Expression of membrane-bound dehydrogenases from a mother of vinegar metagenome in Gluconobacter oxydans

Acetic acid bacteria are well-known for their membrane-bound dehydrogenases rapidly oxidizing a variety of substrates in the periplasm. Since many acetic acid bacteria have not been successfully cultured in the laboratory yet, studying membrane-bound dehydrogenases directly from a metagenome of vinegar microbiota seems to be a promising way to identify novel variants of these enzymes. To this end, DNA from a mother of vinegar was isolated, sequenced, and screened for membrane-bound dehydrogenases using an in silico approach. Six metagenomic dehydrogenases were successfully expressed using an expression vector with native promoters in the acetic acid bacterium strain Gluconobacter oxydans BP.9, which is devoid of its major native membrane-bound dehydrogenases. Determining the substrates converted by these enzymes, using a whole-cell DCPIP assay, revealed one glucose dehydrogenase with an enlarged substrate spectrum additionally oxidizing aldoheptoses, D-ribose and aldotetroses, one polyol dehydrogenase with an extreme diminished spectrum but distinguishing cis and trans-1,2-cyclohexandiol and a completely new secondary alcohol dehydrogenase, which oxidizes secondary alcohols with a hydroxyl group at position 2, as long as no primary hydroxyl group is present. Three further dehydrogenases were found with substrate spectra similar to known dehydrogenases of G. oxydans 621H.

     

Purification and Properties of Primary and Secondary Alcohol Dehydrogenases from Thermoanaerobacter ethanolicus

Thermoanaerobacter ethanolicus (ATCC 31550) has primary and secondary alcohol dehydrogenases. The two enzymes were purified to homogeneity as judged from sodium dodecyl sulfate-polyacrylamide gel electrophoresis and gel filtration. The apparent M_rs of the primary and secondary alcohol dehydrogenases are 184,000 and 172,000, respectively. Both enzymes have high thermostability. They are tetrameric with apparently identical subunits and contain from 3.2 to 5.5 atoms of Zn per subunit. The two dehydrogenases are NADP dependent and reversibly convert ethanol and 1-propanol to the respective aldehydes. The V_m values with ethanol as a substrate are 45.6 μmol/min per mg for the primary alcohol dehydrogenase and 13 μmol/min per mg for the secondary alcohol dehydrogenase at pH 8.9 and 60°C. The primary enzyme oxidizes primary alcohols, including up to heptanol, at rates similar to that of ethanol. It is inactive with secondary alcohols. The secondary enzyme is inactive with 1-pentanol or longer chain alcohols. Its best substrate is 2-propanol, which is oxidized 15 times faster than ethanol. The secondary alcohol dehydrogenase is formed early during the growth cycle. It is stimulated by pyruvate and has a low K_m for acetaldehyde (44.8 mM) in comparison to that of the primary alcohol dehydrogenase (210 mM). The latter enzyme is formed late in the growth cycle. It is postulated that the secondary alcohol dehydrogenase is largely responsible for the formation of ethanol in fermentations of carbohydrates by T. ethanolicus.     

Purification of two alcohol dehydrogenases from Zymomonas mobilis and their properties

Summary Two alcohol dehydrogenases (ADHI and ADHII, EC 1.1.1.1) were purified to homogeneity from the cell extract of Zymomonas mobilis. The subunit molecular weights of ADHI and ADHII were 40,000 and 38,000, respectively, and both enzymes were homologous dimers. The optimal pHs of ADHI in ethanol oxidation and acetaldehyde reduction reactions were 9.5 and 4.5, and those of ADHII were 9.5 and 6.5, respectively. The optimal temperatures of ADHI and ADHII were 55° C and 45° C, respectively. ADHI was heat-inactivated at 65° C at a 10-fold higher rate than ADHII. ADHI and ADHII were inhibited by 4 M and 1 mM p-chloromercuribenzoate, respectively, and the inhibitions were reversed by the addition of 70 mM 2-mercaptoethanol. ADHII activity was enhanced by 0.02 to 2 mM CoCl₂ and inhibited by 0.4 mM o-phenanthroline; and the activity of inactivated ADHII was restored by addition of 1 mM CoCl₂ or ZnCl₂.ADHI was active on most primary alcohols but not secondary alcohols. ADHII was active on only ethanol, n-propanol, allylalcohol, and furfuryl alcohol.In the anaerobic culture of Z. mobilis, ADHII activity accounted for more than 80% of total alcohol dehydrogenase activity. In aerobic culture, ADHII was the main enzyme but was produced only in the early growth phase.     

