Altered serum alpha-D-mannosidase activity in mucolipidosis II and mucolipidosis III.

Normal human serum contains at least three forms of α-D-mannosidase: an acidic form which has a pH optimum of 4.25, is inhibited by Co²⁺ and is thermostable; an intermediate form, which has a pH optimum of 5.6–5.7, is stimulated by Co²⁺ and is heat labile at 50°C; and a neutral form with a pH optimum of 6.0–6.5. In Mucolipidosis II and III sera, the acidic α-mannosidase activity persists while the intermediate activity is absent or altered. Heating the serum does not affect the pH activity curve, the electrofocusing profile or the response to Co²⁺ of α-mannosidase. During heat inactivation at 55°, 90–100% of the pH 5.6 α-mannosidase activity is lost in normal sera while less than 40% is lost from ML sera. The effect on sera from ML obligate heterozygotes is intermediate. The absent or altered intermediate mannosidase may be responsible for aberrant biochemical properties reported for other glycosidases in Mucolipidosis II and Mucolipidosis III.     

Novel alpha-D-mannosidase of rat sperm plasma membranes: characterization and potential role in sperm-egg interactions

During the course of a study of glycoprotein processing mannosidases in the rat epididymis, we have made an intriguing discovery regarding the presence of a novel alpha-D-mannosidase on the rat sperm plasma membranes. Unlike the sperm acrosomal "acid" mannosidase which has a pH optimum of 4.4, the newly discovered alpha-D-mannosidase has a pH optimum of 6.2, and 6.5 when assayed in sperm plasma membranes and intact spermatozoa, respectively. In addition, the two enzymes show different substrate specificity. The acrosomal alpha-D-mannosidase is active mainly towards synthetic substrate, p-nitrophenyl alpha-D-mannopyranoside, whereas the sperm plasma membrane alpha-D-mannosidase shows activity mainly towards mannose-containing oligosaccharides. Evidence is presented which suggest that the sperm plasma membrane alpha-D-mannosidase is different from several processing mannosidases previously characterized from the rat liver. The newly discovered alpha-D-mannosidase appears to be an intrinsic plasma membrane component, since washing of the purified membranes with buffered 0.4 M NaCl did not release the enzyme in soluble form. The enzyme requires nonionic detergent (Triton X-100) for complete solubilization. The enzyme is activated by Co2+ and Mn2+. However, Cu2+ and Zn2+ are potent inhibitors of the sperm plasma membrane alpha-D-mannosidase. At a concentration of 0.1 mM, these divalent cations caused nearly complete inactivation of the sperm enzyme. In addition methyl-alpha-D-mannoside, methyl-alpha-D-glucoside, mannose, 2-deoxy-D-glucose, and D-mannosamine are inhibitors of the sperm surface alpha-D-mannosidase. The physiological role of the newly discovered enzyme is not yet known. Several published reports in three species, including the rat, suggest that the sperm surface alpha-D-mannosidase may have a role in binding to mannose-containing saccharides presumably present on the zona pellucida.     

Characterization of a novel alpha-D-mannosidase from rat brain microsomes

A new alpha-D-mannosidase has been identified in rat brain microsomes. The enzyme was purified 70-100-fold over the microsomal fraction by solubilization with Triton X-100, followed by ion exchange, concanavalin A-Sepharose, and hydroxylapatite chromatography. The purified enzyme is very active towards mannose-containing oligosaccharides and has a pH optimum of 6.0. Unlike rat liver endoplasmic reticulum alpha-D-mannosidase and both Golgi mannosidases IA and IB, which have substantial activity only towards alpha 1,2-linked mannosyl residues, the brain enzyme readily cleaves alpha 1,2-, alpha 1,3-, and alpha 1,6-linked mannosyl residues present in high mannose oligosaccharides. The brain enzyme is also different from liver Golgi mannosidase II in that it hydrolyzes (Man)5GlcNAc and (Man)4GlcNAc without their prior N-acetylglucosaminylation. Moreover, the facts that the ability of the enzyme to cleave GlcNAc(Man)5GlcNAc, the biological substrate for Golgi mannosidase II, is not inhibited by swainsonine, and that p-nitrophenyl alpha-D-mannoside is a poor substrate provide further evidence for major differences between the brain enzyme and mannosidase II. Inactivation studies and the co-purification of activities towards various substrates suggest that a single enzyme is responsible for all the activities found. In view of these results, it seems possible that, in rat brain, a single mannosidase cleaves asparagine-linked high mannose oligosaccharide to form the core Man3GlcNAc2 moiety, which would then be modified by various glycosyl transferases to form complex type glycoproteins.     

