Identity of dimeric dihydrodiol dehydrogenase as NADP(+)-dependent D-xylose dehydrogenase in pig liver

Dimeric dihydrodiol dehydrogenases (DDs, EC 1.3.1.20), which oxidize trans-dihydrodiols of aromatic hydrocarbons to the corresponding catechols, have been molecularly cloned from human intestine, monkey kidney, pig liver, dog liver, and rabbit lens. A comparison of the sequences with the DNA sequences in databases suggested that dimeric DDs constitute a novel protein family with 20 gene products. In addition, it was found that dimeric DD oxidizes several pentoses and hexoses, and the specificity resembles that of NADP(+)-dependent D-xylose dehydrogenase (EC 1.1.1.179) of pig liver. The inhibition of D-xylose dehydrogenase activity in the extracts of monkey kidney, dog liver and pig liver, its co-purification with dimeric DD activity from pig liver, and kinetic analysis of the D-xylose reduction by pig dimeric DD indicated that the two enzymes are the same protein.     

Glycerol phosphate dehydrogenase in mammalian peroxisomes

Peroxisomes isolated on sucrose density gradients from homogenates of rat, chicken, or dog livers and rat kidney contained NAD⁺:α-glycerol phosphate dehydrogenase. Since the amount of sucrose in the peroxisomal fraction inhibited the enzyme activity about 70%, it was necessary to remove the sucrose by dialysis. About 8.4% of the total dehydrogenase of rat livers was in the surviving intact peroxisomes after homogenation. If corrected for particle breakage, this represented approximately 21% of the total activity. About 9.5% of the total enzyme was isolated in rat kidney peroxisomes, and because of severe particle rupture may represent over half of the total activity. No glycerol phosphate dehydrogenase was found in spinach leaf peroxisomes. A specific activity of 326 nmoles min^?1 mg^?1 protein in the rat liver peroxisomal fraction was at least twice that in the cytoplasm. NAD⁺:α-glycerol phosphate dehydrogenase was also present in a membrane fraction which was not identified, but none was in the mitochondria. The liver peroxisomal and cytoplasmic NAD⁺:α-glycerol phosphate dehydrogenase moved similarly on polyacrylamide gels and each resolved into two adjacent bands.Malate dehydrogenase was not found in peroxisomes from liver and kidney of rats and pigs, but 1–2% of the total particulate malate dehydrogenase was present in the peroxisomal area of the gradient from dog livers. However, this malate dehydrogenase in dog peroxisomal fractions did not exactly coincide with the peroxisomal marker, catalase. Malate dehydrogenase in dog liver mitochondria and in the peroxisomal fraction had similar pH optima and K_m values and migrated similarly to the anode at pH 6.5 on starch gels as a major and a minor band. The cytoplasmic malate dehydrogenase had a different pH optimum and K_m value and resolved into five different isoenzymes by electrophoresis. It is concluded that NAD⁺:α-glycerol phosphate dehydrogenase is in peroxisomes of liver and kidney, whereas malate dehydrogenase, present in peroxisomes of plants, is apparently absent in animal peroxisomes.     

gamma-Butyrobetaine hydroxylation to carnitine in mammalian kidney.

Activity of γ-butyrobetaine hydroxylase (γ-butyrobetaine, 2-oxoglutarate dioxygenase; EC 1.14.11.1) in liver and kidney of several mammalian species was assayed by measurement of tritium release from γ-[2,3-³H]butyrobetaine. Crude extracts from cat, hamster, rabbit, and Rhesus monkey kidneys effectively converted γ-butyrobetaine to carnitine. In these species, the levels of hydroxylating activity in kidney exceeded or nearly equaled the level of γ-butyrobetaine hydroxylase activity in the corresponding liver. In contrast, dog, guinea pig, mouse, and rat kidney exhibited no or insignificant capacity to hydroxylate γ-butyrobetaine. The notion that the liver is the exclusive or primary site of carnitine synthesis must be reconsidered at least for some mammalian species.     

