The stereochemistry of NADH utilization by the flavoenzyme monooxygenase orcinol hydroxylase.

Ribbons et al. (Ribbons, D.W., Ohta, Y., and Higgins, I.J. (1972) in Molecular Basis of Electron Transport, Miami Winter Symposic Series (Schultz, J., and Cameron, B.F., eds) Vol. 4, pp. 251-274, Academic Press, New York) presented a preliminary report that the flavoenzyme monooxygenase orcinol hydroxylase shows mixed type 4R, 4S stereospecificity with respect to dihydronicotinamide oxidation when resorcinol and m-cresol were used as substrate analogs. With the natural substrate orcinol, 4R chirality was maintained. In kinetic isotope experiments reported here, we demonstrate in fact that orcinol hydroxylase maintains 4R stereospecificity with respect to dihydronicotinamide oxidation with all three substrates, orcinol, resorcinol, and m-cresol. Deuterium and tritium kinetic isotope effects were detected under Vmax conditions with (4R)-[4-2H]-, and (4R)-[4-3H]NADH for all three substrates. No isotope effect was observed with (4S)-[4-2H]NADH and tritium labilization from assays with (4S)-[4-3H]-NADH was negligible in all cases.     

Stereochemistry and mechanism of the GDP-mannose dehydratase reaction.

The reaction catalyzed by bacterial GDP-mannose dehydratase (E.C. 4.2.1.47), the conversion of GDP-D-mannose to GDP-4-keto-6-deoxymannose (GDP-6-deoxy-D-lyxo-hexos-4-ulose), was studied with (6R)- and (6S)-GDP-D-[4-2H1,6-3H]mannose. Conversion of these stereospecifically labeled substrates in the presence of excess unlabeled GDP-mannose into the 4-keto-6-deoxy derivatives followed by Kuhn-Roth oxidation gave acetic acid samples which were subjected to configurational analysis of the isotopically chiral methyl group. The observed F values of 64 for the material from the (6S) substrate and 31 for that from the (6R) isomer, corresponding to 48% e.e. R and 66% e.e. S configuration, respectively, of the methyl group indicate that (a) the oxidoreductase reaction involves transfer of H-4 to C-6, (b) the transfer is predominantly intramolecular, and (c) the transfer is stereospecific, H-4 replacing the C-6 hydroxyl group with inversion of configuration. A mechanism for the reaction is proposed on the basis of these results.     

Diastereoselective C-arylation of prochiral enolates by the SRN1 reaction

Chiral phenyl acetamide enolate ions were diastereoselectively arylated using aromatic substrates by means of the S(RN)1 reaction. The substitution took place with a diastereomeric excess that varied from 31-98%, depending on the enolate counterion, the reaction temperature, the solvent, and the aromatic substrate. The absolute configuration of the new stereogenic center of the products (4R,5S)-1,5-dimethyl-4-phenyl-3-[2'-phenyl-2'-arylacetyl]-imidazolidin-2-one (Aryl = 3-quinolyl, 1-naphthyl, 4-anisyl, 4-benzonitryl, 4-tolyl, 9-phenanthryl) was determined by (1)H NMR spectroscopy and theoretical calculations.     

Localisation of the subunits of the photosynthetic reaction centers in the chromatophore membrane of Rhodospirillum rubrum.

Reaction centers were isolated with the detergent lauryl dimethyl amine oxide from chromatophore membranes of Rhodospirillum rubrum. The subunit composition of these reaction centers is similar to the one obtained from Rhodopseudomonas spheroides: three subunits with the molecular weights of 21 000, 24 000 and 29 000. Reaction centers prepared from chromatophores labeled with 131I were heavely labeled in their large subunit (H). The smaller subunits (L and M) contained only little label. Sonication during labeling yielded a slightly higher incorporation of 131I in subunit H compared to the smaller ones. It is concluded that the H protein is largely exposed at the cytoplasmic side of the membrane but might also be accessible for iodination on the inside of the membrane while the L and M proteins are almost completely embedded in the membrane. Iodination of spheroplasts results in only a slight binding of 131I to chromatophores and reaction centers.     