Characterization of multiple forms of phosphoinositide-specific phospholipase C from bovine aorta.

Three forms (I, II and III) of phospholipase C were separated from the cytosol of bovine aorta by chromatography on Blue Sepharose. All three forms showed an increase of enzyme activity when free Ca2+ in the assay was raised between 40 microM and 9 mM. The pH optimum was in the range of 6.0 to 6.5 for each subtype. Marked differences in thermostability were found when the three enzyme forms were pre-incubated at 50 degrees C prior to the assay. All three forms were able to hydrolyse phosphatidylinositol as well as phosphatidylinositol 4-phosphate and phosphatidylinositol 4,5-bisphosphate. In contrast, when phosphatidylcholine was used as substrate, no enzyme activity was observed. Spermine and spermidine, but not putrescine, were able to stimulate form I and III; neomycin sulphate inhibited all three subtypes.     

Properties of acid beta-N-acetyl-D-glucosaminidase from cock semen.

Two forms (I and II) of beta-N-acetyl-D-glucosaminidase from cock seminal plasma and one form (III) from spermatozoa were separated by chromatofocusing. The active enzyme forms I and II had pI values of 6.6 and 6.3, respectively, while form III had two subforms with pI values of 6.3 and 6.1, as determined by polyacrylamide gel electrofocusing. The molecular weights were 76,000 for forms I and III and 32,000 for form II. The optimum pH of enzyme forms I and III ranged from 3.6 to 4.0. In contrast, form II showed one distinct maximum at pH 3.7. The Km values obtained with p-nitrophenyl-beta-N-acetyl-D-glucosaminide as substrate were 0.35, 0.28, and 0.39 mM for forms I, II, and III, respectively. It is assumed that both cock spermatozoa and cock seminal plasma contain a common, enzymatically active beta-N-acetyl-D-glucosaminidase subunit with M(r) about 32,000 and pI 6.3.     

Cyclic nucleotide phosphodiesterase in silkworm. Separation and characterization of multiple forms of the enzyme.

The existence of two forms of cyclic AMP phosphodiesterase (3',5'-cyclic AMP 5'-nucleotidohydrolase, EC 3.1.4.17) was demonstrated in silkworm larvae by kinetic analysis and DEAE-cellulose column chromatography. The two forms of the enzyme (phosphodiesterase II and III) differ apparently in their characteristics from the previously reported cyclic nucleotide phosphodiesterase (phosphodiesterase I) of silkworm. The higher K-m form (phosphodiesterase II) has a molecular weight of approx. 50 000 and optimum pH of 7.8, and requires Mn-2-+ for maximum activity. The lower K-m form (phosphodiesterase III) has a molecular weight of approx. 97 000 and optimum pH of 7.2, and requires Mg-2-+ for maximum activity. Phosphodiesterase II and probably phosphodiesterase III are specific enzymes for the hydrolysis of cyclic AMP.     

Asparagine-linked glycoprotein biosynthesis in rat brain: identification of glucosidase I, glucosidase II, and and endomannosidase (glucosyl mannosidase)

Previous studies from this laboratory provided evidence, largely based upon the presence of a novel alpha-D-mannosidase, suggesting that the biosynthesis of N-linked glycoproteins may be different in brain as compared to other tissues (Tulsiani, D. R. P., and Touster, O. (1985) J. Biol. Chem. 260, 13,081-13,087). In the present report we describe studies on the enzymes involved in early processing reactions. These studies indicate that the brain, like other tissues, contains glucosidases I and II. The two glucosidases were separated as distinct activities with some overlapping by chromatography on a DE-52 column. The differential inhibition studies and substrate specificity studies support our conclusion that, as in other tissues, rat brain glucosidase I cleaves alpha 1,2-linked terminal glucosyl residues, whereas glucosidase II prefers alpha 1,3-linked glucosyl residues. In addition to these two processing glucosidases, we have characterized an endo enzyme (glucosyl mannosidase) in rat brain. The endomannosidase cleaves a disaccharide (glucosyl alpha 1,3-mannose) from monoglucosylated oligosaccharides (GlcMan7-9GlcNAc). Little or no activity was observed when di- or triglucosylated oligosaccharide was used as a substrate. The pH optimum of the glucosyl mannosidase is 6.2-6.8. The enzyme appears to be an intrinsic microsomal membrane component, since washing of the microsomal membranes with salt solution did not release the enzyme in soluble form. A mixture of Triton X-100 and sodium deoxycholate is required for complete solubilization of the enzyme. The solubilized enzyme is eluted from a Bio-Gel A-1.5m column as a single peak with an apparent molecular weight of 380,000.     

