Comparative study of D-glyceraldehyde-3-phosphate dehydrogenase from frog and pike skeletal muscles]

The purified preparations of glyceraldehyde-3-phosphate dehydrogenase isolated from frog and pike skeletal muscles were found homogenous under polyacrylamide gel electrophoresis. Their amino acid composition is similar to that of glyceraldehyde-3-phosphate dehydrogenase from other animal species. The interaction kinetics for frog and pike glyceraldehyde-3-phosphate dehydrogenase SH-groups with 5,5'-dithio-bis-(2-nitrobenzoate) (DTNB) were studied. A negative correlation between the thermal stability of the enzyme preparations from pig, pike, lamprey and frog muscles and the reactivity of their SH-groups with respect to DTNB was observed. NAD at saturating concentrations was found to protect the enzyme from lower vertebrates muscles against thermal inactivation in a lesser degree than does the pig muscle enzyme. The weaker protective effect of NAD was observed for lamprey and frog enzyme preparations, which are characterized by a low SH-group reaction ability. Frog and pike apoenzymes are considerably more resistant to trypsin proteolysis than the pig apoenzyme.     

The mechanism of photodamage of eye structures. IV. Changes in the reactivity of crystalline SH-groups during UV irradiation

The kinetics of individual crystalline SH-group modification by DTNB were studied. According to the rates of their interaction with the modifier, the thiol groups in the native protein molecule can be classified as free, accessible, weakly modified and "masked" ones. Denaturation by the detergent (CTAB) caused an increase in the SH-group modification rate. In this case the SH-groups were modified as free and accessible ones. Illumination with UV-light resulted in a decrease in the number of SH-groups, opening of "masked" SH-groups in almost all crystallines except for alpha-crystalline, and essential changes in the SH-group modification rate.     

Effect of halide anions on the binding of FAD to D-amino acid oxidase and the tryptophanyl fluorescence of the apoenzyme.

The quenching of tryptophanyl fluorescence of native and denatured D-amino acid oxidase from hog kidney was measured. About 60% of the tryptophanyl fluorescence of the native apoenzyme was quenched by iodide at pH 8.3, and 25 degrees C. All of the tryptophanyl fluorescence of the apoenzyme in 6 M guanidine hydrochloride was quenched. The tryptophanyl fluorescence quenching of the holoenzyme by 1-methyl nicotinamide chloride was low in comparison with that of the apoenzyme. These results of the quenching experiments are discussed based on the intermolecular collision quenching mechanism. By measuring the fluorescence intensities of the tryptophanyl residues and FAD of the holoenzyme solution, and the fluorescence polarization of the holoenzyme solution containing halide anions such as iodide, bromide, chloride, or fluoride, we found that FAD dissociates from the holoenzyme in the presence of iodide, bromide, or chloride, and the ability to dissociate FAD from the holoenzyme decreases in order iodide, bromide, and chloride. However, fluoride seems to enhance the association reaction of FAD with the apoenzyme. These results were consistent with the visible absorption spectra and derivative spectra of free FAD and the holoenzyme in the presence and absence of halide anions.     

Effect of oligomerization on the properties of essential SH-groups of mitochondrial creatine kinase