Effects of 17β-estradiol on the distribution and activity of some oxydative enzymes of uterine and cervical epithelium in neonatal mice

Summary The following enzymes were studied histochemically in uterine and cervical epithelium from neonatal mice treated with 17-estradiol for the first four days after birth: NADH-, NADPH-, succinate-, -glycerophosphate-, lactate-, glucose-6-phosphate-, and 17-OH-steroid dehydrogenases.It was demonstrated that estradiol administration had a marked influence on distribution and activity of several of the enzymes compared with the control animals. In cervix there was an increase of activity for most of the enzymes, especially in the apical parts of the epithelium cells. The uterine epithelium was also estradiol sensitive as regards most enzymes, and in the case of glucose-6-phosphate dehydrogenase there was a dramatic enhancement of reaction in the uterus of the experimental animals. The differences obtained between cervical and uterine epithelium are described.17-OH-steroid dehydrogenase could not be detected histochemically in the present material.Supported by the Norwegian Research Council for Science and the Humanities.     

SCOPE AND LIMITATIONS OF THE USE OF NICOTINOPROTEIN ALCOHOL DEHYDROGENASE FOR THE COENZYME-FREE PRODUCTION OF ENANTIOPURE FINE-CHEMICALS

Nicotinoprotein alcohol dehydrogenases are enzymes that contain non-dissociable NAD(P)(H) in the active site. The suitability of a nicotinoprotein alcohol dehydrogenase as coenzyme-independent alternative to classic alcohol dehydrogenases for enantioselective synthetic applications was studied. To this end the NADH-containing nicotinoprotein, np-ADH, from Rhodococcus erythropolis DSM 1069 was used as a model enzyme in different types of conversion: asymmetric synthesis, kinetic resolution and racemization. The enzyme was found to catalyze the asymmetric reduction of ketones using cheap reductants, such as ethanol, with high stereoselectivity, but the reaction was too slow to obtain good yields. Kinetic resolutions of racemic alcohols failed due to dismutation of the aldehyde that was used as cosubstrate. Racemization of a secondary alcohol via the corresponding ketone could not be achieved, which was due to an unidentified side reaction. This evaluation shows that, for developing biotransformations of industrial interest using nicotinoprotein alcohol dehydrogenases, the attention should be focused on enzymes with a higher reactivity towards prochiral ketones and secondary alcohols.     

Purification of Alcohol Dehydrogenase fromEntamoeba histolyticaandSaccharomyces cerevisiaeUsing Zinc-Affinity Chromatography

We have developed a single-step method for the purification of NADP⁺-dependent alcohol dehydrogenase fromEntamoeba histolyticaand NAD⁺-dependent alcohol dehydrogenase fromSaccharomyces cerevisiae.It is based on the affinity for zinc of both enzymes. The amebic enzyme was purified almost 800 times with a recovery of 54% and the yeast enzyme was purified 30 times with a recovery of 100%. The kinetic constants of the purified enzymes were similar to those reported for other purification methods. With mammalian alcohol dehydrogenase, we obtained a 40-kDa band suggestive of purified alcohol dehydrogenase, but we failed to retain enzymatic activity in this preparation. Our results suggest that the described method is more applicable to the purification of tetrameric alcohol dehydrogenases.     

Purification and characterization of threonine dehydrogenase from Clostridium sticklandii

Threonine dehydrogenase from Clostridium sticklandii has been purified 76-fold from cells grown in a defined medium to a homogeneous preparation of 234 units · mg^-1 protein. Purification was obtained by chromatography on Q-Sepharose fast flow and Reactive green 19-Agarose. The native enzyme had a molecular mass of 67 kDa and consisted of two identical subunits (33 kDa each). The optimum pH for catalytic activity was 9.0. Only l-threo-threo-nine, dl--hydroxynorvaline and acetoin were substrates; only NAD was used as the natural electron acceptor. The apparent K _m values for l-threonine and NAD were 18 mM and 0.1 mM, respectively. Zn²⁺, Co²⁺ and Cu²⁺ ions (0.9 mM) inhibited enzyme activity. The N-terminal amino acid sequence revealed similarities to the class of non-metal short-chain alcohol dehydrogenases, whereas the threonine dehydrogenase from Escherichia coli belongs to the class of medium chain, zinc-containing alcohol dehydrogenases.Abbreviations PMSF phenylmethylsulfonyl fluoride - Dea diethanolamine - Tris tris-(hydroxy-methyl)-aminomethane - Nbs ₂ 5,5-dithiobis-(2-nitrobenzoic acid) - ApADN 3-acetylpyridine adenine diucleotide - thio-NAD thionicotinamide adenine dinucleotide - NBT nitro blue tetrazolium chloride     