Nonequivalence of transketolase active centers with respect to acceptor substrate binding

The interaction of transketolase with its acceptor substrate, ribose 5-phosphate, has been studied. The active centers of the enzyme were shown to be functionally nonequivalent with respect to ribose 5-phosphate binding. Under the conditions where only one out of the two active centers of transketolase is functional, their affinities for ribose 5-phosphate are identical. The phenomenon of nonequivalence becomes apparent when the substrate interacts with one of the two active centers. As a consequence of such interaction, the affinity of the second active center for ribose 5-phosphate decreases.     

The titration of the active centers of cellobiohydrolase from Trichoderma reesei

A novel approach has been developed for the titration of enzyme active centers and for the determination of the molecular activity of enzymes. It is based on the simultaneous use of a nonspecific chromogenic substrate and a specific ligand (a substrate or an inhibitor), the latter being tightly bound with the enzyme's active center. The approach is demonstrated using the titration (that is, the determination of the molar concentration of the enzyme active centers) of purified cellobiohydrolase I (CBH I) (EC 3.2.1.91) of the fungus Trichoderma reesei. p-Nitrophenyl-beta-D-lactoside was used as a reference substrate (Km = 0.5 mM), and cellobiose and CM-cellulose as specific ligands. The molecular weight of CBH I as it was determined by the titration with cellobiose was 42,000 +/- 3,000. The inhibition constant by cellobiose was (6 +/- 1) X 10(-6) M. The value of the catalytic constant for the hydrolysis of p-nitrophenyl-beta-D-lactoside calculated from the titration data was equal to 0.063 s-1. CM-cellulose turned out to be more efficient titration agent for cellobiohydrolase than cellobiose, and might be used for the titration of the enzyme in concentrations of the latter of 0.008-0.02 mg/ml. The titration data showed that the inhibition constant of CM-cellulose toward CBH I was equal to (1.0 +/- 0.2) X 10(-7) M.     

Stereochemical inversion at C-15 accompanies the enzymatic isomerization of all-trans- to 11-cis-retinoids

all-trans-Retinol (vitamin A) is processed by membranes from the pigment epithelium of the amphibian or bovine eye to form 11-cis-retinoids. When the isomerization reaction is performed with either [15(S)-3H,14C]-all-trans-retinol or [15(R)-3H,14C]-all-trans-retinol as substrate, the resultant 11-cis-retinals, formed by the in vitro enzymatic oxidation of the retinols, retain their 3H in the former case and lose it in the latter. The ocular all-trans- (pro-R specific) and 11-cis-retinol (pro-S specific) dehydrogenases operate with different stereochemistries with respect to the prochiral methylene hydroxyl centers of their substrates. Inversion of stereochemistry at the prochiral retinol centers was shown to accompany the isomerization process in both the amphibian and bovine systems. The 11-cis-retinol formed from [15(S)-3H,14C]-all-trans-retinol was chemically isomerized with I2 to produce [15(R)-3H,14C]-all-trans-retinol. The 11-cis-retinol formed from [15(R)-3H,14C]-all-trans-retinol was chemically isomerized with I2 to produce [15(S)-3H,14C]-all-trans-retinol. The stereochemistry at the prochiral center of retinol is not affected by the I2-catalyzed double-bond isomerization process and, hence, inversion of stereochemistry at C-15 must accompany isomerization. The same inverted stereochemistry was found with the associated retinyl palmitates. Possible mechanistic reasons for the observed inversion of stereochemistry during isomerization are discussed.     

