Reduction of the heme could be accomplished by chemically using sodium dithionite and electrospectrochemically; this latter method yielded remarkably low midpoint potentials of -445 and -453 mV (following Soret and α-band absorption changes, respectively). The reduced form of the heme (Fe(II) state) binds both NO and CO. Cysteine coordination of the as isolated Fe(III) protein is unambiguous, but interestingly, the reduced heme instead displays spectral features indicative of histidine coordination. Cys-His ligand switches have been reported as putative signaling mechanisms in other heme-binding proteins; however, these novel cyanobacterial proteins are the first where such a ligand-switch mechanism has been observed in a GAF domain. DNA binding of the helix-turn-helix domain was investigated using a DNA sequence motif from its own promoter region. Formation of a protein-DNA complex preferentially formed in ferric state of the protein.

Nitrite dismutase reaction mechanism: kinetic and spectroscopic investigation of the interaction between nitrophorin and nitrite.

Nitrite is an important metabolite in the physiological pathways of NO and other nitrogen oxides in both enzymatic and nonenzymatic reactions. The ferric heme b protein nitrophorin 4 (NP4) is capable of catalyzing nitrite disproportionation at neutral pH, producing NO. Here we attempt to resolve its disproportionation mechanism. Isothermal titration calorimetry of a gallium(III) derivative of NP4 demonstrates that the heme iron coordinates the first substrate nitrite. Contrary to previous low-temperature EPR measurements, which assigned the NP4-nitrite complex electronic configuration solely to a low-spin (S = 1/2) species, electronic absorption and resonance Raman spectroscopy presented here demonstrate that the NP4-NO2(-) cofactor exists in a high-spin/low-spin equilibrium of 7:3 which is in fast exchange in solution. Spin-state interchange is taken as evidence for dynamic NO2(-) coordination, with the high-spin configuration (S = 5/2) representing the reactive species. Subsequent kinetic measurements reveal that the dismutation reaction proceeds in two discrete steps and identify an {FeNO}(7) intermediate species. The first reaction step, generating the {FeNO}(7) intermediate, represents an oxygen atom transfer from the iron bound nitrite to a second nitrite molecule in the protein pocket. In the second step this intermediate reduces a third nitrite substrate yielding two NO molecules. A nearby aspartic acid residue side-chain transiently stores protons required for the reaction, which is crucial for NPs' function as nitrite dismutase.

A caged substrate peptide for matrix metalloproteinases.

Based on the widely applied fluorogenic peptide FS-6 (Mca-Lys-Pro-Leu-Gly-Leu-Dpa-Ala-Arg-NH2; Mca = methoxycoumarin-4-acetyl; Dpa = N-3-(2,4-dinitrophenyl)l-α,ß-diaminopropionyl) a caged substrate peptide Ac-Lys-Pro-Leu-Gly-Lys*-Lys-Ala-Arg-NH2 (*, position of the cage group) for matrix metalloproteinases was synthesized and characterized. The synthesis implies the modification of a carbamidated lysine side-chain amine with a photocleavable 2-nitrobenzyl group. Mass spectrometry upon UV irradiation demonstrated the complete photolytic cleavage of the protecting group. Time-resolved laser-flash photolysis at 355 nm in combination with transient absorption spectroscopy determined the biphasic decomposition with τa = 171 ± 3 ms (79%) and τb = 2.9 ± 0.2 ms (21%) at pH 6.0 of the photo induced release of the 2-nitrobenzyl group. The recombinantly expressed catalytic domain of human membrane type I matrix metalloproteinase (MT1-MMP or MMP-14) was used to determine the hydrolysis efficiency of the caged peptide before and after photolysis. It turned out that the cage group sufficiently shields the peptide from peptidase activity, which can be thus controlled by UV light.

Kinetics and computational studies of ligand migration in nitrophorin 7 and its Δ1-3 mutant.