Three forms of DNA polymerase from Drosophila melanogaster embryos. Purification and properties.

DNA polymerase was purified from Drosophila melanogaster embryos by a combination of phosphocellulose adsorption, Sepharose 6B gel filtration, and DEAE-cellulose chromatography. Three enzyme forms, designated enzymes I, II, and III, were separated by differential elution from DEAE-cellulose and were further purified by glycerol gradient centrifugation. Purification was monitored with two synthetic primer-templates, poly(dA) . (dT)-16 and poly(rA) . (dT)-16. At the final step of purification, enzymes I, II, and III were purified approximately 1700-fold, 2000-fold and 1000-fold, respectively, on the basis of their activities with poly(dA) . (dT)-16. The DNA polymerase eluted heterogeneously as anomalously high-molecular-weight molecules from Sepharose 6B gel filtration columns. On DEAE-cellulose chromatography enzymes I and II eluted as distinct peaks and enzyme III eluted heterogeneously. On glycerol velocity gradients enzyme I sedimented at 5.5-7.3 S, enzyme II sedimented at 7.3-8.3 S, and enzyme III sedimented at 7.3-9.0 S. All enzymes were active with both synthetic primer-templates, except the 9.0 S component of enzyme III, which was inactive with poly(rA) . (dT)-16. Non-denaturing polyacrylamide gel electrophoresis did not separate poly(dA) . (dT)-16 activity from poly(rA) . (dT)-16 activity. The DNA polymerase preferred poly(dA) . (dT)-16 (with Mg2+) as a primer-template, although it was also active with poly(rA) . (dT)-16 (with Mn2+), and it preferred activated calf thymus DNA to native or heat-denatured calf thymus DNA. All three primer-template activities were inhibited by N-ethylmaleimide. Enzyme activity with activated DNA and poly(dA) . (dT)-16 was inhibited by K+ and activity with poly(rA) . (dT)-16 was stimulated by K+ and by spermidine. The optimum pH for enzyme activity with the synthetic primer-templates was 8.5. The DNA polymerases did not exhibit deoxyribonuclease or ATPase activities. The results of this study suggest that the forms of DNA polymerase from Drosophila embryos have physical properties similar to those of DNA polymerase-alpha and enzymatic properties similar to those of all three vertebrate DNA polymerases.     

alpha-D-mannopyranosylmethyl-p-nitrophenyltriazene inhibition of rat liver alpha-D-mannosidases

The compound alpha-D-mannopyranosylmethyl-p-nitrophenyltriazene (alpha-ManMNT) has been tested for its effect on four alpha-D-mannosidase activities present in rat liver. When p-nitrophenyl alpha-D-mannopyranoside was used as a substrate, preincubation of enzyme with 1.0 mM alpha-ManMNT inhibited soluble alpha-D-mannosidase by 90%, lysosomal alpha-D-mannosidase by approx. 60%, and had virtually no effect on Golgi mannosidase II. Golgi mannosidase I removal of the four alpha-1,2-linked D-mannoses from the common Man9GlcNAc2 oligosaccharide structure formed during N-linked glycoprotein biosynthesis was also blocked by treatment of the Golgi fraction with this compound. Mannosyltriazene inhibition of the three susceptible hepatic alpha-D-mannosidases was largely irreversible. alpha-ManMNT should therefore be useful for studying oligosaccharide processing and possibly for determining the turnover time of the inhibited alpha-D-mannosidases.     