The properties of creatine kinase isolated from bovine heart mitochondria in dimeric (Mr = 84 +/- 6 kD) and octameric (Mr = 340 +/- 17 kD) forms were compared with those of the earlier described hexameric form of the enzyme (Mr = 240 +/- 12 kD). The kinetics of SH-group modification by DTNB, the inactivation kinetics as well as the number of modified SH-groups point to significant differences between the three oligomeric forms of the enzyme. Each subunit of creatine kinase was found to possess one "fast" essential cysteine residue whose modification by DTNB and iodoacetamide led to enzyme inactivation. The formation of an analog of the transition state complex (E--MgADP--NO3--creatine) was paralleled with partial protection of only the "fast" cysteine residue which manifested itself in the decrease of the rate of its interaction with DTNB in all the three oligomeric forms. Dimer association into a hexamer and octamer occurred in parallel with a decrease of the affinity of essential SH-groups of cysteine for DTNB in 50% of the oligomeric molecule subunits. Thus, in the dimer two essential SH-groups were rapidly modified by DTNB at the same rate: k1 = k2 = (23.9 +/- 5.6).10(4) M-1 min-1. Within the hexamer, the rate of modification of 3 out of 6 SH-groups was practically unchanged: k1 = (10.6 +/- 2.3).10(4) M-1 min-1. Another 3 SH-groups in the remaining 50% of the subunits were partly masked, which manifested itself in a 10-fold decrease of their modification rate: k2 = (1.12 +/- 0.28).10(4) M-1 min-1. Within the octamer, the SH-groups rapidly interacted with DTNB only on 4 subunits: k1 = (20.7 +/- 2.2).10(4) M-1 min-1, whereas in the remaining 4 octamer subunits a practically complete masking of essential SH-groups was observed, as a result of which these groups became inaccessible to DTNB. This manifested itself in a 1000-fold decrease of the rate of SH-group modification by DTNB which reached that of non-essential SH-group modification. In has been found that a complete loss of the octamer activity is due to the modification of only 4 SH-groups which interact with DTNB at a high rate. A model for subunit association into a dimer, hexamer and octamer has been proposed. Presumably, 50% of the active centers in the mitochondrial creatine kinase octamer are not involved in the catalytic act.     

SH-groups of NAD kinase from the rabbit liver

Two SH-groups per enzyme subunit have been identified in the native preparation of rabbit liver NAD kinase, using DTNB. The titration curve is biphasic; one SH-group is modified at each step. There is a strict correlation between the loss of the enzyme activity and the rate of modification of fast and slow SH-groups. Substrates afford only a partial protection of NAD kinase against the DTNB-induced inactivation. The data obtained suggest that two SH-groups of NAD kinase are essential for the enzyme activity; however, these groups are not directly involved in the active center formation.     

Steroid-transforming enzymes from microorganisms. IX. Affinity chromatographic preparation and studies of the apoenzyme from a 4-en-3-oxosteroid: (acceptor)-1-en-oxidoreductase from Nocardia opaca]

From the flavoenzyme, 4-en-3-oxosteroid: (acceptor)-1-en-oxidoreductase of Nocardia opaca, prosthetic group and apoenzyme were separated quantitatively by means of affinity chromatography in the presence of 2 M (NH4)2 at pH 3.0. Subsequently the apoenzyme was eluted from affinity matrix by 0.01 M phosphate buffer, pH 8.0, whereas under these conditions the intact enzyme could not be eluted. The whole enzyme activity applied could be restored by incubation of the eluted apoenzyme with FAD. The binding strength of the apoenzyme to the immobilized steroid ligand is highly decreased in comparison to the native enzyme and can be interpreted by the action of rest hydrophobicity. That indicates the essential character of FAD for both ligand binding and transformation.     

Studies on new intracellular proteases in various organs of rat. 2. Mode of limited proteolysis.

1. The mechanism of proteolysis of ornithine transaminase apoenzyme II by group-specific protease and the relation between the confirmations of ornithine transaminase and its susceptibility to group-specific protease were studied to elucidate the mode of action of the protease. 2. Differences in the conformations of ornithine transaminase apoenzyme II, molecular weight 67000, and ornithine transaminase holoenzyme, molecular weight 140000, were shown by studies on difference spectra produced by various concentrations of ethylene glycol. Increase of the titratable sulfhydryl groups on resolution of the coenzyme from ornithine transaminase also supports this finding. These results are consistent with the facts that the apoenzyme was sensitive to group-specific protease, while the holoenzyme was not. 3. Kinetics studies showed that ornithine transaminase apoenzyme II was degraded by limited proteolysis. Reaction of the native enzyme with group-specific protease resulted in a nick in the enzyme molecule with formation of one homogeneous large product and small peptides. The large product was not degraded further. The large product was indistinguishable from native ornithine transaminase apoenzyme II in various properties including its elution volume on gel filtration, its mobility on disc electrophoresis, its antigenicity, its estimated number of exposed tryptophan residues, and its titratable number of sulfhydryl groups. But unlike the apoenzyme the product did not show tetramerization with coenzyme or catalytic activity, although it retained the ability to bind with coenzyme and had the same number of bound pyridoxal phosphate as the native ornithine transaminase molecule. Thus, native ornithine transaminase apoenzyme II was degraded by limited proteolysis. Unfolded enzyme, denatured by 8 M urea, was degraded extensively. 4. The initial step of intracellular proteins degradation is discussed on the basis of these results.     