Roles of His-79 and Tyr-180 of D-xylose/dihydrodiol dehydrogenase in catalytic function

Mammalian dimeric dihydrodiol dehydrogenase is identical with d-xylose dehydrogenase and belongs to a protein family with prokaryotic proteins including glucose-fructose oxidoreductase. Of the conserved residues in this family, either His-79 or Tyr-180 of d-xylose/dihydrodiol dehydrogenase has been proposed to be involved in the catalytic function. Site-directed mutagenesis was used to examine the roles of the two residues of the monkey enzyme. A mutant, Y180F, was almost inactive, but, similarly to the wild-type enzyme, exhibited high affinity for NADP(H) and fluorescence energy transfer upon binding of NADPH. The H79Q mutation had kinetically largest effects on K(d) (>7-fold increase) and K(m) (>25-fold increase) for NADP(H), and eliminated the fluorescence energy transfer. Interestingly, the dehydrogenase activity of this mutant was potently inhibited with a 190-fold increase in the K(m) for NADP(+) by high ionic strength, which activated the activity of the wild-type enzyme. These results suggest a critical role of Tyr-180 in the catalytic function of this class of enzymes, in addition to functions of His-79 in the coenzyme binding and chemical steps of the reaction.     

Inhibition of 15-hydroxyprostaglandin dehydrogenase by papaverine.

Papaverine was found to inhibit NAD⁺-linked 15-hydroxyprostaglandin dehydrogenase partially purified from guinea pig lung. The inhibition was noncompetitive with prostaglandin E₂, uncompetitive with NAD⁺, and reversible. The Ki was calculated to be 26 μM. Papaverine also inhibited the enzyme from swine lung, chicken and dog heart, and rat and dog kidney. The inhibitory effects of papaverine on the 15-hydroxyprostaglandin dehydrogenase were compared with those on cyclic AMP phosphodiesterases in these tissues.     

Ethanol metabolism in guinea pig: In vivo ethanol elimination,alcohol dehydrogenase distribution,and subcellular localization of acetaldehyde dehydrogenase in liver

Guinea pig ethanol metabolism as well as distribution and activities of ethanol metabolizing enzymes were studied. Alcohol dehydrogenase (ADH; EC 1.1.1.1) is almost exclusively present in liver except for minor activities in the cecum. All other organ tissues tested (skeletal muscle, heart, brain, stomach, and testes) contained only negligible enzyme activities. In fed livers, ADH could only be demonstrated in the cytosolic fraction (2.94 μmol/g liver/min at 38 °C) and its apparent K_m value of 0.42 mm for ethanol as substrate is similar to the average K_m of the human enzymes. Acetaldehyde dehydrogenase (ALDH; EC 1.2.1.3) of guinea pig liver was measured at low (0.05 mm) and high (10 mm) acetaldehyde concentrations and its subcellular localization was found to be mainly mitochondrial. The total acetaldehyde activity in liver amounts to 3.56 μmol/g/ min. Fed and fasted animals showed similar zero-order alcohol elimination rates after intraperitoneal injection of 1.7 or 3.0 g ethanol/kg body wt. The ethanol elimination rate of fed animals after 1.7 g ethanol/kg body wt (2.59 μmol/g liver/min) was inhibited by 80% after intraperitoneal injection of 4-methylpyrazole. Average ethanol elimination rates in vivo after 1.7 g/kg ethanol commanded only 88% of the totally available ADH activity in fed guinea pig livers. Catalase (EC 1.11.1.6), an enzyme previously implicated in ethanol metabolism, is of 3.4-fold higher activity in guinea pig (10,400 U/g liver) than in rat livers (3,100 U/g liver), but 98% inhibition by 3-amino-1,2,4-triazole did not significantly alter ethanol elimination rates. After ethanol injection, fed and fasted guinea pigs reacted with prolonged hyperglycemia.     

Prostaglandin metabolism. II. Identification of two 15-hydroxyprostaglandin dehydrogenase types.

Homogenates of several mammalian tissues were measured by radioimmunoassay for 15-hydroxyprostaglandin dehydrogenase activity. Two types of enzyme activity were detected. One, which used NAD-plus as cofactor much more effectively than NADP-lus, was found in monkey lung, heart, liver, kidney, and spleen and in chicken heart and dog lung. A second type, which uses NADP-plus as a cofactor more effectively than NAD-plus, was found in monkey and human brain and red blood cells and in swine kidney. These two types of 15-hydroxyprostaglandin dehydrogenase were partially purified from monkey brain and chicken heart. In addition to different cofactor requirements, the two partially purified enzymes could be distinguished by chromatographic properties, their relative affinities for prostaglandin I2 and F2alpha, and their sensitivities to inhibition by reduced pyridine nucleotides, thyroid hormones, and prostaglandin B2.     