Nitrophorins (NPs) are nitric oxide (NO)-carrying heme proteins found in the saliva of the blood-sucking insect Rhodnius prolixus. Though NP7 exhibits a large sequence resemblance with other NPs, two major differential features are the ability to interact with negatively charged cell surfaces and the presence of a specific N-terminus composed of three extra residues (Leu1-Pro2-Gly3). The aim of this study is to examine the influence of the N-terminus on the ligand binding, and the topological features of inner cavities in closed and open states of NP7, which can be associated to the protein structure at low and high pH, respectively. Laser flash photolysis measurements of the CO rebinding kinetics to NP7 and its variant NP7(Δ1-3), which lacks the three extra residues at the N-terminus, exhibit a similar pattern and support the existence of a common kinetic mechanism for ligand migration and binding. This is supported by the existence of a common topology of inner cavities, which consists of two docking sites in the heme pocket and a secondary site at the back of the protein. The ligand exchange between these cavities is facilitated by an additional site, which can be transiently occupied by the ligand in NP7, although it is absent in NP4. These features provide a basis to explain the enhanced internal gas hosting capacity found experimentally in NP7 and the absence of ligand rebinding from secondary sites in NP4. The current data allow us to speculate that the processes of docking to cell surfaces and NO release may be interconnected in NP7, thereby efficiently releasing NO into a target cell. This article is part of a Special Issue entitled: Oxygen Binding and Sensing Proteins.

Preparation of nitrophorin 7(Δ1-3) from Rhodnius prolixus without start-methionine using recombinant expression in Escherichia coli.

The heterologous recombinant expression of proteins in Escherichia coli without start-methionine is a common problem. The nitrophorin 7 heme properties and function strongly depend on the accurate N-terminal amino acid sequence. Leading protein expression into the periplasm by fusion with the leader peptide pelB yields functional protein; however, the folded protein sticks to the cell debris. Therefore, the periplasmic fraction was dissolved in guanidinium chloride and folded by a drop-in method. Separation from impurities including residual pelB-nitrophorin 7 required establishing an unconventional chromatographic technique using calcium-loaded Chelating Sepharose as cation exchanger and elution by a linear CaCl2 gradient.

THz absorption spectroscopy of solvated ß-lactoglobulin.

The influence of ß-lactoglobulin (ßLG) on the fast sub-picosecond collective hydration dynamics in the solvent was investigated by THz absorption spectroscopy as a function of pH. It is well-known that a change in pH from pH 6 to pH 8 reversibly opens or closes the binding cavity by a transition of the E-F loop. Furthermore, the aggregation of the protein into dimers is affected, which is thought to be triggered by changes in the enzyme's electrostatic potential. Our data reveal that pH has a clear influence on the THz absorption of ßLG. We discuss this influence in light of the changes observed in the sub-psec solute/solvent dynamics when probed by THz spectroscopy, which are, in turn, seen to correlate with changes in the pH value.

Expression, purification, and solid-state NMR characterization of the membrane binding heme protein nitrophorin 7 in two electronic spin states.

The nitrophorins (NPs) comprise a group of NO transporting ferriheme b proteins found in the saliva of the blood sucking insect Rhodnius prolixus . In contrast to other nitrophorins (NP1-4), the recently identified membrane binding isoform NP7 tends to form oligomers and precipitates at higher concentrations in solution. Hence, solid-state NMR (ssNMR) was employed as an alternative method to gain structural insights on the precipitated protein. We report the expression and purification of (13)C,(15)N isotopically labeled protein together with the first ssNMR characterization of NP7. Because the size of NP7 (21 kDa) still provides a challenge for ssNMR, the samples were reverse labeled with Lys and Val to reduce the number of crosspeaks in two-dimensional spectra. The two electronic spin states with S = 1/2 and S = 0 at the ferriheme iron were generated by the complexation with imidazole and NO, respectively. ssNMR spectra of both forms are well resolved, which allows for sequential resonance assignments of 22 residues. Importantly, the ssNMR spectra demonstrate that aggregation does not affect the protein fold. Comparison of the spectra of the two electronic spin states allows the determination of paramagnetically shifted cross peaks due to pseudocontact shifts, which assists the assignment of residues close to the heme center.

Preparation of cysteine-34-nitroxide spin labeled human α1-microglobulin.