Stability and reconstitution of pyruvate oxidase from Lactobacillus plantarum: dissection of the stabilizing effects of coenzyme binding and subunit interaction.

Pyruvate oxidase from Lactobacillus plantarum is a homotetrameric flavoprotein with strong binding sites for FAD, TPP, and a divalent cation. Treatment with acid ammonium sulfate in the presence of 1.5 M KBr leads to the release of the cofactors, yielding the stable apoenzyme. In the present study, the effects of FAD, TPP, and Mn2+ on the structural properties of the apoenzyme and the reconstitution of the active holoenzyme from its constituents have been investigated. As shown by circular dichroism and fluorescence emission, as well as by Nile red binding, the secondary and tertiary structures of the apoenzyme and the holoenzyme do not exhibit marked differences. The quaternary structure is stabilized significantly in the presence of the cofactors. Size-exclusion high-performance liquid chromatography and analytical ultracentrifugation demonstrate that the holoenzyme retains its tetrameric state down to 20 micrograms/mL, whereas the apoenzyme shows stepwise tetramer-dimer-monomer dissociation, with the monomer as the major component, at a protein concentration of < 20 micrograms/mL. In the presence of divalent cations, the coenzymes FAD and TPP bind to the apoenzyme, forming the inactive binary FAD or TPP complexes. Both FAD and TPP affect the quaternary structure by shifting the equilibrium of association toward the dimer or tetramer. High FAD concentrations exert significant stabilization against urea and heat denaturation, whereas excess TPP has no effect. Reconstitution of the holoenzyme from its components yields full reactivation. The kinetic analysis reveals a compulsory sequential mechanism of cofactor binding and quaternary structure formation, with TPP binding as the first step. The binary TPP complex (in the presence of 1 mM Mn2+/TPP) is characterized by a dimer-tetramer equilibrium transition with an association constant of Ka = 2 x 10(7) M-1. The apoenzyme TPP complex dimer associates with the tetrameric holoenzyme in the presence of 10 microM FAD. This association step obeys second-order kinetics with an association rate constant k = 7.4 x 10(3) M-1 s-1 at 20 degrees C. FAD binding to the tetrameric binary TPP complex is too fast to be resolved by manual mixing.     

Reconstitution of native Escherichia coli pyruvate oxidase from apoenzyme monomers and FAD

Pyruvate oxidase, a tetrameric enzyme consisting of 4 identical subunits, dissociates into apoenzyme monomers and free FAD when treated with acid ammonium sulfate in the presence of high concentrations of potassium bromide. Reconstitution of the native enzymatically active protein can be accomplished by incubating equimolar concentrations of apomonomers and FAD at pH 6.5. The kinetics of the reconstitution reaction have been measured by 1) enzyme activity assays, 2) spectrophotometric assays to measure FAD binding, and 3) high performance liquid chromatography analysis measuring the distribution of monomeric, dimeric, and tetrameric species during reconstitution. The kinetic analysis indicates that the second order reaction of apomonomers with FAD to form an initial monomer-FAD complex is fast. The rate-limiting step for enzymatic reactivation appears to be the folding of the polypeptide chain in the monomer-FAD complex to reconstitute the three-dimensional FAD binding site prior to subunit reassociation. The subsequent formation of native tetramers appears to proceed via an essentially irreversible dimer assembly pathway.     

The role of cofactor binding in tryptophan accessibility and conformational stability of His-tagged D-amino acid oxidase from Trigonopsis variabilis