Two benzaldehyde dehydrogenases in bacterium N.C.I.B. 8250. Distinguishing properties and regulation

Evidence is presented for the existence in bacterium N.C.I.B. 8250 of two inducible NAD⁺-linked benzaldehyde dehydrogenases. They may be distinguished in crude extracts by their different thermal stabilities at high pH values, benzaldehyde dehydrogenase I being much more heat-stable than benzaldehyde dehydrogenase II. Only benzaldehyde dehydrogenase I is activated by K⁺ and certain other univalent cations. Gel-filtration experiments indicate that both enzymes have molecular weights of about 180000. Both enzymes are induced by growth on l-mandelate or phenylglyoxylate; only benzaldehyde dehydrogenase I is gratuitously induced by thiophenoxyacetate and only benzaldehyde dehydrogenase II is induced by benzyl alcohol, by benzaldehyde, and by a number of heterocyclic compounds which do not support growth. Mutants have been isolated that lack either benzaldehyde dehydrogenase II or benzyl alcohol dehydrogenase, or both of the enzymes. Results obtained in induction experiments with the wild-type bacterium N.C.I.B. 8250 and with the mutants show that benzaldehyde dehydrogenase II and benzyl alcohol dehydrogenase are co-ordinately regulated. Overall, the results suggest that benzaldehyde dehydrogenase I is associated with the metabolism of l-mandelate whereas benzaldehyde dehydrogenase II is associated with the metabolism of benzyl alcohol.     

Occurrence of inducible and NAD(P)-independent primary alcohol dehydrogenases in an alkane-oxidizingPseudomonas

Pseudomonas aeruginosa (strain 473) constitutively contains a soluble NADP-linked dehydrogenase active towards primary alcohols. In addition, at least two NAD(P)-independent primary alcohol dehydrogenases can be induced by growing this strain on primary alcohols,α,ω-diols orn-alkanes. These inducible enzymes were found to be bound to cellular structures. They reduce bovine cytochromec and various dyes, but not oxygen. The main difference between the inducible enzymes is their different capacity to oxidize ethanol. Noteworthy properties of the enzymes are:

1. the affinities for the straight-chain primary alcohols increase with increasing chain length (tested up to 1-decanol);
2. the affinities decrease when polar atoms or groups are introduced into the alcohol molecule;
3. enzyme preparations as well as intact cells, when provided with a mixture of alcohols, first oxidize the compound with the lowest solubility in water.

These properties can be explained by assuming that hydrophobic bonds are formed between the enzyme and aliphatic parts of the alcohol molecule.     

The inducible microsomal fatty alcohol oxidase of Candida (Torulopsis) apicola

In the transition phase of Candida apicola IMET 43747 from logarithmic to stationary growth a pyridine-nucleotide-independent alcohol oxidase was induced coinciding with the beginning of sophorose lipid production. This enzyme was not repressed by glucose and was measurable in stationary cells grown on glucose or on a mixture of n-hexadecane and glucose. An NAD⁺-dependent aldehyde dehydrogenase behaved in the same way. Both enzymes were localized in the microsomal fraction. The alcohol oxidase accepted long-chain (fatty) aliphatic alcohols (C₈ to at least C₁₆) and diols starting from decanediol. Trace activities were found with -hydroxy fatty acids. Aromatic, secondary and tertiary alcohols were not oxidized. In the stationary growth phase the substrate specificity of the alcohol oxidase tends to be changed to more hydrophobic substrates. The physiological role of both enzymes, the alcohol oxidase and aldehyde dehydrogenase, is discussed including their possible involvement in the synthesis of sophorose lipid. Correspondence to: R. K. Hommel     

Polyol Dehydrogenases in the Soluble Fraction of Acetobacter melanogenum

Polyol dehydrogenases of Acetobacter melanogenum were investigated. Three polyol dehydrogenases, i. e. NAD⁺-linked d-mannitol dehydrogenase, NAD⁺-linked sorbitol dehydrogenase and NADP⁺-linked d-mannitol dehydrogenase, in the soluble fraction of the organism were purified 12-fold, 8-fold and 88-fold, respectively, by fractionation with ammonium sulfate and DEAE-cellulose column chromatography. NAD⁺-linked sorbitol dehydrogenase reduced 5-keto-d-fructose (5KF) to l-sorbose in the presence of NADH, whereas NADP⁺-linked d-mannitol dehydrogenase reduced the same substrate to d-fructose in the presence of NADPH. It was also shown that NAD⁺-linked d-mannitol dehydrogenase was specific for the interconversion between d-mannitol and d-fructose and that this enzyme was very unstable in alkaline conditions.     