α(1)-Microglobulin (α(1)m) is a protein of yet unresolved function occurring in blood plasma and urine. It consists of a lipocaline type of fold with two cysteine residues forming a disulfide bridge and the third cysteine-34 remaining a free, somewhat reactive thiol. A number of investigations point to an interaction with heme and we have recently reported, that heme binding triggers the formation of a stable α(1)m trimer upon modification of cysteine-34 with 2-iodoacetamide, i.e., [α(1)m(heme)(2)](3) [J.F. Siebel, R.L. Kosinsky, B. Åkerström, M. Knipp, Insertion of heme b into the structure of the Cys34-carbamidomethylated human lipocalin α(1)-microglobulin-formation of a [(heme)(2)(α(1)-microglobulin)](3) complex, ChemBioChem 13 (2012) 879-887]. For further structural and functional investigations, an improved purification protocol for α(1)m was sought, in particular yielding an untagged amino acid sequence. The method reported herein improves the speed and the yield of the protein production even when an expression plasmid without tag was applied. Furthermore, for the purpose of future structural studies using electron paramagnetic resonance (EPR) techniques, in accordance to the modification with 2-iodoacetamide (α(1)m(AM)), the protein was modified with 3-(2-iodoacetamido)-2,2,5,5-tetramethyl-1-pyrrolidinyloxy (3-(2-iodoacetamido)-PROXYL) yielding the nitroxide spin labeled α(1)m(N-O). The extinction coefficient of the protein was calibrated using magnetic circular dichroism (MCD) spectroscopy of tryptophan (ε(280nm)=40,625M(-1)cm(-1)). The parallel quantification by absorbance spectroscopy (protein) and cw-EPR spectroscopy (radical spin) determined the degree of spin labeling to 90%. Characterization of the protein by circular dichroism (CD) spectroscopy and matrix assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) upon tryptic digestion further demonstrated the similar fold of α(1)m(AM) and α(1)m(N-O), but also established the modification of cystein-34 as well as the formation of the cysteine-72-cysteine-169 disulfide bond.

Heme protonation affects iron-NO binding in the NO transport protein nitrophorin.

The nitrophorins (NPs) comprise an unusual group of heme proteins with stable ferric heme iron nitric oxide (Fe-NO) complexes. They are found in the salivary glands of the blood-sucking kissing bug Rhodnius prolixus, which uses the NPs to transport the highly reactive signaling molecule NO. Nuclear resonance vibrational spectroscopy (NRVS) of both isoform NP2 and a mutant NP2(Leu132Val) show, after addition of NO, a strong structured vibrational band at around 600 cm-1, which is due to modes with significant Fe-NO bending and stretching contribution. Based on a hybrid calculation method, which uses density functional theory and molecular mechanics, it is demonstrated that protonation of the heme carboxyl groups does influence both the vibrational properties of the Fe-NO entity and its electronic ground state. Moreover, heme protonation causes a significant increase of the gap between the highest occupied and lowest unoccupied molecular orbital by almost one order of magnitude leading to a stabilization of the Fe-NO bond.

Heterogeneous kinetics of the carbon monoxide association and dissociation reaction to nitrophorin 4 and 7 coincide with structural heterogeneity of the gate-loop.

NO is an important signaling molecule in human tissue. However, the mechanisms by which this molecule is controlled and directed are currently little understood. Nitrophorins (NPs) comprise a group of ferriheme proteins originating from blood-sucking insects that are tailored to protect and deliver NO via coordination to and release from the heme iron. Therefore, the kinetics of the association and dissociation reactions were studied in this work using the ferroheme-CO complexes of NP4, NP4(D30N), and NP7 as isoelectronic models for the ferriheme-NO complexes. The kinetic measurements performed by nanosecond laser-flash-photolysis and stopped-flow are accompanied by resonance Raman and FT-IR spectroscopy to characterize the carbonyl species. Careful analysis of the CO rebinding kinetics reveals that in NP4 and, to a larger extent, NP7 internal gas binding cavities are located, which temporarily trap photodissociated ligands. Moreover, changes in the free energy barriers throughout the rebinding and release pathway upon increase of the pH are surprisingly small in case of NP4. Also in case of NP4, a heterogeneous kinetic trace is obtained at pH 7.5, which corresponds to the presence of two carbonyl species in the heme cavity that are seen in vibrational spectroscopy and that are due to the change of the distal heme pocket polarity. Quantification of the two species from FT-IR spectra allowed the fitting of the kinetic traces as two processes, corresponding to the previously reported open and closed conformation of the A-B and G-H loops. With the use of the A-B loop mutant NP4(D30N), it was confirmed that the kinetic heterogeneity is controlled by pH through the disruption of the H-bond between the Asp30 side chain and the Leu130 backbone carbonyl. Overall, this first study on the slow phase of the dynamics of diatomic gas molecule interaction with NPs comprises an important experimental contribution for the understanding of the dynamics involved in the binding/release processes of NO/CO in NPs.