d-amino acid oxidase from Trigonopsis variabilis (TvDAAO) is a flavoenzyme with high biotechnological and industrial interest. The overexpression and purification of the apoprotein form of a recombinant His-tagged TvDAAO allowed us to go deep into the structural differences between apoenzyme and holoenzyme, and on the cofactor binding and its contribution to enzyme stability. A significant decrease in intrinsic fluorescence emission took place upon FAD binding, associated to cofactor induced conformational transitions or subunit dimerization that could affect the local environment of protein tryptophan residues. Furthermore, acrylamide-quenching experiments indicated that one of the five tryptophan residues of TvDAAO became less accessible upon FAD binding. A K(d)=1.5+/-0.1x10(-7) M for the dissociation of FAD from TvDAAO was calculated from binding experiments based on both quenching of FAD fluorescence and activity titration curves. Secondary structure prediction indicated that TvDAAO is a mixed alpha/beta protein with 8 alpha-helices and 14 beta-sheets connected by loops. Prediction results were in good agreement with the estimates obtained by circular dichroism which indicated that both the apoenzyme and the holoenzyme had the same structural component ratios: 34% alpha-helix content, 20% beta-structure content (14% antiparallel and 6% parallel beta-sheet), 15% beta-turns and 31% of random structure. Circular dichroism thermal-transition curves suggested single-step denaturation processes with apparent midpoint transition temperatures (T(m)) of 37.9 degrees C and 41.4 degrees C for the apoenzyme and the holoenzyme, respectively. A three-dimensional model of TvDAAO built by homology modelling and consistent with the spectroscopic studies is shown. Comparing our results with those reported for pig kidney (pkDAAO) and Rhodotorula gracilis (RgDAAO) d-amino acid oxidases, a "head-to-head" interaction between subunits in the TvDAAO dimer might be expected.     

Origins of blood acetate in the rat.

1. Fluorimetric techniques were used to characterize the environment of tryptophan residues in thermolysin and apo-thermolysin. The apo-thermolysin was obtained by dissolving the enzyme in the presence of 10mm-EDTA, which removed the functional Zn(2+) ion and the four Ca(2+) ions/molecule from the enzyme. 2. At 25 degrees C in aqueous solution the fluorescence-emission spectrum of the native holoenzyme, on excitation at 290nm, was essentially characteristic of tryptophan, with an emission maximum at 333nm. The emission maximum of the apoenzyme is red-shifted to 338nm and the relative intensity of fluorescence is decreased by 10%, both effects indicating some unfolding of the protein molecule, with the indole groups being transferred to a more hydrophilic environment. 3. Fluorescence quenching studies using KI, N'-methylnicotinamide hydrochloride and acrylamide indicated a more open structure in the apoenzyme, with the tryptophan residues located in a negatively charged environment. 4. The thermal properties of the apoenzyme, as monitored by fluorescence-emission measurements, are dramatically changed with respect to the native holoenzyme. In fact, whereas the native enzyme is heat-stable up to about 80 degrees C, for the apoenzyme a thermal transition is observed near 48 degrees C. The apoenzyme is also unstable to the action of unfolding agents such as urea and guanidinium chloride, much as for other globular proteins from mesophilic organisms. 5. The functional Zn(2+) ion does not contribute noticeably to the stability of thermolysin. 6. It is concluded that a major role in the structural stability of thermolysin is played by the Ca(2+) ions, which have a bridging function within this disulphide-free protein molecule.     

Non-equivalency of SH groups essential for the activity of mitochondrial creatine kinase

The properties of SH-groups of mitochondrial creatine kinase existing in solution as a hexamer with Mr of (240 +/- 12) X 10(3) Da, were investigated. The number and reactivity of SH-groups by specific modifiers--[5.5'-dithiobis-(2-nitrobenzoic acid), DTNB; 7-chloro-4-nitrobenzo-2-oxo-1.3-diazol, NBD-Cl; 2.2'-dithiopyridine, DTP] were determined. It was found that each subunit of the enzyme hexameric molecule contains two modified SH-groups, only one of which is protected against modification by Mg-ADP, Mg-ATP as well as during the formation of the transition state analog (TSA)--E-Mg X ADP-NO3-creatine--and is essential for the enzyme activity. These six essential SH-groups within the hexameric molecule of mitochondrial creatine kinase may be classified into two groups according to the rate of their interaction with DTNB, NBD-Cl and DTP. The rate constants of modification of three fast and three slow essential SH-groups differ 4-10 times. The kinetics of enzyme inactivation by iodoacetamide (IAA) is biphasic; each phase is characterized by a 50% loss of activity. The inactivation constants differ 30 times; both phases being protected by TSA; consequently, the inactivation is caused by the binding of IAA to the essential SH-groups. The unequal reactivity of essential SH-groups seems to be preexisting. Using a computer analysis, the dependence of the amount of residual activity on the number of modified SH-groups by NBD-Cl and DTNB was studied. The interaction of NBD-Cl and DTNB with the most reactive essential SH-groups in half of the subunits results in the inactivation of these subunits as well as in partial or complete inactivation of the other half of the non-modified subunits. The degree of inactivation of the latter 50% of subunits strongly depends on the nature of the modifier. The inactivating effect of the bound modifier is translated from one subunit to another in one direction. The experimental results point to asymmetrical association of mitochondrial creatine kinase subunits.     