Sensitive non-radioactive determination of aminotransferase stereospecificity for C-4' hydrogen transfer on the coenzyme

A sensitive non-radioactive method for determination of the stereospecificity of the C-4′ hydrogen transfer on the coenzymes (pyridoxal phosphate, PLP; and pyridoxamine phosphate, PMP) of aminotransferases has been developed. Aminotransferase of unknown stereospecificity in its PLP form was incubated in ²H₂O with a substrate amino acid resulted in PMP labeled with deuterium at C-4′ in the pro-S or pro-R configuration according to the stereospecificity of the aminotransferase tested. The [4′-²H]PMP was isolated from the enzyme protein and divided into two portions. The first portion was incubated in aqueous buffer with apo-aspartate aminotransferase (a reference si-face specific enzyme), and the other was incubated with apo-branched-chain amino acid aminotransferase (a reference re-face specific enzyme) in the presence of a substrate 2-oxo acid. The ²H at C-4′ is retained with the PLP if the aminotransferase in question transfers C-4′ hydrogen on the opposite face of the coenzyme compared with the reference aminotransferase, but the ²H is removed if the test and reference aminotransferases catalyze hydrogen transfer on the same face. PLP formed in the final reactions was analyzed by LC–MS/MS for the presence or absence of ²H. The method was highly sensitive that for the aminotransferase with ca. 50 kDa subunit molecular weight, only 2 mg of the enzyme was sufficient for the whole test. With this method, the use of radioactive substances could be avoided without compromising the sensitivity of the assay.     

Spectroscopic studies on the iron-sulfur centers of milk xanthine oxidase

The optical electron paramagnetic resonance and M?ssbauer spectral properties of the two iron-sulfur centers present in milk xanthine oxidase have been reexamined. It is found in the case of the optical spectral change observed on reduction of the enzyme that the two centers contribute approximately equally, with a ratio of spectral contributions for Fe/S I and Fe/S II of 0.55:0.45. This conclusion is based both on the behavior of the spectral change at wavelengths where only the two iron-sulfur centers contribute to the spectral change (under experimental conditions minimizing the effect of flavin semiquinone) during reductive titrations and a comparison of the spectra of 1- and 2-electron reduced enzyme under different conditions. This very similar spectral weighting for the two centers applies throughout the visible region. In the case of the EPR spectra, it is found from computer simulation of the signals observed under nonsaturating conditions that iron-sulfur center II exhibits g values of 1.902, 1.991, and 2.110 and does not exhibit two g values above that for the free electron, as has been reported (Lowe, J., Lynden-Bell, R.M., and Bray, R. C. (1972) Biochem. J. 130, 239-249). The g values for iron-sulfur center I obtained from the simulations are 1.894, 1.932, and 2.022. Finally, M?ssbauer spectra of xanthine oxidase have been obtained, and it is found that while the two iron-sulfur centers are indistinguishable in the oxidized state, the ferrous iron in one of the reduced iron-sulfur centers exhibits an unusually large quadrupole coupling.     

Effect of bivalent cations on the interaction of transketolase with its donor substrate

The effect of the type of the cation cofactor of transketolase (i.e., Ca2+ or Mg2+) on its interaction with xylulose 5-phosphate (donor substrate) has been studied. In the presence of magnesium, the active centers of the enzyme were functionally equivalent with respect to xylulose 5-phosphate binding and exhibited identical affinities for the donor substrate. Substitution of Ca2+ for Mg2+ results in the loss of the equivalence. In particular, this becomes apparent on binding of xylulose 5-phosphates to one of the two active centers of the enzyme, which caused the second center to undergo a several fold decrease in the affinity for the donor substrate.     

pH dependence of proton translocation in the oxidative and reductive phases of the catalytic cycle of cytochrome c oxidase. The role of H2O produced at the oxygen-reduction site

