Photoreceptor Pigment for Blue Light in Neurospora crassa

Irradiating the mycelium of Neurospora crassa with moderate intensities of blue light causes a reversible photoreduction of a b-type cytochrome. The action spectrum for the photoreduction of cytochrome b is very similar to the absorption spectrum of flavin pigments. Prolonged irradiation of the mycelium with strong blue light irreversibly bleaches flavin-like pigments and as these pigments are bleached the photoresponse of cytochrome b is lost. We conclude from these and other data that a flavin is the photoreceptor pigment for the photoreduction of cytochrome b. The close similarity between the action spectrum for the photoreduction of cytochrome b and action spectra for a number of physiological photoresponses suggests that this photoreceptor pigment controls a wide variety of photobiological processes in a wide diversity of organisms.     

The effect of eye colour pigments on the action spectrum of Drosophila

In vivo absorption spectra for Drosophila melanogaster eye colour pigment classes (drosopterins and ommatins) were constructed by subtracting the whole eye electroretinographic (ERG) spectral sensitivities of cn and bw respectively from the sensitivities of white-eyed strains. In situ microspectrophotometric (MSP) absorption spectra were also obtained. Both the ERG and MSP drosopterin spectra show a visible peak at 500 nm compared to the 480 nm peak of in vitro drosopterins. For the ommatins, the ERG absorption spectrum peaks at 450 nm while the MSP spectrum peaks at 400 and 525 nm. The ERG spectrum is similar to the in vitro absorption spectrum of xanthommatin while the MSP spectrum is similar to the in vitro absorption spectrum of reduced xanthommatin. The ERG absorption spectra for the drosopterins and the ommatins yield an accurate prediction of the effect of the combined pigments in wild-type eyes. Newly emerged and 7 day post-emergence bw flies show quantitatively similar pigment absorption effects while the drosopterins depress the sensitivity of newly emerged cn flies to a greater extent than that of cn flies 7 days after emergence.     

The flavin dimers I. The application of absorption in anti-stokes excitation region to investigate the flavin dimer formation

The dimer formation process of the flavin in aqueous solution has been studied. The difference absorption spectra with the change of concentration in Stokes and anti-Stokes excitation region of the flavomononucleotide and riboflavin were measured. The highest temperature in which the dimers still appear is discussed. It is suggested that this temperature T_d can be treated as one of the empirical parameters which describe the dimer formation process of the dyes in solutions. The aqueous solution of flavins with the concentration c?5·10^?5 M at room temperature can be treated as a flavin monomers solution. For higher concentrations the flavin monomers and dimers exist in a solution at room temperature.     

Some novel flavin-nicotinamide biscoenzymes and their reactivities

The present study was undertaken to investigate flavin-nicotinamide reactions and interactions. A series of novel flavin-nicotinamide biscoenzymes have been synthesized by a general three-step procedure. The structures of these compounds were confirmed by nuclear magnetic resonance spectra, absorption spectra and elemental analysis. These compounds consist of short linear hydrocarbon chains interconnecting the N-1 of nicotinamide and the N-10 of the 7,8-dimethyl-isoalloxazine ring. The compounds were reduced with sodium dithionite (Na₂S₂O₄) and the flavin portion was reoxidized with ferricyanide. Re-reduction of the flavin portion by the nicotinamide portion of the molecule was followed anaerobically at 442 nm. When the interconnecting hydrocarbon chain was unsaturated, a second order reaction was observed with a rate equal to that of lumiflavin and 1-propyl-1,4-dihydronicotinamide (NprNicH₂) under the same conditions. When the two halves of the biscoenzymes were connected by saturated three- and four-carbon chains, the expected unimolecular reaction was not observed. Instead, the reduced biscoenzyme, after separation from excess sodium dithionite, was shown to have a strong absorption at 298 nm. This absorption is characteristic of hydration of dihydronicotinamides at the 5,6-double bond.In further studies, the C₃-biscoenzyme exhibited an absorption at 600 nm due to a complex between the reduced flavin and oxidized nicotinamide portions of the molecule. Absorbance at 600 nm increased linearly with the C₃-biscoenzyme concentration, clearly indicating that this is an intramolecular complex. When the C₃-biscoenzyme was at 0°C in 60–75% dimethylformamide buffer solution, no absorption at 600 nm was observed. When excess dithionite was removed, the spectrum under these conditions showed definite peaks at 297 and 357 nm. These respective peaks were attributed to hydrated dihydronicotinamide and dihydronicotinamide species present in the reaction mixture.The reduced flavin was postulated to be a catalyst for the hydration of dihydronicotinamide. This hypothesis was tested by incubating 1-propyl-1,4-dihydronicotinamide alone and with several concentrations of reduced riboflavin under basic anaerobic conditions. The results show that the reduced flavin increases the rate of disappearance of the dihydronicotinamide species and that the product shows an absorption near 298 nm. These results indicate that a reduced form of the flavin nucleus catalyzes the hydration of dihydronicotinamides.     