Reversible resolution of flavin and pterin cofactors of His-tagged Escherichia coli DNA photolyase

Escherichia coli photolyase catalyzes the repair of cyclobutane pyrimidine dimers (CPD) in DNA under near UV/blue-light irradiation. The enzyme contains flavin adenine dinucleotide (FAD) and methenyltetrahydrofolate (MTHF) as noncovalently bound light sensing cofactors. To study the apoprotein-chromophore interactions we developed a new procedure to prepare apo-photolyase. MTHF-free photolyase was obtained by binding the C-terminal His-tagged holoenzyme to a metal-affinity column at neutral pH and washing the column with deionized water. Under these conditions the flavin remains bound and the defolated enzyme can be released from the column with 0.5 M imidazole pH 7.2. The MTHF-free protein was still capable of DNA repair, showing 70% activity of native enzyme. Fluorescence polarization experiments confirmed that MTHF binding is weakened at low ionic strength. Apo-photolyase was obtained by treating the His-tagged holoenzyme with 0.5 M imidazole pH 10.0. The apo-photolyase thus obtained was highly reconstitutable and bound nearly stoichiometric amounts of FAD(ox). Photolyase reconstituted with FAD(ox) had about 34% activity of native enzyme, which increased to 83% when FAD(ox) was reduced to FADH(-). Reconstitution kinetics performed at 20 degrees C showed that apo-photolyase associates with FADH(-) much faster (k(obs) approximately 3,000 M(-1) s(-1)) than with FAD(ox) (k(obs)=16 [corrected] M(-1) s(-1)). The dissociation constant of the photolyase-FAD(ox) complex is about 2.3 microM and that of E-FADH(-) is not higher than 20 nM (pH 7.2).     

Reactive sulfhydryl groups of coenzyme B12-dependent diol dehydrase: Differential modification of essential and nonessential ones

The apoenzyme of diol dehydrase was inactivated by four sulfhydryl-modifying reagents, p-chloromercuribenzoate, 5,5′-dithiobis(2-nitrobenzoate) (DTNB), iodoacetamide, and N-ethylmaleimide. In each case pseudo-first-order kinetics was observed. p-Chloromercuribenzoate modified two sulfhydryl groups per enzyme molecule and modification of the first one resulted in complete inactivation of the enzyme. DTNB also modified two sulfhydryl groups, but modification of the second one essentially corresponded to the inactivation. In both cases, the inactivation was reversed by incubation with dithiothreitol. Cyanocobalamin, a potent competitive inhibitor of adenosylcobalamin, protected the essential residue, but not the nonessential one, against the modification by these reagents. By resolving the sulfhydryl-modified cyanocobalamin-enzyme complex, the enzyme activity was recovered, irrespective of treatment with dithiothreitol. From these results, we can conclude that diol dehydrase has two reactive sulfhydryl groups, one of which is essential for catalytic activity and located at or in close proximity to the coenzyme binding site. The other is nonessential for activity. Neitherp-chloromercuribenzoate- nor DTNB-modified apoenzyme was able to bind cyanocobalamin, whereas the iodoacetamide- and N-ethylmaleimide-modified apoenzyme only partially lost the ability to bind cyanocobalamin. The inactivation of diol dehydrase by p-chloromercuribenzoate and DTNB did not bring about dissociation of the enzyme into subunits. Total number of the sulfhydryl groups of this enzyme was 14 when determined in the presence of 6 m guanidine hydrochloride. No disulfide bond was detected.     