In vitro synthesis of pig kidney general acyl CoA dehydrogenase

In vitro synthesis of general acyl CoA dehydrogenase [EC 1.3.99.3], one of the mitochondrial flavoenzymes, was carried out to elucidate its biosynthetic mechanism. Poly(A)+ RNA isolated from pig kidney was translated in vitro using wheat germ lysate system and the synthesized enzyme was immunoprecipitated by the antibody against purified pig kidney general acyl CoA dehydrogenase. The apparent molecular weight of the synthesized protein was estimated to be approximately 1,000 daltons larger than that of the mature enzyme, indicating that general acyl CoA dehydrogenase in pig kidney is synthesized as a precursor with a larger molecular weight.     

Kinetic characterization of d-xylose isomerases by enzymatic assays using d-sorbitol dehydrogenase

The enzymatic and coupled d-xylose isomerase/d-sorbitol dehydrogenase assay is a rapid and specific method, permitting accurate quantification of d-xylose isomerization and of d-xylose. The method is based on the isomerization of d-xylose to d-xylulose, followed by reduction of the latter to xylitol by commercially available d-sorbitol dehydrogenase and NADH. The application of this one-step method cannot be extended to d-glucose isomerization since the conditions for a valid coupled assay are not fulfilled. For quantification of d-glucose isomerization, the two-step procedure with d-sorbitol dehydrogenase is recommended. Kinetic parameters for d-xylose and d-glucose using d-xylose isomerase from Streptomyces violaceoruber are reported. The results are compared with the widely used colorimetric cysteine-carbazole method.     

The relation of the pH and concentration-dependent dissociation of porcine heart mitochondrial malate dehydrogenase.

The relationship of the pH-dependent and concentration-dependent dissociation of porcine heart mitochondrial malate dehydrogenase (L-malate: NAD⁺ oxidoreductase, EC 1.1.1.37) was investigated by means of gel filtration chromatography utilizing a standardized Sephacryl S-200 column. The results obtained indicate that the dimeric form of this enzyme dissociates to yield monomers at conditions of low protein concentration or at pH values below neutrality. In addition it is apparent that as the pH is lowered, the minimum concentration of protein required to maintain the enzyme in the dimeric form is increased.     

Cloning and expression of cDNA encoding hamster liver 3-hydroxyhexobarbital/17β(3α)-hydroxysteroid dehydrogenase 1

Using RACE techniques we have cloned and sequenced one of the hamster liver 3-hydroxy-hexobarbital dehydrogenases which catalyze not only cyclic alcohols but also 17β-hydroxy-steroids and 3α-hydroxysteroids. The gene specific primers to 3-hydroxyhexobarbital dehydrogenase 1 (G2) were synthesized on the basis of its partial peptide sequences. The sequence of full length cDNA generated by 3′- and 5′-RACE PCR consisted of 1225 nucleotides including an open reading frame of 972 nucleotides encoding a protein of 323 amino acids. The deduced amino acid sequence matched exactly with the partial peptide sequences of hamster liver 3-hydroxyhexobarbital dehydrogenase 1 (G2). The sequence showed 84.5% identity to mouse liver 17β-dehydrogenase(A-specific), and 74–76% identity to human liver bile acid binding protein/3α-hydroxysteroid dehydrogenase (DD2), human liver 3α-hydroxysteroid dehydrogenase type I (DD4) and type II (DD3), and rabbit ovary 20α-hydroxysteroid dehydrogenase. The protein contains catalytic residues of aldo-keto reductases, Asp50, Tyr55, Lys84, His117. These results suggest that the hamster liver 3-hydroxyhexobarbital/17β(3α)-hydroxysteroid dehydrogenase belongs to aldo-keto reductase superfamily. The insert containing the full-length cDNA of 3-hydroxyhexobarbital dehydrogenase and vector specific overhang produced by PCR was annealed with pET-32 Xa/LIC vector. The plasmid was transformed into BL21 (DE3) cells containing pLysS. The recombinant enzyme was induced 1 mM IPTG. The expressed enzyme was produced as fusion protein and purified by nickel chelating affinity chromatography followed by POROS CM column chromatography and superdex 75 gel filtration. Molecular weight of the recombinant enzyme fused thioredoxin and his•tag was about 55 000 and that was 35 000 after Factor Xa protease treatment. The recombinant enzyme dehydrogenated 3-hydroxy-hexobarbital, 1-acenaphthenol, 2-cyclohexen-1-ol, testosterone, glycolithocholic acid as well as the native enzyme purified from hamster liver.     