Photoconversion of riboflavin to lumichrome in plant tissues

Free flavins have been extracted from shoots of etiolated corn (Zea mays L., var. Burpee Snowcross) and from yeast cells and separated from other substances by absorption on resorcinol-formaldehyde resin and talc columns and by thin layer chromatography. Riboflavin was the only free flavin present. Extracts of etiolated shoots of oats (Avena sativa L., var. Multiline E-69 and Clinford) yielded riboflavin plus a second free flavin previously demonstrated in oats. The areas of the chromatograms expected to contain lumichrome were completely clear. After illumination of any of the three organisms with artificial light (1100 ft-c) or sunlight for 6 hours, lumichrome (7,8-dimethylalloxazine) was found. In corn shoots after irradiation by sunlight, the amount of lumichrome present was equivalent to 2.5% of the total free flavin. Lumichrome was identified by thin layer chromatography in six solvent systems (including two two-dimensional systems), by its characteristic fluorescence in acetic acid, by its absorption spectrum, and by formation of a characteristic hydrate in ammonia-containing solutions. A comparison was made with in vitro photolysis of riboflavin and the possible role of photolysis of riboflavin (either free or bound) and of lumichrome formation in photo-responses of plants is discussed. Placing the shoots in the dark for 4 hours after irradiation in sunlight for 6 hours led to no detectable loss of the lumichrome which had been formed.     

Action spectra for nitrate and nitrite assimilation in blue-green algae

Action spectra for the assimilation of nitrate and nitrite have been obtained for several blue-green algae (cyanobacteria) with different accessory pigment composition. The action spectra for both nitrate and nitrite utilization by nitrate-grown Anacystis nidulans L-1402-1 cells exhibited a clear peak at about 620 nanometers, corresponding to photosystem II (PSII) C-phycocyanin absorption, the contribution of chlorophyll a (Chl a) being barely detectable. The action spectrum for nitrate reduction by a nitrite reductase mutant of A. nidulans R2 was very similar. All these action spectra resemble the fluorescence excitation spectrum of cell suspensions of the microalgae monitored at 685 nanometers—the fluorescence band of Chl a in PSII. In contrast, the action spectrum for nitrite utilization by nitrogen-starved A. nidulans cells, which are depleted of C-phycocyanin, showed a maximum near 680 nanometers, attributable to Chl a absorption. The action spectrum for nitrite utilization by Calothrix sp. PCC 7601 cells, which contain both C-phycoerythrin and C-phycocyanin as PSII accessory pigments, presented a plateau in the region from 550 to 630 nanometers. In this case, there was also a clear parallelism between the action spectrum and the fluorescence excitation spectrum, which showed two overlapped peaks with maxima at 562 and 633 nanometers. The correlation observed between the action spectra for both nitrate and nitrite assimilation and the light-harvesting pigment content of the blue-green algae studied strongly suggests that phycobiliproteins perform a direct and active role in these photosynthetic processes.     

The effects of light on a circadian rhythm of conidiation in neurospora

The expression of a circadian rhythm of conidiation by timex, a strain of Neurospora crassa, is inhibited by growth in continuous white light. The action spectrum for this effect has a strong peak (with minor subpeaks) in the blue region of the visible spectrum, and a broad shoulder in the near ultraviolet. This action spectrum suggests that a carotenoid or flavin compound may be the photoreceptor, but does not allow one to determine conclusively whether the receptor is indeed a carotenoid, flavin, or some other unrelated pigment. Two lines of evidence suggest that a carotenoid is not the photoreceptor. First, the in vivo absorption spectrum of timex (representing the sum of the spectra of the individual pigments present, predominantly carotenoids) has peaks at wavelengths 10 to 20 mμ longer than those of the action spectrum peaks. Second, an albino-timex has normal photosensitivity, a situation requiring that the photoreceptor, if carotenoid, be a quantitatively minor constituent of the total carotenoid complement.