Large-scale preparation and reconstitution of apo-flavoproteins with special reference to butyryl-CoA dehydrogenase from Megasphaera elsdenii. Hydrophobic-interaction chromatography

A new method is described for the large-scale reversible dissociation of flavoproteins into apoprotein and prosthetic group using hydrophobic-interaction chromatography. Lipoamide dehydrogenase from Azotobacter vinelandii and butyryl-CoA dehydrogenase from Megasphaera elsdenii are selected to demonstrate the usefulness of the method. In contrast to conventional methods, homogeneous preparations of apoproteins in high yields are obtained. The apoproteins show high reconstitutability. The holoenzymes are bound to phenyl-Sepharose CL-4B at neutral pH in the presence of ammonium sulfate. FAD is subsequently removed at pH 3.5-4.0 by addition of high concentrations of KBr. Large amounts of apoenzymes (200-500 mg), showing negligible residual activity, are eluted at neutral pH in the presence of 50% ethylene glycol. The holoenzyme of lipoamide dehydrogenase can be reconstituted while the apoprotein is still bound to the column or the apoenzyme can be isolated in the free state. In both cases the yield and degree of reconstitution of holoenzyme is more than 90% of starting material. Apo-lipoamide-dehydrogenase exists mainly as a monomer in solution and reassociates to the native dimeric structure in the presence of FAD. The apoenzyme is stable for a long period of time when kept in 50% ethylene glycol at -18 degrees C. Steady-state fluorescence-polarization measurements of protein-bound FAD indicate that reconstituted lipoamide dehydrogenase possesses a high stability which is governed by the low dissociation rate constant of the apoenzyme-FAD complex. The holoenzyme of butyryl-CoA dehydrogenase cannot be reconstituted when the apoenzyme is bound to the column. However, stable apoprotein can be isolated in the free state yielding 50-80% of starting material, depending on the immobilization conditions. The coenzyme A ligand present in native holoenzyme is removed during apoprotein preparation. The apoenzyme is relatively stable when kept in 50% ethylene glycol at -18 degrees C. From kinetic and gel filtration experiments it is concluded that the reconstitution reaction of butyryl-CoA dehydrogenase is governed by both the pH-dependent hydrodynamic properties of apoenzyme and the pH-dependent stability of reconstituted enzyme. At pH 7, the apoenzyme is in equilibrium between dimeric and tetrameric forms and reassociates to a native-like tetrameric structure in the presence of FAD. The stability of reconstituted enzyme is strongly influenced by the presence of CoA ligands as shown by fluorescence-polarization measurements. The degree of reconstitution of butyryl-CoA dehydrogenase is more than 80% of the original specific activity under certain conditions.(ABSTRACT TRUNCATED AT 400 WORDS)     

人胎盘谷胱甘肽S-转移酶中巯基的研究

 用巯基试剂5.5'-二硫双(2-硝基苯甲酸)(DTNB)测得人胎盘谷胱甘肽S-转移酶(GST-π)的总巯基数为每亚基2个,均为表面巯基,,其中一个与DTNB反应快,被修饰后可导致酶活力全部丧失。另一巯基与DTNB反应较慢,可能与酶活力无关。用在12℃测定剩余巯基和Stallcup-Koshland作图法求得DTNB修饰快反应和慢反应巯基的速度常数分别为44056和162min~(-1)(mol/L)~(-1)。底物谷胱甘肽的衍生物S-正辛烷谷胱甘肽(S-o-GSH)能保护GST-π能保护的快反应巯基免受DTNB的修饰,使反应速度常数随着S-o-GSH浓度的增高而降低。S-o-GSH也能保护酶被N-乙基马来酰亚胺(NEMI)修饰失活,但不能保护慢反应巯基被DTNB修饰。另一底物2,4-二硝基氯苯(CDNB)对NEMI的修饰失活没有保护作用。上述结果提示快反应巯基参与GST-π和谷胱甘肽的结合,是组成活性中心的重要基因。     

Modification of the catalytic and regulatory properties of beef heart AMP-deaminase by DTNB treatment

In beef heart AMP-deaminase (EC 3.5.4.6.), 7 SH-groups out of 26 half-cysteine residues in the protein molecule have been shown to be accessible to alkylation by DTNB in the absence of ATP. The addition of ATP showed that only 6 SH-groups were accessible. DTNB-modified enzyme showed about 30% of the native catalytic activity but no sensitivity to the ATP-activating effect. Almost full reactivation of the modified enzyme and the restoration of the activatory effect of ATP could be achieved by exhaustive dialysis against mercaptoethanol.     