Aldehyde dehydrogenase activity in blood from various vertebrates

1. Aldehyde dehydrogenase activity was determined in whole blood samples from 17 selected vertebrates of 5 classes, using 3,4-dihydroxyphenylacetaldehyde (the aldehyde derived from dopamine) as substrate. 2. Aldehyde dehydrogenase activity in blood was widely but unevenly distributed among the species studied. 3. Mean aldehyde dehydrogenase activities in the range of 40-140 nmol/min.ml blood (measured at 37 degrees C, pH 8.8) were found in blood from man, monkey, rabbit, guinea pig and mouse (C57BL and NMRI strains), with the highest activity in rabbit blood. 4. Much lower aldehyde dehydrogenase activities (0.5-7.5 nmol/min.ml blood) were found in blood from Sprague-Dawley and Wistar rat, dog, cat, horse, pig, chicken, caiman, frog and rainbow trout, whereas the activities in blood from DBA mouse, cow, sheep and crucian carp were close to the detection limit.     

Enzyme changes associated with mitochondrial malic enzyme deficiency in mice

A genetically determined absence of mitochondrial malic enzyme (EC 1.1.1.40) in c^3H/c^6H mice is accompanied by a four-fold increase in liver glucose-6-phosphate dehydrogenase and a two-fold increase for 6-phosphogluconate dehydrogenase activity. Smaller increases in the activity of serine dehydratase and glutamic oxaloacetic transaminase are observed while the level of glutamic pyruvate transaminase activity is reduced in the liver of deficient mice. Unexpectedly, the level of activity of total malic enzyme in the livers of mitochondrial malic enzyme-deficient mice is increased approximately 50% compared to littermate controls. No similar increase in soluble malic enzyme activity is observed in heart of kidney tissue of mutant mice and the levels of total malic enzyme in these tissues are in accord with expected levels of activity in mitochondrial malic enzyme-deficient mice. The divergence in levels of enzyme activity between mutant and wild-type mice begins at 19–21 days of age. Immunoinactivation experiments with monospecific antisera to the soluble malic enzyme and glucose-6-phosphate dehydrogenase demonstrate that the activity increases represent increases in the amount of enzyme protein. The alterations are not consistent with a single hormonal response.     

Uridine diphosphate D-glucose dehydrogenase of Aerobacter aerogenes

Uridine diphosphate d-glucose dehydrogenase (EC 1.1.1.22) from Aerobacter aerogenes has been partially purified and its properties have been investigated. The molecular weight of the enzyme is between 70,000 and 100,000. Uridine diphosphate d-glucose is a substrate; the diphosphoglucose derivatives of adenosine, cytidine, guanosine, and thymidine are not substrates. Nicotinamide adenine dinucleotide (NAD), but not nicotinamide adenine dinucleotide phosphate, is active as hydrogen acceptor. The pH optimum is between 9.4 and 9.7; the K(m) is 0.6 mm for uridine diphosphate d-glucose and 0.06 mm for NAD. Inhibition of the enzyme by uridine diphosphate d-xylose is noncooperative and of mixed type; the K(i) is 0.08 mm. Thus, uridine diphosphate d-glucose dehydrogenase from A. aerogenes differs from the enzyme from mammalian liver, higher plants, and Cryptococcus laurentii, in which uridine diphosphate d-xylose functions as a cooperative, allosteric feedback inhibitor.     

The isozyme spectra of lactate dehydrogenase in the tissues of the raccoon dog <Emphasis Type="Italic">Nyctereutes procyonoides</Emphasis> in the autumn

An electrophoretic assay of lactate dehydrogenase (EC 1.1.1.27) isozymes in the tissue homogenates of cardiac and skeletal muscles, kidney, lungs, spleen, and liver of the raccoon dog Nyctereutes procyonoides from two different geographic zones, viz., northwestern Russia and Poland, as well as the Arctic blue fox Alopex lagopus L. and the red fox Vulpes vulpes L. was performed during the preparatory period to the winter season. Raccoon dogs, which hibernate under natural conditions, differ from other canids (the red fox and Arctic blue fox) to which they are close taxonomically by their body weight and by the higher proportion of aerobic H subunits of lactate dehydrogenase in all organs except for the heart. A higher content of “fast” anode fractions, lactate dehydrogenase-1 and lactate dehydrogenase-2, in the heart, kidney, lungs, liver, and spleen was detected in the raccoon dogs from the northern region compared to those from the southern geographic zone. The shift in the reaction catalyzed by lactate dehydrogenase towards the production of pyruvate indicates that this metabolite is necessary for the synthesis of fatty acids during lipogenesis in the autumn.     