Alcohol Dehydrogenase from Methylobacterium organophilum

The alcohol dehydrogenase from Methylobacterium organophilum, a facultative methane-oxidizing bacterium, has been purified to homogeneity as indicated by sodium dodecyl sulfate-gel electrophoresis. It has several properties in common with the alcohol dehydrogenases from other methylotrophic bacteria. The active enzyme is a dimeric protein, both subunits having molecular weights of about 62,000. The enzyme exhibits broad substrate specificity for primary alcohols and catalyzes the two-step oxidation of methanol to formate. The apparent Michaelis constants of the enzyme are 2.9 × 10⁻⁵ M for methanol and 8.2 × 10⁻⁵ M for formaldehyde. Activity of the purified enzyme is dependent on phenazine methosulfate. Certain characteristics of this enzyme distinguish it from the other alcohol dehydrogenases of other methylotrophic bacteria. Ammonia is not required for, but stimulates the activity of newly purified enzyme. An absolute dependence on ammonia develops after storage of the purified enzyme. Activity is not inhibited by phosphate. The fluorescence spectrum of the enzyme indicates that it and the cofactor associated with it may be chemically different from the alcohol dehydrogenases from other methylotrophic bacteria. The alcohol dehydrogenases of Hyphomicrobium WC-65, Pseudomonas methanica, Methylosinus trichosporium, and several facultative methylotrophs are serologically related to the enzyme purified in this study. The enzymes of Rhodopseudomonas acidophila and of organisms of the Methylococcus group did not cross-react with the antiserum prepared against the alcohol dehydrogenase of M. organophilum.     

Ethanol Oxidase Respiratory Chain of Acetic Acid Bacteria. Reactivity with Ubiquinone of Pyrroloquinoline Quinone-dependent Alcohol Dehydrogenases Purified from Acetobacter aceti and Gluconohacter suhoxydans

Membrane-bound, pyrroloquinoline quinone-dependent, alcohol dehydrogenase functions as the primary dehydrogenase in the respiratory chain of acetic acid bacteria. In this study, an ability of the enzyme to directly react with ubiquinone was investigated in alcohol dehydrogenases purified from both Acetobacter aceti and Gluconobacter suboxydans by two different approaches. First, it was shown that the enzymes are able to reduce natural ubiquinones, ubiquinone-9 or -t0, in a detergent solution as well as a soluble short-chain homologue, ubiquinone-I. In order to show the reactivity of the enzyme with natural ubiquinone in a native membrane environment, furthermore, alcohol dehydrogenase was reconstituted into proteoliposomes together with natural ubiquinone and a terminal ubiquinol oxidase. The reconstitution was done by binding the detergent-free dehydrogenase at room temperature to proteoliposomes that had been prepared in advance from a ubiquinol oxidase and phospholipids containing ubiquinone by detergent dialysis using octyl-β-D-glucopyranoside; the enzyme of A. aceti was reconstituted together with ubiquinone-9 and A. aceti cytochrome a₁ while G. suboxydans alcohol dehydrogenase was done into proteoliposomes containing ubiquinone-10 and G. suboxydans cytochrome o. The proteoliposomes thus reconstituted had a reasonable level of ethanol oxidase activity, the electron transfer reaction of which was also able to generate a ‘membrane potential. Thus, it has been shown that alcohol dehydrogenase of acetic acid bacteria donates electrons directly to ubiquinone in the cytoplasmic membranes and thus the ethanol oxidase respiratory chain of acetic acid bacteria is constituted of only three membranous respiratory components, alcohol dehydrogenase, ubiquinone, and terminal ubiquinol oxidase.     