A study is presented on the pH dependence of proton translocation in the oxidative and reductive phases of the catalytic cycle of purified cytochrome c oxidase (COX) from beef heart reconstituted in phospholipid vesicles (COV). Protons were shown to be released from COV both in the oxidative and reductive phases. In the oxidation by O2 of the fully reduced oxidase, the H+/COX ratio for proton release from COV (R --> O transition) decreased from approximately 2.4 at pH 6.5 to approximately 1.8 at pH 8.5. In the direct reduction of the fully oxidized enzyme (O --> R transition), the H+/COX ratio for proton release from COV increased from approximately 0.3 at pH 6.5 to approximately 1.6 at pH 8.5. Anaerobic oxidation by ferricyanide of the fully reduced oxidase, reconstituted in COV or in the soluble case, resulted in H+ release which exhibited, in both cases, an H+/COX ratio of 1.7-1.9 in the pH range 6.5-8.5. This H+ release associated with ferricyanide oxidation of the oxidase, in the absence of oxygen, originates evidently from deprotonation of acidic groups in the enzyme cooperatively linked to the redox state of the metal centers (redox Bohr protons). The additional H+ release (O2 versus ferricyanide oxidation) approaching 1 H+/COX at pH < or = 6.5 is associated with the reduction of O2 by the reduced metal centers. At pH > or = 8.5, this additional proton release takes place in the reductive phase of the catalytic cycle of the oxidase. The H+/COX ratio for proton release from COV in the overall catalytic cycle, oxidation by O2 of the fully reduced oxidase directly followed by re-reduction (R --> O --> R transition), exhibited a bell-shaped pH dependence approaching 4 at pH 7.2. A mechanism for the involvement in the proton pump of the oxidase of H+/e- cooperative coupling at the metal centers (redox Bohr effects) and protonmotive steps of reduction of O2 to H2O is presented.     

A simple method for the rapid determination of the stereospecificity of NAD-dependent dehydrogenases applied to mammalian IMP dehydrogenase and bacterial NADH peroxidase

The stereospecificity of IMP dehydrogenase (IMP:NAD+ oxidoreductase, EC 1.1.1.205) from two different sources was determined. The enzyme preparations were obtained from murine lymphoblasts and from Escherichia coli. Both enzymes transferred the 2-3H of IMP to the pro-S position of carbon atom C-4 of the nicotinamide ring in NAD. Thus, B-sided stereospecificity is common to the enzyme from two very different species. In addition, the studies described here demonstrate that alcohol dehydrogenase and NADH peroxidase, used as auxiliary enzymes, in combination with a microdistillation procedure, should permit rapid determination of the stereospecificity of any NAD-dependent dehydrogenase for which the appropriate tritiated substrate is available.     

On the mechanism of action of methylmalonyl-CoA mutase. Change of the steric course on isotope substitution

When (methyl-2H3)methylmalonyl-CoA was reacted with partially purified methylmalonyl-CoA mutase, 1H-NMR revealed that about 24% of the migrating deuterium was lost after 88% conversion. When [methyl-3H]methylmalonyl-CoA was incubated with highly purified methylmalonyl-CoA mutase, tritium exchange with the medium depended on added methylmalonyl-CoA epimerase. With highly purified preparations of methylmalonyl-CoA mutase, effective tritium exchange from [5'-3H]adenosylcobalamin to water required the addition of methylmalonyl-CoA epimerase and of substrate (e.g. succinyl-CoA). By addition of [14C]succinyl-CoA to a partially purified preparation of methylmalonyl-CoA mutase, it was shown that the mutase binds one substrate molecule very tightly. Coupling the mutase reaction with the transcarboxylase reaction and using variously labelled succinyl-CoA as substrate, revealed that only (2R)- and not (2S)-methylmalonyl-CoA will be formed by the mutase with a kinetic isotope effect of 3.5 using (2H4)succinyl-CoA. When (1-13C) propionyl-CoA was reacted with a mixture of highly purified methylmalonyl-CoA carboxylase, epimerase and mutase, 13C-NMR signals were obtained for the thioester carbonyl of succinyl-CoA (relative intensity 100%) and of methylmalonyl-CoA (5%) as well as for the carboxyl of free succinic acid (27%) and of succinyl-CoA (less than 4.5%). Thus very little, if any, migration of the CoA from one carboxyl to the other appears to take place. (1,4-13C2)Succinic acid and (1,4-13C2)succinyl-CoA were synthesised and their 13C-NMR chemical shifts were exactly determined. Evidence is provided for a strict stereospecificity of the mutase toward the (2R)-epimer of methylmalonyl-CoA and for an incomplete stereospecificity toward the two diastereotopic 3-H atoms of succinyl-CoA. The latter, combined with a high intramolecular isotope discrimination, causes rapid washing-out of the migrating 2H and 3H to water and slow washing-in from the medium. Whenever migration of protium from the sterically less preferred 3-pro(S)- position of succinyl-CoA occurs and simultaneously a heavy isotope is maneuvered from the migratable 3-pro(R)- position into the labile alpha-position of methylmalonyl-CoA, the substitution by the COSCoA group takes place with inversion of configuration. When the sterically preferred 3-pro(R)-hydrogen atom migrates, the previously reported stereochemical retention occurs. A mechanistic and stereochemical scheme is discussed that fully accounts for all observations.     