Studies on sugar isomerases of Lactobacillus sp.: Whole cell immobilization of d-glucose isomerase

A new soil isolate of Lactobacillus sp. grown in Yamanaka medium under submerged conditions showed the presence of d-glucose, d-xylose and d-ribose isomerases in washed cell suspension and cell free extracts. d-Xylose isomerase (d-xylose ketol-isomerase, EC 5.3.1.5) and d-ribose isomerase (d-ribose ketol-isomerase, EC 5.3.1.20) activities reached a maximum in 48 h of growth and then declined. d-Glucose isomerase (d-glucose 6-phosphate isomerase, d-glucose-6-phosphate ketol-isomerase, EC 5.3.1.9) activity was maximum after 72 h and remained constant for ～120 h of growth. d-Glucose isomerase activity increased with the increase in number of generations of culture and reached a maximum in 5–6 generations, whereas d-xylose and d-ribose isomerase activities decreased. The washed and starved whole cells could be heat treated and immobilized on the rough surface of glass rods or glass slides using acetone treatment. The heat treated immobilized cells showed only the presence of d-glucose isomerase activity and showed no d-xylose and d-ribose isomerase activities. d-Glucose isomerase activity of heat treated immobilized cells was inhibited less by sorbitol, mannitol, sodium arsenate, cysteine and calcium ions than the free d-glucose isomerase activity in fresh untreated washed whole cells and cell free extracts. EDTA inhibition had the same effect for both forms. Ca²⁺inhibition could be reversed by adding Mg²⁺ions.     

Pig liver glyceraldehyde-3-P dehydrogenase: purification, crystallization, and characterization.

Glyceraldehyde 3-P dehydrogenase was purified approximately 250-fold from pig liver and crystallized. The purification procedure consisted of treating liver homogenates with zinc chloride, followed by ammonium sulfate fractionation and ion exchange chromatography. The enzyme was monodisperse in the ultracentrifuge with a sedimentation coefficient of s_20,w = 7.85 S. Sodium dodecyl sulfate polyacrylamide gel electrophoresis showed a single subunit band with an approximate molecular weight of 38,000. High-speed sedimentation equilibrium gave a molecular weight of 1.5 × 10⁵. Incubation of the enzyme with ATP at 0 °C caused a loss of its dehydrogenase activity; some of the lost activity was regained upon warming to room temperature. Sucrose density gradient studies of the ATP-treated enzyme revealed a decrease in its sedimentation coefficient from 7.8 to 3.85 S. In the forward reaction direction, the K_m for glyceraldehyde 3-P was 240 μm and the K_m for NAD was 12 μm. In the backward reaction direction, the K_m for NADH was 23 μm and the K_i for NAD was 850 μm. Pig liver glyceraldehyde-3-P dehydrogenase resembles the rabbit muscle enzyme in that it apparently contains 2 to 3 mol of tightly bound NAD. However, it differs strongly from that enzyme in its rate and extent of inactivation by ATP at 0 °C and by urea; the pig liver enzyme, like the yeast enzyme, dissociates much more slowly and much less completely than the rabbit muscle enzyme under comparable conditions.     