Electrochemical and enzymatic activity of flavin adenine dinucleotide and glucose oxidase immobilized by adsorption on carbon

Flavin adenine dinucleotide (FAD) and glucose oxidase were adsorbed on medium porosity spectroscopic graphite (SG) and on low porosity glassy carbon (GC) with retention of electrochemical activity, as measured by cyclic and differential pulse voltammetry. Adsorption on the SG was very strong, while that on GC was much weaker. Enzyme activity could be partially restored by the addition of the apoenzyme of glucose oxidase to the SG-adsorbed FAD preparation. The holoenzyme of glucose oxidase also was adsorbed on SG with retention of enzyme activity. The mechanism for the reconstitution of active enzyme from adsorbed FAD and soluble apoenzyme is not clear. The data suggest that the reconstituted enzyme stays adsorbed to the SG, but it is not clear whether the FAD or protein portions (or both) are adsorbed after reconstitution. The data also indicate that substrate mass transfer resistance may be important with the reconstituted-adsorbed enzyme.     

GroE dependence of refolding and holoenzyme formation of 6-hydroxy-D-nicotine oxidase.

In Escherichia coli cells expressing 6-hydroxy-D-nicotine oxidase (6-HDNO), a flavoprotein with covalently bound FAD, approximately 40% of the polypeptide is in its apoform. We investigated whether in vivo holoenzyme formation was influenced by the association of the apoenzyme with cellular chaperones. Immunoprecipitation of apoenzyme-containing cell extract with protein-A-Sepharose-bound 6-HDNO- or GroEL-specific antibodies failed to reveal the formation of complexes between these proteins. The limiting factor in holoenzyme formation in vivo appeared to be the intracellular supply of phosphorylated tricarbon compounds (e.g. glycerol-3-P) acting as allosteric effectors in the flavinylation reaction. When holoenzyme formation from purified apo6-HDNO was investigated in vitro, addition of GroEL and GroES to the reaction assays increased the yield of holoenzyme formation. The observed increase in apoenzyme to holoenzyme transition was ATP independent, and the effect of GroE could be simulated by high concentrations of glycerol (40%). Apparently, a nonspecific protein-protein interaction between the GroE proteins and the apo6-HDNO favored holoenzyme formation. The refolding of guanidinium hydrochloride-unfolded holoenzyme, however, was catalyzed by GroEL and GroES in an ATP-dependent reaction. Recovery of the native, enzymatically active, conformation ranged from 30 to 40%. When apo6-HDNO was denatured and refolded, the same dependence on GroE and ATP was observed in the recovery of a conformation able to incorporate FAD and to holoenzyme. [14C] FAD in the refolding assay yielded radioactively labeled 6-HDNO demonstrating the autocatalytical covalent incorporation of FAD into the polypeptide during the folding process.     

Modification of the Cl−-activated arginine aminopeptidases from rat liver and human erythrocytes: A comparative study

The amino acid residues important for the catalytic activity of the Cl^?-activated arginine aminopeptidases from human erythrocytes and rat liver were studied using enzyme modification. The general inhibition characteristics were similar with both enzymes. Inactivation with 5,5′-dithiobis-(2-nitrobenzoic acid) revealed one essential SH-group per active enzyme unit in both aminopeptidases. l-Arginyl-l-phenylalanine and N-l-arginyl-2-naphthylamide protected the enzymes against inactivation by DTNB, the former substrate being more effective. The rat liver enzyme was more sensitive to DTNB than the erythrocyte enzyme. Titration with DTNB revealed only fast reacting SH-groups in rat liver APB (mean 7.8). The erythrocyte enzyme, however, revealed SH-groups which reacted fast with low concentrations of DTNB, while high concentrations of DTNB or SDS treatment were needed to reveal all enzyme SH-groups (mean 8.0). The presence of at least one essential imidazole group in the erythrocyte enzyme was indicated by photooxidation in the presence of methylene blue, as previously found with the rat liver enzyme (5., 22.). The pH dependence curves of both enzymes also supported the presence of SH- and imidazole groups at or near the active site. Thus, the functional groups identified were the same for both enzymes. Neither enzyme had essential COOH or arginyl groups and they did not contain any zinc. The absence of Zn suggests that the reaction mechanism recently presented by other authors, based on the presence of Zn in the active center, does not apply to the Cl^?-activated arginine aminopeptidases. Accordingly, this enzyme group cannot be classified to metallopeptidases.