Fragments formed by the side chain cleavage of a 20-aryl analog of 20alpha-hydroxycholesterol by adrenal mitochondria.

An analog of 20alpha-hydroxycholesterol, (20R)-20-phenyl-5-pregnene-3beta,20-diol, which is completely substituted at C-22 was prepared with radioisotopes at various positions. The analog labeled with 3H at C-M and 14C at C-4 and C-IU was converted into radioactive pregnenolone by an enzyme preparation derived from adrenal mitochondria. Cleavage of the phenyl analog labeled with 3H in the aromatic ring by the same enzyme preparation led to the formation of [3H]phenol. Using the substrate doubly labeled with 14C at C-4 and 3H in the aromatic ring, it appeared that the products of the reactions, pregnenolone and phenol, were formed in equal amounts. During incubation of the side chain labeled substrate, another labeled fragment was formed. It was identified as acetophenone, a product resulting from cleavage of the C17,20 bond. The steroidal fragment corresponding to this C8 ketone was traced using nuclear label analog. From its nonpolar chromatographic properties it appears to be a C-17-deoxy-C19 steroid.     

Characterization of the flavins and the iron-sulfur centers of glutamate synthase from Azospirillum brasilense by absorption, circular dichroism, and electron paramagnetic resonance spectroscopies.

Azospirillum brasilense glutamate synthase has been studied by absorption, electron paramagnetic resonance, and circular dichroism spectroscopies in order to determine the type and number of iron-sulfur centers present in the enzyme alpha beta protomer and to gain information on the role of the flavin and iron-sulfur centers in the catalytic mechanism. The FMN and FAD prosthetic groups are demonstrated to be non-equivalent with respect to their reactivities with sulfite. Sulfite reacts with only one of the two flavins forming an N(5)-sulfite adduct with a Kd of approximately 1 mM. The enzyme-sulfite complex is reduced by NADPH, and the complexed sulfite is competitively displaced by 2-oxoglutarate, which suggests the reactive flavin to be at the imine-reducing site. These data are in agreement with the two-site model of the enzyme active center proposed on the basis of kinetic studies [Vanoni, M.A., Nuzzi, L., Rescigno, M., Zanetti, G., & Curti, B. (1991) Eur. J. Biochem. 202, 181-189]. Each enzyme protomer was found, by chemical analysis, to contain 12.1 +/- 0.5 mol of non-heme iron. Electron paramagnetic resonance spectroscopic studies on the oxidized and reduced forms of glutamate synthase demonstrated the presence of three distinct iron-sulfur centers per enzyme protomer. The oxidized enzyme exhibits an axial spectrum with g values at 2.03 and 1.97, which is highly temperature-dependent and integrates to 1.1 +/- 0.2 spin/protomer. This signal is assigned to a [3Fe-4S]1+ cluster (Fe-S)I. Reduction of the enzyme with an NADPH-regenerating system results in reduction of the [3Fe-4S]1+ center to a species with a g approximately 12 signal characteristic of the S = 2 spin state of a [3Fe-4S]0 cluster. The NADPH-reduced enzyme also exhibits an [Fe-S] signal at g values of 1.98, 1.95, and 1.88, which integrates to 0.9 spin/protomer and is due to a second cluster (Fe-S)II. Reduction of the enzyme with the light/deazaflavin method results in a signal characteristic of [Fe-S] clusters with g values of 2.03, 1.92, and 1.86 and an integrated intensity of 1.9 spin/protomer. This signal arises from reduction of the (Fe-S)II center and from that of the third, lower potential iron-sulfur center (Fe-S)III. Circular dichroism spectral data on the oxidized and reduced forms of the enzyme are more consistent with the assignment of (Fe-S)II and (Fe-S)III as [4Fe-4S] clusters rather than [2Fe-2S] centers.     