Insertion of heme b into the structure of the Cys34-carbamidomethylated human lipocalin α(1)-microglobulin: formation of a [(heme)(2) (α(1)-Microglobulin)](3) complex.

α(1)-Microglobulin (α(1)m) is a 26 kDa plasma and tissue protein belonging to the lipocalin protein family. Previous investigations indicate that the protein interacts with heme and suggest that it has a function in heme metabolism. However, detailed characterizations of the α(1)m-heme interactions are lacking. Here, we report for the first time the preparation and analysis of a stable α(1)m-heme complex upon carbamidomethylation of the reactive Cys34 by using recombinantly expressed human α(1)m. Analytical size-exclusion chromatography coupled with a diode-array absorbance spectrophotometry demonstrates that at first an α(1)m-heme monomer is formed. Subsequently, a second heme triggers oligomerization that leads to trimerization. The resulting (α(1)m[heme](2))(3) complex was characterized by resonance Raman and EPR spectroscopy, which support the presence of two ferrihemes, thus indicating an unusual spin-state admixed ground state with S=(3)/(2), (5)/(2).

Identification of the native N-terminus of the membrane attaching ferriheme protein nitrophorin 7 from Rhodnius prolixus.

All species of the genus Rhodnius have a characteristic red coloration in their salivary glands due to the presence of heme proteins. Some of these secreted proteins, known as nitrophorins (NPs), are responsible for many of the antihemostatic activities of Rhodnius saliva such as anticoagulant and antihistamine. Several NPs have been described (NP1-4 and NP7), where NP7 is the only one with affinity to phospholipid membranes. Computational prediction suggested that NP7 also has an extended N-terminal tail on signal peptide cleavage; however, the complementary DNA does not allow the determination of the exact site of signal peptidase cleavage. On the other hand, according to previous studies, the exact length of the N-terminus has important consequences for the nitric oxide binding properties of NP7. Here, a method was developed to select phospholipid membrane-attaching proteins from homogenized tissue for analysis by mass spectrometry. The method was used to determine the exact N-terminus of the ferriheme protein NP7 from homogenates of the salivary glands of 5th instar nymphal stages of Rhodnius prolixus.

A caged cyanide.

A photoactivatable caged cyanide, 1-(2-nitrophenyl)ethyl (NPE) cyanide, was synthesized, which upon irradiation in the near UV releases cyanide. It is demonstrated that the compound can be used to induce formation of the Fe(III)-CN(-) complex in the heme protein nitrophorin 4 from Rhodnius prolixus.

Crystallization and preliminary X-ray crystallographic analysis of the membrane-binding haemprotein nitrophorin 7 from Rhodnius prolixus.

Nitrophorins (nitric oxide transport proteins) are haemproteins originating from the blood-feeding insect Rhodnius prolixus. They consist of an eight-stranded ß-barrel, which classifies them into the lipocalin family. Nitrophorin 7 (NP7) and the E27V mutant protein NP7(E27V) were crystallized at 277 K using the vapour-diffusion method with PEG as the precipitating agent. Data sets for wild-type NP7 and NP7(E27V) were collected to 1.80 Å resolution from single crystals at 100 K using synchrotron radiation. The crystals belonged to space group P2(1), with unit-cell parameters a = 38, b = 67, c = 39 Å, ß = 117°. The crystal contained one molecule per asymmetric unit, with a Matthews coefficient (V(M)) of 2.11 Å(3) Da(-1); the solvent content was estimated to be 41.8%.

Insertion of an H-bonding residue into the distal pocket of the ferriheme protein nitrophorin 4: effect on nitrite-iron coordination and nitrite disproportionation.

Heme proteins are important entities for the metabolism of nitrite. Inspection of the structural features of the reported hemoprotein-nitrite crystal structures reveals that, except for nitrophorin 4 (NP4), H-bonding to the nitrite ligand is accomplished via histidine or arginine residues. These H-bonds probably play an important role for the nitrite coordination and/or reactivities. In nitrophorins, which catalyze the nitrite disproportionation reaction, such a residue is missing. Here, we report on the L130R mutant of the NP isoprotein NP4 that provides the Arg130 residue as part of the flexible G-H loop as a potential H-bonding residue in the distal heme pocket. Similar to the wild-type protein, nitrite remains N-bonded in the crystal structure of NP4(L130R). However, spectroscopic investigations show that, in solution, a second ligand-rotational orientation exists, which is in fast-exchange equilibrium with the normal, parallel ligand orientation. Moreover, the nitrite disproportionation is inhibited in NP4(L130R). Comparison with another, also less active mutant NP4(D30N) suggests that the displacement of H(2)O molecules from the heme cavity prevents the proton donation pathway through Asp30.