Isolation and properties of three forms of phosphorylase and phosphorylase kinase from human skeletal muscle]

Three forms of phosphorylase (I, II and III), two of which (I and II) were active in the presence of AMP and one (III) was active without AMP, were isolated from human skeletal muscles. The pI values for phosphorylases b(I) and b(II) were found to be identical (5.8-5.9). During chromatofocusing a low molecular weight protein (M(r) = 20-21 kDa, pI 4.8) was separated from phosphorylase b(II). This process was accompanied by an increase of the enzyme specific activity followed by its decline. During reconstitution of the complex the activity of phosphorylase b(II) returned to the initial level. Upon phosphorylation the amount of 32P incorporated into phosphorylase b(II) was 2 times as low as compared with rabbit phosphorylase b and human phosphorylase b(I). It may be supposed that in the human phosphorylase b(II) molecule one of the two subunits undergoes phosphorylation in vivo. This form of the enzyme is characterized by a greater affinity for glycogen and a lower sensitivity to allosteric effectors (AMP, glucose-6-phosphate, caffeine) compared with phosphorylase b(I). Thus, among the three phosphorylase forms obtained in this study, form b(II) is the most unusual one, since it is partly phosphorylated by phosphorylase kinase to form a complex with a low molecular weight protein which stabilizes its activity. A partially purified preparation of phosphorylase kinase was isolated from human skeletal muscles. The enzyme activity necessitates Ca2+ (c0.5 = 0.63 microM). At pH 6.8 the enzyme is activated by calmodulin (c0.5 = 15 microM). The enzyme activity ratio at pH 6.8/8.2 is equal to 0.18.     

Kinetic properties of phosphoenolpyruvate carboxylase from lupin nodules and roots

The kinetic properties of two forms of phosphoenolpyruvate carboxylase (PEPC I and PEPC II, EC 4.1, 1.31) from lupin ( Lupinus luteus L. cv. Ventus) nodules and one enzyme form (PEPC III) from roots were studied. The Michaelis constant (K_m) values for PEP, Mg²⁺ and especially HCO₃⁻were lower for PEPC I. Kinetic studies showed that aspartate is a competitive inhibitor at pH 7.2 and inhibitor constant (K_i) values are different for the three forms of PEPC. Malate is a competitive inhibitor for PEPC I and PEPC III and shows mixed-type inhibition for PEPC II. Malate inhibition is dependent upon the pH of the assay. Different effect of several metabolites was also observed. The temperature optimum was near 39°C for PEPC I and around 43°C for PEPC II and PEPC III. PEPC I appeared to be the most thermolabile. It is suggested that PEPC I from lupin nodules is closely associated with N₂ fixation.     

beta-N-acetylhexosaminidase isoenzymes during chick embryo development

1. Two forms (I and II) with acidic pH optima and a neutral form of beta-hexosaminidase has been separated by DEAE-cellulose chromatography and characterized in skin and lung of 7, 9, 11, 14 day chick embryos and 1 day old chicken. 2. Forms I and II are similar to hexosaminidase A and B for their behaviour on DEAE-cellulose chromatography, Concanavalin A-Sepharose column and thermal stability. 3. Neutral form has a neutral pH optimum and higher molecular weight and a more acidic I. P. than forms I and II, a low beta-N-acetylgalactosaminidase activity and it is not bound by a Concanavalin A-Sepharose column and in that resemble hexosaminidase C and/or other neutral hexosaminidases. 4. We have found differences in the percentage of neutral form and in the specific activities of the extracts in the skin in different stages of development. 5. No significant differences were observed in the lung.     

Characterization of three enzymatic forms of glucose-6-phosphate dehydrogenase from Aspergillus oryzae

Three forms (I, II and III) of glucose-6-phosphate dehydrogenase were isolated from mycelium of Aspergillus oryzae grown on ribose as the carbon source, by ion-exchange chromatography. The Km values determined for the three forms with respect to glucose-6-phosphate were nearly identical; however the Km for NADP+ were different and the Vmax for the isoenzymatic form II was higher than those for I and III. Inhibition by NADPH was competitive with respect to NADP+, isoenzyme II showing the highest Ki. The optimum pH for forms I, II and III were 9.0, 8.0 and 8.5, respectively, and form I was more thermostable than the others. The apparent molecular weights, determined by gel filtration, were 92,000, 117,500 and 141,000 for forms I, II and III, respectively.     