Mutant analysis of glyceraldehyde 3-phosphate dehydrogenase in Escherichia coli

NAD⁺-specific glyceraldehyde 3-phosphate dehydrogenase (EC 1.2.1.12) from Escherichia coli was purified to homogeneity by a relatively simple procedure involving affinity chromatography on agarose–hexane–NAD⁺ and repeated crystallization. Rabbit antiserum directed against this protein produced one precipitin line in double-diffusion studies against the pure enzyme, and two lines against crude extracts of wild-type E. coli strains. Both precipitin lines represent the interaction of antibody with determinants specific for glyceraldehyde 3-phosphate dehydrogenase. Nine independent mutants of E. coli lacking glyceraldehyde 3-phosphate dehydrogenase activity all possessed some antigenic cross-reacting material to the wild-type enzyme. The mutants could be divided into three groups on the basis of the types and amounts of precipitin lines observed in double-diffusion experiments; one group formed little cross-reacting material. The cross-reacting material in crude cell-free extracts of several of the mutant strains were also tested for alterations in their affinity for NAD⁺ and their phosphorylative activity. The cumulative data indicate that the protein in several of the mutant strains is severely altered, and thus that glyceraldehyde 3-phosphate dehydrogenase is unlikely to have an essential, non-catalytic function such as buffering nicotinamide nucleotide or glycolytic-intermediate concentrations. Others of the mutants tested have cross-reacting material which behaved like the wild-type enzyme for the several parameters studied; the proteins from these strains, once purified, might serve as useful analogues of the wild-type enzyme.     

The subcellular location of isozymes of NADP-isocitrate dehydrogenase in tissues from pig, ox and rat

Antibodies against purified NADP-isocitrate dehydrogenase from pig liver cytosol and pig heart were raised in rabbits. The purified enzymes from these sources are different proteins, as demonstrated by differences in electrophoretic mobility and absence of crossreactivity by immunotitration and immunodiffusion. The NADP-isocitrate dehydrogenase in the soluble supernatant homogenate fraction from pig liver, kidney cortex, brain and erythrocyte hemolyzate was identical with the purified enzyme from pig liver cytosol, as determined by electrophoretic mobility and immunological techniques. The enzyme in extracts of mitochondria from pig heart, kidney, liver and brain was identical with the purified pig heart enzyme by the same criteria. However, the 'mitochondrial' isozyme was the major component also in the soluble supernatant fraction of pig heart homogenate. The 'cytosolic' isozyme accounted for only 1-2% of total NADP-isocitrate dehydrogenase in pig heart, as determined by separation of the isozymes with agarose gel electrophoresis and immunotitration. The mitochondrial isozyme was also the predominant NADP-isocitrate dehydrogenase in porcine skeletal muscle. The ratio of cytosolic/mitochondrial isozyme for porcine whole tissue extract, determined by immunotitration, was about 2 for liver and 1 for kidney cortex and brain. The distribution of isozymes in cell homogenate fractions from ox and rat tissues corresponded to that observed in organs of porcine origin. The mitochondrial and cytosolic isozymes from ox and rat tissues exhibited crossreactivity with the antibodies against the pig heart and pig liver cytosol enzyme, respectively, and the electrophoretic migration patterns were similar qualitatively to those found for the isozymes in porcine tissues. Nevertheless, there were species specific differences in the characteristics of each of the corresponding isozymes. NAD-isocitrate dehydrogenase was not inhibited by the antibodies, confirming that the protein is distinct from that of either isozyme of NADP-isocitrate dehydrogenase.     

Demonstration of apolipoprotein CII in guinea pigs. Functional characteristics, cDNA sequence, and tissue expression

In contrast to plasma from other mammals, guinea pig plasma does not stimulate the activity of lipoprotein lipases in vitro. This had led previously to the conclusion that guinea pigs lack an analogue to apolipoprotein CII (apoCII). By adsorption of lipid-binding proteins to lipid droplets, thereby separating them from other plasma components, we could demonstrate apoCII-like activity in guinea pig plasma. On electrophoresis, the CII-like activity co-migrated with one isoform of guinea pig apolipoprotein CIII, identified by amino-terminal amino acid sequence determination (40 residues). By isoelectric focusing in a narrow pH gradient, the activating protein was separated sufficiently from the dominating apoCIII isoform to allow sequence determination of 8 residues from the amino terminus. Six of these were identical to corresponding residues in apoCII from dog and monkey. With the aid of a human apoCII cDNA probe we identified one cross-hybridizing mRNA species (approximately 600 nucleotides) on Northern blots of guinea pig liver. Three positive clones were isolated from a guinea pig liver cDNA library using the same cDNA probe. The nucleotide sequence showed extensive similarities to the previously known human, monkey, and canine sequences, but the signal peptide was 3 amino acid residues longer in the guinea pig protein, and there was a deletion of 4 residues in the putative lipid binding domain. Northern blot analyses indicated that guinea pig apoCII is mainly expressed in the liver with little or no contribution from the intestine.