The magnitude and direction of phase-shift resulting from a standard dose of white light given at different times in the daily cycle of timex varies in the manner reported for other organisms. Additional phase-shift experiments have shown that there are no major transients in the attainment of a new equilibrium after a phase-shifting perturbation, and that 2 light reactions (rapidly and slowly saturating) may be involved in the phase-shift response.

     

Activation and inactivation of rabbit liver pyridoxamine (pyridoxine) 5'-phosphate oxidase activity by urea and other solutes.

Urea, guanidine hydrochloride, and neutral salts both activate and denature pyridoxamine (pyridoxine) 5′-phosphate oxidase (EC 1.4.3.5) from rabbit liver. Activation occurs at lower concentrations (e.g. 2-2.5 m for urea) of these compounds and is rapid and reversible. Greater structural changes leading to inactivation occur slowly under “activating conditions” but rapidly at higher concentrations of urea. Both reversibly and irreversibly inactivated species are formed. Activation by urea does not involve either dissociation of the enzyme to subunits or aggregation to multimers, and there is little disruption of protein secondary structure. The V and K_m for substrates, K_i for product, and the rate of release of product from the enzyme are increased by urea, and substrate inhibition is decreased; urea has little effect on the reactivity of reduced enzyme with oxygen. Both flavin and tryptophanyl fluorescence increase in the presence of urea; at lower concentrations of urea (≤2 m), there is a rapid increase followed by slower, sigmoidal increases. The polarization of flavin fluorescence of the oxidase is increased upon the addition of 2 m urea, which corresponds to the initial enhancement of protein and flavin fluorescence intensities, and then decreases. The near-ultraviolet-visible absorption spectra of native enzyme and that treated with 2 m urea are only slightly different; however, a considerable change at the flavin-binding site is reflected by the circular dichroism spectra. Hence, it appears that urea yields a rapidly formed, “activated” species of the oxidase that is changed primarily at the active site in a manner that allows increased dissociation of substrate and product.     

The oxidation mechanisms of thiosulphate and sulphide in Chlorobium thiosulphatophilum: Roles of cytochrome c-551 and cytochrome c-553

A thiosulphate-cytochrome c reductase was highly purified from Chlorobium thiosulphatophilum and its properties were studied. The enzyme catalyses reduction with Na₂S₂O₃ of c cytochromes, including cytochrome c-551 of the bacterium. Cytochrome c (555, C. thiosulphatophilum) does not react directly with the enzyme at an appreciable rate but stimulates greatly the reduction by the enzyme of cytochrome c-551 with Na₂S₂O₃. The reduction of c cytochromes catalysed by the enzyme is strongly inhibited by cyanide and sulphite.Cytochrome c (553, C. thiosulphatophilum), a c-type cytochrome with covalently bound flavin, was found to catalyse reduction with sulphide of c cytochromes, including cytochrome c-555. The reaction is strongly inhibited by cyanide. Cyanide seems to combine strongly with cytochrome c-553 probably at the flavin moiety. Thus, the absorption spectrum attributable to flavin of the haemoprotein is changed on addition of cyanide, and neither the original spectrum nor the activity reappears even after the cyanide-treated cytochrome has been subjected to gel filtration with a Sephadex G-25 column or to isoelectric focusing.     

Modified Light-Induced Absorbance Changes in dim Y Photoresponse Mutants of Trichoderma

A brief pulse of blue light induces the common soil fungus Trichoderma harzianum to sporulate. Photoresponse mutants with higher light requirements than the wild type are available, including one class, dim Y, with modified absorption spectra. We found blue-light-induced absorbance changes in the blue region of the spectrum, in wild-type and dim Y mutant strains. The light-minus-dark difference spectra of the wild type and of several other strains indicate photoreduction of flavins and cytochromes, as reported for other fungi and plants. The difference spectra in strains with normal photoinduced sporulation have a prominent peak at 440 nm. After actinic irradiation, this 440 nanometer difference peak decays rapidly in the dark. In two dim Y photoresponse mutants, the difference spectra were modified; in one of these, LS44, the 440 nanometer peak was undetectable in difference spectra. Detailed study of the dark-decay kinetics in LS44 and the corresponding control indicated that the 440 nanometer difference peak escaped detection in LS44 because it decays faster than in the control. The action spectrum of the 440 nm difference peak is quite different from that of photoinduced sporulation. The light-induced absorbance changes are thus unlikely to be identical to the primary photochemical reaction triggering sporulation. Nevertheless, these results constitute genetic evidence that physiologically relevant pigments participate in these light-induced absorbance changes in Trichoderma.     