Separation and Characterization of Four Forms of β-N-Acetylhexosaminidase from Chicken Brain

Chicken brain beta-N-acetylhexosaminidases from embryos (16 and 21 days old), newborns (1 and 4 days old), and adults (3 1/2 months and 2 years old) were separated into four different forms by ion exchange chromatography on diethylaminoethyl-cellulose. Three of these forms were "acid" hexosaminidases (I, IIA, and IIB), and the fourth was a "neutral" form. Throughout development of the chicken, forms IIA and III maintained the same activity ratio, whereas that for form I decreased and that for form IIB showed an increase.     

Resolution of myocardial phospholipase C into several forms with distinct properties.

Phospholipase C activity capable of hydrolysing phosphatidylinositol in bovine heart was resolved into four forms (I-IV) by ion-exchange chromatography. Some of these forms could only be detected if the assay was performed at acidic pH (I and IV) or in the presence of deoxycholate (II). Gel-filtration chromatography indicated that the four forms had different molecular weights in the range 40000-120000. I, II and III all had pH optima in the range 4.5-5.5. However, the major form (III) also had substantial activity at pH 7.0 and above. The activities of I, II and III at pH 7.0 were stimulated by deoxycholate; this effect was most marked with I and II, which had very low activity at this pH. All forms of the enzyme were inhibited by EGTA and required 2-5 mM-CaCl2 for maximal activity. When the fractions eluted from the ion-exchange and gel-filtration columns were assayed with polyphosphoinositides as substrates there was a close correspondence to the elution profile obtained with phosphatidylinositol as substrate; there was no evidence for the existence in heart of phospholipase C activities specific for individual phosphoinositides.     

The identification and biosynthesis of siderochromes formed by Micrococcus denitrificans.

1. Micrococcus denitrificans excretes three catechol-containing compounds, which can bind iron, when grown aerobically and anaerobically in media deficient in iron, and anaerobically in medium with a high concentration of Ca2+. 2. One of these compounds was identified as 2,3-dihydroxybenzoic acid (compound I), and the other two were tentatively identified as N1N8-bis-(2,3-dihydroxybenzoyl)spermidine (compound II) and 2-hydroxybenzoyl-N-L-threonyl-N4[N1N8-bis-(2,3-dihydroxybenzoyl)]spermidine (compound III). 3. The equimolar ferric complex of compound III was prepared; compound III also forms complexes with Al3+, Cr3+ and Co2+ ions. 4. Cell-free extracts from iron-deficient organisms catalyse the formation of compound II from 2,3-dihydroxybenzoic acid and spermidine, and of compound III from compound II, L-threonine and 2-hydroxybenzoic acid; both reactions require ATP and dithiothreitol, and Mg2+ stimulates activity. The enzyme system catalysing the formation of compound II has optimum activity at pH 8.8 Fe2+ (35muM), Fe3+ (35muM) and Al3+ (65muM) inhibit the reaction by 50 percent. The enzyme system forming compound III has optimum activity at pH 8.6. Fe2+ (110 muM), Fe3+ (110 muM) and Al3+ (135 muM) inhibit the reaction by 50 percent. 5. At least two proteins are required for the formation of compound II, and another two proteins for its conversion into compound III. 6. The changes in the activities of these two systems were followed after cultures became deficient in iron. 7. Ferrous 1,10-phenanthroline is formed when a cell-free extract from iron-deficient cells is incubated with the ferric complex of compound III, succinate, NADH and 1,10-phenanthroline under N2.     

Forms and intracellular distribution of alpha-D-mannosidases in murine liver and spleen

1. The intracellular distribution of alpha-D-mannosidase in homogenates of murine liver and spleen was investigated by differential and gradient density centrifugation. 2. In both tissues an enzyme with a neutral pH optimum was found in the cytosol together with an alpha-D-mannosidase with optimal activity between pH 5.5 and 6.0 which was also partially membrane-bound. 3. In liver the acidic alpha-D-mannosidase was obtained almost entirely in a particulate form distributed equally between a heterogeneous low density region and heavy density lysosomes. 4. The lysosomal form of the liver enzyme was purified to electrophoretic homogeneity and shown to be a glycoprotein composed of four identical subunits of molecular weight 65 kDa. 5. Antibody raised against the purified liver alpha-D-mannosidase immunoprecipitated a polypeptide from spleen which had the same molecular size. This acidic enzyme was the predominant type of alpha-D-mannosidase in spleen, but in contrast to liver, it was obtained mainly in a cytosoluble form, the remaining activity being present in the heterogeneous light density compartment. 6. Although both tissues contain the same molecular form of the acidic alpha-D-mannosidase, in murine spleen this enzyme does not appear to be associated with stable heavy density lysosomes.     