Further enzyme histochemical observations on the segmentation of the proximal tubules in the kidney of the male rat

Summary The segmentation of the proximal tubules of the male rat kidney was studied by means of enzyme histochemical reactions. Soluble oxidoreductases (glucose 6-phosphate dehydrogenase, -glycerophosphate dehydrogenase, 3-hydroxysteroid dehydrogenase, NAD- and NADP-dependent isocitrate dehydrogenases, NAD-dependent malate dehydrogenase, NADP-dependent, decarboxylating malate dehydrogenase, uridine diphosphate glucose dehydrogenase) were demonstrated using methods which reduce enzyme diffusion (incubating in presence of polyvinyl alcohol) and eliminate interference from tissue tetrazolium reductases. Less soluble or insoluble enzymes (glucose 6-phosphatase, -hydroxybutyrate dehydrogenase, succinate dehydrogenase and tetrazolium reductases) were demonstrated by incubation in conventional watery media.Segmental differences were observed in respect to all enzymes studied, and most reactions clearly visualized the three segments known to exist from ultrastructural as well as previous histochemical studies: The pars convoluta includes the first (P₁) and most of the second (P₂) segment. The transition to the third segment (P₃) is in the beginning of the pars recta. Also these reactions revealed a difference between the first part of the P₃, which runs through the cortex in the medullary rays, and the terminal part transversing the outer stripe of the medulla. In most instances intensity of reaction decreased in the last portion of the P₃.A number of the enzymes studied were mainly or solely localized to the P₃ (glucose 6-phosphate dehydrogenase, -glycerophosphate dehydrogenases, -hydroxybutyrate dehydrogenase, 3-hydroxysteroid dehydrogenase, decarboxylating malate dehydrogenase and uridine diphosphate glucose dehydrogenase). Some possible functional implications of the findings are discussed.Supported by grants from Fonden til Lægevidenskabens Fremme and the Danish Medical Research Council. — Mr. Kaj L. Pedersen is thanked for valuable photographic assistance.     

On the nature of the ''nothing dehydrogenase'' reaction

Summary The biochemical mechanism underlying the nothing dehydrogenase reaction during the histochemical demonstration of dehydrogenases using tetranitro BT as the final electron acceptor has been investigated in unfixed, frozen rat liver sections. The reaction is stronger with NAD⁺ than either with NADP⁺ or in the absence of coenzyme. As much as 50% of the reaction is due to lactate dehydrogenase converting endogenous lactate and is largely inhibited by pyruvate. No NAD⁺-dependent alcohol dehydrogenase activity was detected at pH 7.45, the pH used for the incubations. The coenzyme-independent activity may be caused by SH-groups present in proteins and compounds like glutathione and cysteine and can be inhibited byN-ethylmaleimide andp-chloromercuribenzoic acid. It was also found that the nothing dehydrogenase reaction mainly occurs during the first few minutes of incubation, levelling off quickly to a slow rate. When studying the kinetics of dehydrogenase reactions with tetrazolium salts, it should be realized that the nothing dehydrogenase reaction, which as a whole is nonlinear with time, can interfere seriously with the dehydrogenase reaction to be analysed and may yield initial reaction rates that are too high. The findings of the present study reveal the nature of the reactions used for detection of necrosis in tissues with tetrazolium salts.     

Isolation and properties of an isocitrate dehydrogenase from Anacystis nidulans

A NADP⁺-specific isocitrate dehydrogenase (EC 1.1.1.42) was isolated and purified over 400-fold from Anacystis nidulans. The enzyme activity responded slowly to rapid changes in ligand (NADP⁺, isocitrate, Mg²⁺-ions) or enzyme concentration as well as to rapid changes in temperature. These are properties characteristic of the hysteretic enzymes. In addition, the enzyme activity was subject to product (-ketoglutarate) inhibition. ATP, ADP and CDP also inhibited the enzyme. Unlike several other cyanobacterial enzymes, the isocitrate dehydrogenase of Anacystis is not under redox control.     

Subcellular localization of long-chain alcohol dehydrogenase and aldehyde dehydrogenase in n-alkane-grown Candida tropicalis

Long-chain alcohol dehydrogenase and longchain aldehyde dehydrogenase were induced in the cells of Candida tropicalis grown on n-alkanes. Subcellular localization of these dehydrogenases, together with that of acyl-CoA synthetase and glycerol-3-phosphate acyltransferase, was studied in terms of the metabolism of fatty acids derived from n-alkane substrates. Both longchain alcohol and aldehyde dehydrogenases distributed in the fractions of microsomes, mitochondria and peroxisomes obtained from the alkane-grown cells of C. tropicalis. Acyl-CoA synthetase was also located in these three fractions. Glycerol-3-phosphate acyltransferase was found in microsomes and mitochondria, in contrast to fatty acid -oxidation system localized exclusively in peroxisomes. Similar results of the enzyme localization were also obtained with C. lipolytica grown on n-alkanes. These results suggest strongly that microsomal and mitochondrial dehydrogenases provide long-chain fatty acids to be utilized for lipid synthesis, whereas those in peroxisomes supply fatty acids to be degraded via -oxidation to yield energy and cell constituents.     