Breaking the proximal Fe(II)-N(His) bond in heme proteins through local structural tension: lessons from the heme b proteins nitrophorin 4, nitrophorin 7, and related site-directed mutant proteins.

The factors leading to the breakage of the proximal iron-histidine bond in the ferroheme protein soluble guanylate cyclase (sGC) are still a matter of debate. This event is a key mechanism in the sensing of NO that leads to the production of the second-messenger molecule cGMP. Surprisingly, in the heme protein nitrophorin 7 (NP7), we noticed by UV-vis absorbance spectroscopy and resonance Raman spectroscopy that heme reduction leads to a loss of the proximal histidine coordination, which is not observed for the other isoproteins (NP1-4). Structural considerations led to the generation and spectroscopic investigation of site-directed mutants NP7(E27V), NP7(E27Q), NP4(D70A), and NP2(V24E). Spectroscopic investigation of these proteins shows that the spatial arrangement of residues Glu27, Phe43, and His60 in the proximal heme pocket of NP7 is the reason for the weakened Fe(II)-His60 bond through steric demand. Spectroscopic investigation of the sample of NP7 reconstituted with 2,4-dimethyldeuterohemin ("symmetric heme") demonstrated that the heme vinyl substituents are also responsible. Whereas the breaking of the iron-histidine bond is rarely seen among unliganded ferroheme proteins, the breakage of the Fe(II)-His bond upon binding of NO to the sixth coordination site is sometimes observed because of the negative trans effect of NO. However, it is still rare among the heme proteins, which is in contrast to the case for trans liganded nitrosyl model hemes. Thus, the question of which factors determine the Fe(II)-His bond labilization in proteins arises. Surprisingly, mutant NP2(V24E) turned out to be particularly similar in behavior to sGC; i.e., the Fe(II)-His bond is sensitive to breakage upon NO binding, whereas the unliganded form binds the proximal His at neutral pH. To the best of our knowledge, NP2(V24E) is the first example in which the ability to use the His-on ↔ His-off switch was engineered into a heme protein by site-directed mutagenesis other than the proximal His itself. Steric tension is, therefore, introduced as a potential structural determinant for proximal Fe(II)-His bond breakage in heme proteins.

Nitrophorins: nitrite disproportionation reaction and other novel functionalities of insect heme-based nitric oxide transport proteins.

Nitrophorins (NPs) comprise a unique class of heme proteins used by the blood-sucking insect Rhodnius prolixus to deliver the signaling gas molecule NO into the blood vessel of a host during feeding. Upon NO release, histamine can be scavenged by coordination to the heme iron. Although the protein is of similar size as the mammalian globin monomers and shares the same cofactor and proximal histidine coordination, nitrophorin structure, in contrast, is almost entirely composed of a ß-barrel. Comparison of the NO and histamine association constants with the concentrations of both compounds invivo raises concerns about the very simple ligand release model in case of at least some of the NPs. Therefore, novel functionalities of the NPs were sought. As a result, catalysis of the nitrite disproportionation reaction was found, which leads to the formation of NO with nitrite as the sole substrate. This is the first example of a ferriheme protein that can perform this reaction. Furthermore, although NPs stabilize the ferriheme state, a peroxidase reactivity of the cofactor involving the higher oxidation state iron (Compound I/II) was studied with the potential to catalyze the oxidation of histamine and norepinephrine. In contrast to many other heme proteins including the globins, the ferroheme state was found to be extremely sensitive to O(2) , which is a consequence of the much lower reduction potential of the NPs, so that the 1-electron reduction of O(2) to O (•-)(2) becomes a thermodynamically favored process. Altogether, the detailed study of the NPs gives insight into the structure-function relationships required for the targeted delivery of diatomic gas molecules in biology. Moreover, the comparison of the structure-function relationships of the NPs (NO transporters) with those of the globins (O(2) transporters) will help to elucidate the architectural requirement for the respective tasks.

Formation of the complex of nitrite with the ferriheme b beta-barrel proteins nitrophorin 4 and nitrophorin 7.