Different molecular forms of D-ribulose-1,5-bisphosphate carboxylase from Rhodopseudomonas sphaeroides.

Ribulose-1,5-bisphosphate (Rbu-P2) carboxylase isolated from Rhodopseudomonas sphaeroides 2.4.1.Ga was separated into two different forms by DEAE-cellulose column chromatography. Both forms, designated Peak I and Peak II have been purified to homogeneity by the criterion of polyacrylamide disc-gel electrophoresis. The Peak I carboxylase has a molecular weight of 550,000, while the Peak II carboxylase is a smaller protein having a molecular weight of approximately 360,000. Sodium dodecyl sulfate electrophoresis revealed a large subunit for both enzymes which migrates similarly to the large subunit of spinach Rbu-P2 carboxylase. The Peak I enzyme also exhibited a small subunit having a molecular weight of 11,000. No evidence for a smaller polypeptide was found associated with the Peak II enzyme. Antisera prepared against the Peak I enzyme inhibited Peak I enzymatic activity, but had no effect on the activity of the Peak II enzyme. The two enzymes exhibited marked differences in catalytic properties. The Peak I enzyme exhibits optimal activity at pH 8.0 and is inhibited by low concentrations of 6-phosphogluconate, while the Peak II enzyme has a pH optimum of 7.2 and is relatively insensitive to 6-phosphogluconate.     

Interconversion of multiple forms of tyrosine aminotransferase in vitro and in vivo in cultured hepatoma cells.

Corticosteroid-induced tyrosine aminotransferase (EC 2.6.1.5) from cultured hepatoma cells was separated by carboxymethyl-Sephadex chromatography into three molecular forms resembling those described previously in the rat liver. Enzyme forms were isolated and used as purified substrates to examine their in vitro interconversion by various subcellular fractions. Isolated form III was converted to forms II and I, and isolated form II was converted to form I by the coarse particulate fraction sedimenting at 1000 X g. This activity was inhibited by the serine enzyme inhibitor phenylmethane sulfonyl fluoride or by raising the pH to 8.7. Conversion of enzyme forms in vitro in the opposite direction (I leads to II leads to III) could not be detected. The distribution of enzyme forms in vivo was examined by the use of experimental conditions that prevent their in vitro interconversion during cell extraction. Tyrosine aminotransferase extracted from cell subjected to various treatments that affect the rates of enzyme synthesis or degradation existed always predominantly as form III. It appears, therefore, that multiple forms of tyrosine aminotransferase are not related to the turnover of this enzyme in vivo.     

Partial Purification and Characterization of Three NAD(P)H Dehydrogenases from Beta vulgaris Mitochondria

Mitochondria isolated from the taproot of beet (Beta vulgaris) were used in an effort to identify and partially purify the proteins constituting the exogenous NADH dehydrogenase. Three NAD(P)H dehydrogenases are released from these mitochondria by sonication, and these enzymes were partially purified using fast protein liquid chromatography. One of the enzymes, designated peak I, is capable of oxidizing NADPH and the β form of NADH. The other two activities, peaks II and III, oxidize only β-NADH. All three peaks are insensitive to divalent cation chelators and a complex I inhibitor, rotenone. The major component to peak I is a polypeptide with an apparent molecular mass of approximately 42 kilodaltons. Peak I activity was insensitive to platanetin, a specific inhibitor of the exogenous dehydrogenase, and insensitive to added Ca²⁺ or Mg²⁺. Peak I displayed a broad pH activity profile with an optimum between 7.5 and 8.0 for both NADPH and NADH. Purified peak II gave a single polypeptide of about 32 kilodaltons, had a pH optimum between 7.0 and 7.5, and was slightly stimulated by Ca²⁺ and Mg²⁺. As with peak I, platanetin had no effect on peak II activity. Peak III was not purified completely, but contained two major polypeptides with apparent molecular masses of 55 and 40 kilodaltons. This enzyme was not affected by Ca²⁺ and Mg²⁺, but was inhibited by platanetin. The peak III enzyme had a rather sharp pH optimum of approximately 6.5 to 6.6. The above data indicate that peak III activity is likely the exogenous NADH dehydrogenase.