Purification and characterization of a NAD+-dependent secondary alcohol dehydrogenase from propane-grown Rhodococcus rhodochrous PNKb1

NAD⁺-linked primary and secondary alcohol dehydrogenase activity was detected in cell-free extracts of propane-grown Rhodococcus rhodochrous PNKb1. One enzyme was purified to homogeneity using a two-step procedure involving DEAE-cellulose and NAD-agarose chromatography and this exhibited both primary and secondary NAD⁺-linked alcohol dehydrogenase activity. The Mr of the enzyme was approximately 86,000 with subunits of Mr 42,000. The enzyme exhibited broad substrate specificity, oxidizing a range of short-chain primary and secondary alcohols (C₂–C₈) and representative cyclic and aromatic alcohols. The pH optimum was 10. At pH 6.5, in the presence of NADH, the enzyme catalysed the reduction of ketones to alcohols. The K _m values for propan-1-ol, propan-2-ol and NAD were 12 mM, 18 mM and 0.057 mM respectively. The enzyme was inhibited by metal-complexing agents and iodoacetate. The properties of this enzyme were compared with similar enzymes in the current literature, and were found to be significantly different from those thus far described. It is likely that this enzyme plays a major role in the assimilation of propane by R. rhodochrous PNKb1.Abbreviations HPLC high performance liquid chromatography - DEAE diethyl amino ethyl - IEF isoelectrofocusing - NTG nitrosoguanidine - SDS-PAGE sodium dodecylsulphate polyacrylamide gel electrophoresis - pI isoelectric point     

Formation from synthetic two-stroke lubricants and degradation of 2-ethylhexanol by lakewater bacteria

Summary Bacteria, isolated from lakewater and capable of growing at the expense of commercial synthetic 2-stroke lubricant oils released 2-ethylhexanol from this substrate by means of esterases. The alcohol accumulated to approximatedly 6mM in these incubations but was itself mineralized by a strain of Pseudomonas putida isolated from the same lakewater by elective culture. The initial steps in the degradative pathway of 2-ethylhexanol were catalysed by alcohol and aldehyde dehydrogenases. The resultant 2-ethylhexanoic acid was further metabolised via -oxidation. The accumulation of intermediates in culture fluids facilitated by acrylate addition and higher isocitrate lyase activities in cell extracts, suggested that 2-ethylhexanoic acid was cleaved to two butyrate moieties which were then further metabolised to acetate. The pathway shows the organism has an interesting -oxidation system capable of utilizing branched substrates.The inducible alcohol dehydrogenase system consisted of two different enzymes, one heat-stable and NAD⁺-linked, the other heat-labile and PMS-linked, with widely different pH optima of pH 7.0 and 9.0, respectively. Activity staining of extracts resolved by non-denaturing polyacrylamide gel electrophoresis was used to confirm that the enzymes were substantially different moieties.     

Histochemical observations on the exoerythrocytic malaria parasite Plasmodium berghei in rat liver

Summary Enzyme histochemical methods were performed on sporozoite infected liver tissue of rats in order to gain insight into the nutrition and metabolism of exoerythrocytic forms of Plasmodium berghei. The following enzymes were demonstrated in the hepatocytic stages of the parasites, obtained 41 and 48 h after inoculation of sporozoites: acid phosphatase, cytochrome oxidase, NADH-tetrazolium reductase, succinate dehydrogenase, NAD⁺ and NADP⁺ dependent isocitrate dehydrogenase, NADP⁺-dependent malate dehydrogenase, lactate dehydrogenases, 6-phosphogluconate dehydrogenase and glucose-6-phosphate dehydrogenases and -glycerol-phosphate dehydrogenase. The results suggest that a conventional Embden-Meyerhoff pathway, pentose phosphate pathway and Krebs' citric acid cycle may in part be present in these exoerythrocytic parasites. Alkaline phosphatase, nucleoside polyphosphatase, 5nucleotidase. glucose-6-phosphatase, -glucan phosphorylase, NAD⁺ dependent malate dehydrogenase, amino-peptidase M and non-specific esterases were not detected by our techniques in the parasite. The enzyme distribution of this intrahepatocytic malaria parasite revealed by histochemistry is compared with the enzyme distribution in the other phases of the parasite's life cycle.This study was made possible by grants from the Jan Dekker Foundation for Biomedical Research and the Niels Stensen Foundation, The Netherlands, to the first author