The interaction of ferriheme proteins with nitrite has recently attracted interest as a source for NO or other nitrogen oxides in mammalian physiology. However, met-hemoglobin (metHb), which was suggested as a key player in this process, does not convert nitrite unless small amounts of NO are added in parallel. We have recently reported that, in contrast, nitrophorins (NPs) convert nitrite as the sole substrate to form NO even at pH 7.5, which is an unprecedented case among ferrihemes [He, C., and Knipp, M. (2009) J. Am. Chem. Soc. 131, 12042-12043]. NPs, which comprise a class of unique heme b proteins from the saliva of the blood-sucking insect Rhodnius prolixus, appear in a number of concomitant isoproteins. Herein, the first spectroscopic characterization of the initial complexes of the two isoproteins NP4 and NP7 with nitrite is presented and compared to the data reported for metHb and met-myoglobin (metMb). Because upon nitrite binding, NPs, in contrast to metHb and metMb, continue to react with nitrite, resonance Raman spectroscopy and continuous wave electron paramagnetic resonance spectroscopy were applied to frozen samples. As a result, the existence of two six-coordinate ferriheme low-spin complexes was established. Furthermore, X-ray crystallography of NP4 crystals soaked with nitrite revealed the formation of an eta(1)-N nitro complex, which is in contrast to the eta(1)-O-bound nitrite in metMb and metHb. Stopped-flow kinetic experiments show that although the ligand dissociation constants of NP4 and NP7 (15-190 M(-1)) are comparable to those of metHb and metMb, the rates of ligand binding and release are significantly slower. Moreover, not only the reaction kinetics but also electron paramagnetic resonance spectroscopy reveals notable differences between the two isoproteins.

A one-residue switch reverses the orientation of a heme b cofactor. Investigations of the ferriheme NO transporters nitrophorin 2 and 7 from the blood-feeding insect Rhodnius prolixus.

This study represents the identification of a single amino acid residue that has the major responsibility for the isomeric orientation of a heme b cofactor in a ferriheme protein. The insertion of hemin b into the asymmetric environment of a protein pocket facilitates two cofactor orientations, A and B, which is often called "heme rotational disorder". The proteins studied herein are nitrophorins, a class of ferriheme proteins found in the saliva of the blood-sucking insect Rhodnius prolixus, in this case NP2 and NP7. NMR spectroscopy (pH* 5.5) of the imidazole complex of NP7 revealed solely the A orientation, whereas NP2 shows primarily the B orientation ( approximately 1:5 A:B). The glutamate 27 residue in NP7 is an obvious difference in the heme pocket compared to those of NP1-4, all of which present a valine residue [valine 24 (NP2 and NP3) or valine 25 (NP1 and NP4)] at the same position. Consequently, the mutant NP2(V24E) was prepared and shown to reverse the heme orientation to exclusively A, whereas NP7(E27V) revealed an approximately 1:3 A:B ratio. The reversal A <--> B following the change glutamine <--> valine was further indicated in circular dichroism (CD) spectroscopy with a positive (A) or negative (B) Deltaepsilon of the heme Soret band. Moreover, CD spectroscopy was applied to the mutant NP7(E27Q) and indicated mainly the A orientation, which allows us to conclude that the steric hindrance provided by the glutamate residue is responsible for the heme orientation rather then the carboxylate charge.

Formation of nitric oxide from nitrite by the ferriheme b protein nitrophorin 7.

Recently, the conversion of nitrite into NO by certain heme proteins, in particular hemoglobin, gained much interest as a physiologically important source of NO in human tissue. However, in an aqueous environment, nitrite reduction at an iron porphyrin occurs either through oxidation of ferroheme to ferriheme or with the assistance of a second substrate molecule. Here we report on the reduction of nitrite in the absence of a second substrate at the heme center of the ferriheme protein nitrophorin 7 (NP7) resulting in the formation of NO and restoration of the ferriheme center. The product was spectroscopically characterized, in particular by resonance Raman and FT-IR spectroscopy. Performing the reaction in the presence of the NO trap 2-(4-trimethylammonio)phenyl-4,4,5,5-tetramethylimidazoline-1-oxyl 3-oxide (TMA-PTIO) revealed that continuous NO production is possible, i.e., that NP7 is fully restored upon a single turnover. Thus, NP7 is the first case of a b-type heme that performs reduction of nitrite as a single substrate out of the iron(III) state.