Enzymatic synthesis of (15s)-[15-3h]prostaglandins and their use in the development of a simple and sensitive assay for 15-hydroxyprostaglandin dehydrogenase.

The stereospecificity of swine renal NAD+-dependent 15-hydroxyprostaglandin dehydrogenase has been determined. It was found that the enzyme is a B-side specific dehydrogenase. (15S)-[15-3H]Prostaglandins were synthesized by stereospecific transfer of the tritium label of D-[1-3H]galactose to prostaglandins by coupling 15-hydroxyprostaglandin dehydrogenase with beta-D-galactose dehydrogenase, an enzyme of the same stereospecificity. A simple and sensitive assay for 15-hydroxyprostaglandin dehydrogenase was developed based on the stereospecific transfer of the tritium label of tritiated prostaglandins to glutamate by coupling 15-hydroxyprostaglandin dehydrogenase with glutamate dehydrogenase. The amount of prostaglandin oxidized is determined by the radioactivity of labeled glutamate present in the supernatant after charcoal precipitation of labeled prostaglandin. Concurrent assays with the present tritium release method and the thin-layer chromatography method indicated excellent correlation. The assay was employed to study some of the properties of swine renal 15-hydroxyprostaglandin dehydrogenase in crude extract and the distribution of enzyme activity in various tissues of rat. Enzyme activity was linear for the first 10 min studied and was nonlinear with increasing amounts of crude enzyme, indicating the possible presence of endogenous inhibitor(s). Apparent Km's for PGE2, PGF2alpha, and PGA2 were found to be 2.5, 12.5, and 3.9 muM, respectively. The distribution pattern indicated high levels of enzyme activity in gastrointestinal tract, lung, kidney, and spleen. The assay method may prove to be valuable for studying enzyme turnover and enzyme regulation by hormonal and pharmacological agents.     

Investigation of the selectivity of hydrogen abstraction in the nonenzymatic formation of hydroxyeicosatetraenoic acids and leukotrienes by autoxidation

The biosynthetic conversions of arachidonic acid to hydroperoxyeicosatetraenoic acids (HPETEs) and the further conversion of leukotriene epoxides are accompanied by stereoselective hydrogen abstraction from the reaction substrate. Furthermore, this hydrogen removal has always been found to occur in fixed stereochemical relationship to carbon-oxygen chiral center(s) in the substrate or product. We have used stereospecifically labeled 10-3H-substrates with 14C internal standard to investigate whether the same relationships bear in HPETE and leukotriene formation during autoxidation. After autoxidation of labeled arachidonate, both the 8(R)- and 8(S)-HPETE enantiomers (resolved as diastereomer derivatives) and the 12(RS)-HPETE were observed to retain 41-47% 3H relative to the starting material. In autoxidative formation of leukotrienes from labeled 15(S)-HPETE the four main leukotrienes, including two derived from 14,15-leukotriene A4 hydrolysis, were observed to have retained an average of 45% 3H. Primary and secondary isotope effects were found to accompany these reactions. The results prove that stereorandom hydrogen abstraction occurs in autoxidation and that the hydrogen loss bears no stereochemical relationship to chiral oxygen center(s) in the HPETE product, (8(R) or 8(S], or the 15(S)-hydroperoxy substrate. We conclude that the chiral features of the biosynthetic reactions are a reflection of enzymatic control of stereochemistry. Nonetheless, the findings of primary and secondary isotope effects in autoxidation which are similar to those observed in the analogous biosynthetic reactions suggests that, except for stereochemical control, the autoxidative and enzymatic reactions may be mechanistically similar.     