Coenzyme models: 46. “Remote control” of flavin reactivities by an intramolecular crown ring serving as a metal binding site: Relationship between spectral properties and dissociation of the 8-sulfonamide group

Crown ether flavin mimics (CrSO₂NHFl and NCrSO₂NHFl) which have a flavin moiety serving as a catalytic site and a crown ether moiety serving as a metal binding site at the two sides of a sulfonamide group were synthesized. We have found that the absorption spectra of these flavins are very sensitive to solvent effects; that is, they are yellow to orange in nonpolar solvents like “regular” flavins but imparted a red color to polar solvents characteristic of the intramolecular charge transfer like roseoflavin. This is due to the dissociation of the 8-sulfonamide group in polar solvents. The fluorescence spectra were also sensitive to solvent effects: the quantum yields of neutral NCrSO₂NHFl increased with decreasing solvent polarity. In acetonitrile, Ca²⁺ ion bound to the crown ether cavity in NCrSO₂NHFl facilitated deprotonation of the sulfonamide group to give a new absorption maximum at 452 nm. Correspondingly, the quantum yields for photooxidation of benzyl alcohol by NCrSO₂NHFl increased with increasing Ca²⁺ concentration. These findings indicate that Ca²⁺ ion can control the catalytic activity of NCrSO₂NHFl through the interaction with the sulfonamide group serving as a cap for Ca²⁺ bound to the crown cavity. The changes in the absorption spectra and the quantum yields were not observed for CrSO₂NHFl and a reference flavin, PhSO₂NHFl. Therefore, NCrSO₂NHFl acts as a new model system relevant to allosteric enzymes in which binding of an effector to a remote, allosteric site induces activity changes in the active sites.     

Discovery of signaling effect of UV-B/C light in the extended UV-A/blue-type action spectra for step-down and step-up photophobic responses in the unicellular flagellate algaEuglena gracilis

Summary Cultures of unicellular algal flagellateEuglena gracilis grown in different conditions were subjected to action spectroscopy for step-down and step-up photophobic responses, respectively. The spectral region was extended into the UV-B/C as well as in the UV-A and visible regions with the Okazaki Large Spectrograph as the monochromatic light source. The photophobic responses of the cells were measured with an individual-cell assay method with the aid of a computerized video motion analyzer. In the UV-A and visible regions, the shapes of the action spectra were the so-called UV-A/blue type. In the newly studied UV-B/C region, new action peaks were found at 270 nm for the step-down response and at 280 nm for the step-up one. The absorption spectrum of flavin adenine dinucleotide (FAD) appeared to fit the action spectrum for the step-up response, whereas the shape of the step-down action spectrum, which has a UV-A peak (at 370 nm) higher than the blue peak (at 450 nm), appeared to be mimicked by the absorption spectrum of a mixed solution of 6-biopterin and FAD. These observations might also account for the fact that the UV-B/C peak wavelength at 270 nm of the action spectrum for the step-down response is shorter by 10 nm than the action spectrum for the step-up response at 280 nm.Abbreviations FAD flavin adenine dinucleotide - FWHM spectral full width at half maximum - NIBB National Institute for Basic Biology - OLS Okazaki Large Spectrograph - PFB paraflagellar body - UV-A ultraviolet light of spectral region between 320 and 400 nm - UV-B/C ultraviolet light of spectral region between 190 and 320 nm     

The absence of tightly bound copper, iron, and flavin nucleotide in crystalline ribulose 1,5-bisphosphate carboxylase-oxygenase from tobacco.