Pyridoxamine-5'-phosphate oxidase exhibits no specificity in prochiral hydrogen abstraction from substrate

The stereochemistry for hydrogen removal from pyridoxamine 5'-phosphate with liver pyridoxine (pyridoxamine)-5'-phosphate oxidase was examined to determine whether or not there are significant steric constraints at the substrate region of the active site of the oxidase. For this, pyridoxal 5'-phosphate was reduced with tritium-labeled sodium borohydride in ammoniacal solution to yield racemically labeled [4',4'-3H]pyridoxamine 5'-phosphate which was then chemically or enzymatically oxidized to [4'-3H]pyridoxal 5'-phosphate. This latter was used as coenzyme with either L-aspartate (L-glutamate) aminotransferase and L-glutamate or L-glutamate decarboxylase and alpha-methyl-DL-glutamate to generate [4'-3H]pyridoxamine 5'-phosphate known to be labeled in the R-position. Reaction of the oxidase with the pro-R as well as the pro-R,S-labeled substrates followed by isolation of [4'-3H]pyridoxal 5'-phosphate and 3H2O revealed only half the radioactivity was abstracted from the original substrate in either case. Hence, the oxidase is not stereospecific and equally well catalyzes removal of either pro-R or pro-S hydrogen from the 4-methylene of pyridoxamine 5'-phosphate.     

The stereospecificity of the enzymic reduction of 21-dehydrocortisol by NADH.

(21R)-[21-3H]cortisol and (21S)-[21-3H]cortisol were synthesized by reduction of 21-dehydrocortisol by NADH in the presence of 21-hydroxysteroid dehydrogenase. The stereochemistry at carbon 21 was established after cleaving the side chain and oxidizing the resulting two epimers of tritiated glycolate with glycolate oxidase of known (2-pro-S) stereospecificity. From the distribution of radioactivity in the water and glyoxylate produced in this reaction, it was concluded that the reaction of 21-dehydrocortisol with (4S)-[4-3H]NADH catalyzed by 21-hydroxysteroid dehydrogenase results in a transfer of tritium from the 4S position of the nucleotide to form (21S)-[21-3H]cortisol, and that (21R)-[21-3H]cortisol resulted from the enzyme-catalyzed reduction of 21-dehydro[21-3H]cortisol with NADH. Nuclear magnetic resonance studies on both epimers at position 21 of [21-2H]cortisol and of [21-2H]cortisone prepared enzymically identify the transferring 21-pro-S hydrogen as the relatively downfield of the two 21-hydrogen atoms.     

Linear dichroism of membrane-bound reaction centers from Rhodobacter sphaeroides: Alterations of the B band induced by site-specific mutations

Low temperature absorption and linear dichroism (LD) measurements were performed on oriented membranes containing wild type Rhodobacter sphaeroides reaction centers, a mutant reaction center with the change Phe M197 to Arg (FM197R), and a double mutant reaction center where, in addition, Gly M203 was replaced by Asp (FM197R/GM203D). The monomeric bacteriochlorophyll band (B), which is highly congested in the wild type reaction center, was separated into two bands in the mutant reaction centers peaking 10 nm (single mutant) or 15 nm (double mutant) apart. This separation arose principally from changes in the interaction of the protein with the L-side monomer bacteriochlorophyll B_L.The ability to separate the B bands is extremely useful in spectroscopic studies. The orientations of the two monomer-type transitions contributing to the B band were similar in all three reaction centres studied, and were asymmetric with respect to the orientation axis, with the transition mostly associated with B_L making a smaller angle with the C₂ axis. Differences in the LD observed in wild type membrane-bound or isolated reaction centers can be ascribed either to differences in shifts of the B transitions or to differences in the orientation axis.