Crystalline ribulose 1,5-bisphosphate carboxylase-oxygenase (EC 4.1.1.39) was isolated from tobacco ($\text{Nicotiana tabacum}$ L.) leaf homogenates and analyzed for several characteristic oxygenase prosthetic groups. Analyses by atomic absorption and emission spectroscopy and neutron activation indicated that the crystalline protein contains less than 0.2 g-atoms of tightly bound copper or iron per mole (550,000 g) of enzyme. In addition, the absorption and fluorescence spectra of concentrated solutions of the crystalline protein gave no indication of the presence of a flavin nucleotide. Thus, the enzymatic oxygenation of ribulose 1,5-bisphosphate to yield P-glycolate, which is believed to comprise the initial reaction in the photorespiratory metabolism of higher plants, appears not to involve these cofactors in the catalytic mechanism.     

A lysine conserved in the monoamine oxidase family is involved in oxidation of the reduced flavin in mouse polyamine oxidase

Lysine 315 of mouse polyamine amine oxidase corresponds to a lysine residue that is conserved in the flavoprotein amine oxidases of the monoamine oxidase structural family. In several structures, this lysine residue forms a hydrogen bond to a water molecule that is hydrogen-bonded to the flavin N(5). Mutation of Lys315 in polyamine oxidase to methionine was previously shown to have no effect on the kinetics of the reductive half-reaction of the enzyme (M. Henderson Pozzi, V. Gawandi, P.F. Fitzpatrick, Biochemistry 48 (2009) 1508-1516). In contrast, the mutation does affect steps in the oxidative half-reaction. The k_cat value is unaffected by the mutation; this kinetic parameter likely reflects product release. At pH 10, the k_cat/K_m value for oxygen is 25-fold lower in the mutant enzyme. The k_cat/K_O2 value is pH-dependent for the wild-type enzyme, decreasing below a pK_a of 7.0, while this kinetic parameter for the mutant enzyme is pH-independent. This is consistent with the neutral form of Lys315 being required for more rapid flavin oxidation. The solvent isotope effect on the k_cat/K_O2 value increases from 1.4 in the wild-type enzyme to 1.9 in the mutant protein, and the solvent inventory changes from linear to bowed. The effects of the mutation can be explained by the lysine orienting the bridging water so that it can accept the proton from the flavin N(5) during flavin oxidation. In the mutant enzyme the lysine amine would be replaced by a water chain.     

A Q63E Rhodobacter sphaeroides AppA BLUF domain mutant is locked in a pseudo-light-excited signaling state

The AppA BLUF photoreceptor from Rhodobacter sphaeroides contains a conserved key residue, Gln63, that is thought to undergo a shift in hydrogen-bonding interactions when a bound flavin is light excited. In this study we have characterized two substitution mutants of Gln63 (Q63E, Q63L) in the context of two constructs of the BLUF domain that have differing lengths, AppA1-126 and AppA17-133. Q63L mutations in both constructs exhibit a blue-shifted flavin absorption spectrum as well as a loss of the photocycle. Altered fluorescence emission and fluorescence quenching of the Q63L mutant indicate significant perturbations of hydrogen bonding to the flavin and surrounding amino acids which is confirmed by (1)H-(15)N HSQC NMR spectroscopy. The Q63E substitution mutant is constitutively locked in a lit signaling state as evidenced by a permanent 3 nm red shift of the flavin absorption, quenching of flavin fluorescence emission, analysis of (1)H-(15)N HSQC spectra, and the inability of full-length AppA Q63E to bind to the PpsR repressor. The significance of these findings on the mechanism of light-induced output signaling is discussed.     

Resonance Raman on the purple intermediates of the flavoenzyme D-amino acid oxidase

Resonance Raman (RR) spectra excited at 632.8 nm within a charge transfer absorption band were obtained for a catalytic intermediate, the purple complex of D-amino acid oxidase with D-proline or D-alanine as a substrate. The resonance enhanced Raman lines around 1605 and 1360 cm^?1 in either of the complexes were suggested to be derived from vibrational modes of reduced flavin molecule. Since the highest energy band at 1692 cm^?1 in the RR spectrum with D-alanine was shifted to 1675 cm^?1 upon [¹⁵N] substitution of alanine and ammonium, this Raman line in the spectrum with D-alanine or the line at 1658 cm^?1 with D-proline is assigned to the CN stretching mode of an imino acid corresponding to each amino acid. These results confirm the concept that the purple intermediate of D-amino acid oxidase consists of reduced flavin and an imino acid.     

Coenzyme models: 40. Spectral and reactivity studies of roseoflavin analogs: Correlation between reactivity and spectral parameters

Roseoflavin analogs with a morpholino group or a monoaza-15-crown-5 group at the 8-position [3-methyl-8-morpholino-10-ethylisoalloxazine or 3-methyl-8-(1′,4′,7′,10′-tetraoxa-13′-azacyclopentadec-13′-yl)-10-ethylisoalloxazine (NCrFl), respectively] were synthesized. We have found that the absorption spectra of these roseoflavin analogs are very sensitive to solvent effects: that is, they imparted a red color to polar solvents characteristic of the intramolecular charge transfer from the 8-amino group to the pteridine moiety while they imparted a yellow color to nonpolar solvents characteristic of the inhibition of the charge transfer. The fluorescence spectra were also sensitive to solvent effects: the emission maximum of NCrFl, for example, shifted from 564 nm (water) to 509 nm (benzene) and the fluorescence intensity increased with decreasing solvent polarity. The oxidizing ability, which was estimated by photooxidation of 1-benzyl-1,4-dihydronicotinamide, was well correlated with the absorption maxima: the shorter the maximum wavelength, the more reactive. In particular, the logarithm of the rate constants was linearly correlated with E_T. These results strongly suggest that roseoflavin, inactive in polar media, is possibly activated when it is bound to hydrophobic pockets of enzymes and that the color change can be a quantitative measure of the reactivities.     

Comparative study of two highly purified forms of liver microsomal cytochrome P-450: circular dichroism and other properties.

The two major forms of rabbit liver microsomal cytochrome P-450, P-450_LM2 and P-450_LM4, which were previously shown to differ in their absorption spectra, electrophoretic and immunochemical properties, and substrate specificities, have been further characterized by several methods, (a) The two cytochromes have different CD spectra in the ferric state but similar spectra when reduced. Upon conversion of P-450_LM2 to P-420 by treatment with sodium dodecyl sulfate, the CD spectrum is greatly diminished except in the far ultraviolet region, whereas the conversion of P-450_LM4 toP-420 with this detergent results in a spectrum with a new positive band in the visible region, (b) Although P-450_LM4 has a much higher tryptophan content than P-450_LM2, the fluorescence spectra of these proteins are similar in magnitude. Upon denaturation, the fluorescence of P-450_LM4 increases, thereby indicating a large quenching effect in the native protein, (c) Studies on the interaction of dilauroylglyceryl-3-phosphorylcholine with the cytochromes showed that P-450_LM2 gives a much stronger Type I difference spectrum than does P-450_LM4. This phospholipid has no significant effect on the state of aggregation of these cytochromes as judged by calibrated gel filtration. The CD spectra of P-450_LM2 and P-450_LM4 are unchanged in the visible region but are enhanced in the far ultraviolet region upon the addition of phosphatidylcholine. The results appear to indicate an increase in α-helical content, particularly with P-450_LM4, in the presence of the phospholipid.     

Conversion of NfsA, the Major Escherichia coli Nitroreductase, to a Flavin Reductase with an Activity Similar to That of Frp, a Flavin Reductase in Vibrio harveyi, by a Single Amino Acid Substitution

NfsA is the major oxygen-insensitive nitroreductase of Escherichia coli, similar in amino acid sequence to Frp, a flavin reductase of Vibrio harveyi. Here, we show that a single amino acid substitution at position 99, which may destroy three hydrogen bonds in the putative active center, transforms NfsA from a nitroreductase into a flavin reductase that is as active as the authentic Frp and a tartrazine reductase that is 30-fold more active than wild-type NfsA.     

Occurrence of molybdenum in the nicotinic acid hydroxylase from Clostridium barkeri

Molybdenum, assayed by atomic absorption spectrometry, copurifies with the selenium-containing nicotinic acid hydroxylase from Clostridium barkeri. Fluorescence spectral studies on the enzyme indicate the presence, along with flavin, of another component. The fluorescence spectra of this component obtained after the aerobic denaturation of the nicotinic acid hydroxylase are similar to the fluorescence properties reported for the “pterin-like” cofactor from xanthine oxidase and several other molybdoproteins. Nicotinic acid hydroxylase from C. barkeri contains molybdenum, selenium, iron, acid-labile sulfur, and flavin with the occurrence of a “pterin-like” cofactor also a likely component.