The metabolism of niacytin in the rat. Trigonelline as a major metabolite of niacytin in the urine

1. To investigate the fate of orally administered niacytin, urine and faeces of rats given single niacytin doses were examined for nicotinic acid derivatives methylated on the pyridine nitrogen atom, determined as trigonelline. 2. Methods were devised for the extraction of trigonelline from urine and faeces and for its differentiation from N'-methylnicotinamide. 3. A prolonged elevation of the excretion of trigonelline in the urine of rats dosed with niacytin was detected colorimetrically, in contrast with the urinary excretion in control groups given free nicotinic acid or hydrolysed niacytin. The total conversion of the nicotinoyl moiety of niacytin into trigonelline was 30-40%. 4. The identity of this metabolite as trigonelline was established by t.l.c., by its u.v. spectrum and by g.l.c. after conversion into methyl nicotinate. 5. The excretion of Ehrlich-positive substances was also increased in urine after administration of niacytin, the increase being approximately parallel to the trigonelline excretion. 6. No increase in the excretion of trigonelline in faeces was found after administration of niacytin. 7. These results suggest a metabolic path-way for niacytin in the rat involving methylation of the pyridine nitrogen without prior release of free nicotinic acid. This hypothesis explains the absence of biological activity of niacytin. An endogenous source of urinary trigonelline was also demonstrated.     

The metabolism of niacytin in the rat. Studies of the excretion of nicotinic acid metabolites

1. Nicotinic acid-deficient rats were given a dose of niacytin or an equivalent one of free nicotinic acid or hydrolysed niacytin. 2. The excretion of N'-methylnicotinamide and of tertiary nicotinoyl derivatives in urine showed that niacytin was not metabolized as free nicotinic acid, although hydrolysed niacytin was equivalent to free nicotinic acid. 3. Little or none of the niacytin dose was recovered as tertiary nicotinoyl derivatives in faeces. This result was not affected by fitting rats with tail-cups to prevent coprophagy. 4. At the high doses used niacytin restored the growth rate of the deficient animals because of a small degree of hydrolysis of the bound nicotinic acid.     

Metabolism of nicotinic acid in plant cell suspension cultures, III: Formation and metabolism of trigonelline (author's transl)]

Cell suspension cultures of Phaseolus aureus, Glycinemax., Cicer arietinum and Chenopodium rubrum convert nicotinic acid and nicotinamide into N-methyl nicotinic acid (trigonelline). Application of [carboxyl-14C]- and [N-methyl-14C]nicotinic acid to cell cultures demonstrated that 1) the nicotinic acid moiety of trigonelline is funnelled into the pyridine nucleotide cycle, 2) trigonelline is demethylated partly oxidatively, but predominantly non-oxidatively, transferring the methyl carbon atom to still unknown acceptors, and 3) uptake of trigonelline by mung bean cell cultures is accompanied by demethylation and instantaneous remethylation reactions. Cell suspension cultures of parsley (Petroselinum hortense Hoffm.) show uptake but no metabolism of trigonelline. The data are compared with trigonelline metabolism in intact plants.     

The metabolism of labelled hexadecyl sulphate salts in the rat, dog and human.

The metabolic fate of [1-14-C]hexadecylsulphate and hexadecyl[35-S]sulphate, administered intravenously as the sodium and trimethylammonium salt to dogs and orally as the erythromycin salt to dogs, rats and humans, was studied. Studies with rats indicated that the compounds were well absorbed and rapidly excreted in the urine. However, after oral administration of the 14-C-and 35-S-labelled hexadecyl sulphate erythromycin salt to dogs, considerable amounts of radioactivity were excreted in the faeces as unmetabolized hexadecyl sulphate. Studies with two humans showed that orally administered erythromycin salt of [1-14C]hexadecyl sulphate was well absorbed in one person but poorly absorbed in the other. Radioactive metabolites in urine were separated by t.l.c. in two solvent systems. The main metabolite of hexadecyl sulphate in the dog, rat and human was identified as the sulphate ester of 4-hydroxybutyric acid. In addition, psi-[14-C]butyrolactone as a minor metabolic product of [1-14-C]hexadecyl sulphate was also isolated from the urine of rat, dog and man. However, there was still another metabolite in dog urine, which comprised about 20% of the total urinary radioactivity and carried both 14-C and 35-S labels. This metabolite was absent from rat urine. The metabolite in dog urine was isolated and subsequently identified by t.l.c. and g.l.c. and by isotope-dilution experiments as the sulphate ester of glycollic acid. Small amounts (about 5% of the total recovered radioactivity in excreta) of labelled glycollic acid sulphate were also found in human urine after ingestion of erythromycin [1-14-C]hexadecyl sulphate.     

Biosynthesis of carnitine and 4-N-trimethylaminobutyrate from 6-N-trimethyl-lysine

The conversion of 6-N-[Me-(14)C]trimethyl-lysine into carnitine and 4-N-trimethylaminobutyrate (butyrobetaine) was demonstrated in rats kept on a lysine-deficient diet. After the rats were given [(14)C]trimethyl-lysine for 4 days, a total of 17% of the injected label was recovered as carnitine from carcass and urine extracts. Another 8% of the trimethyl-lysine label was converted into 4-N-trimethylaminobutyrate, most of which was recovered from the urine. The conversion of trimethyl-lysine into the above two metabolites supports the pathway of carnitine biosynthesis as lysine+methionine --> 6-N-trimethyl-lysine --> 4-N-trimethylaminobutyrate --> carnitine. In addition, three other metabolites representing 2% of the injected dose were recovered. Only an insignificant portion of the label was recovered as free trimethyl-lysine from the carcass, whereas 22% of the injected label was recovered in the urine. A relatively low specific radioactivity in carnitine was found when 5-N-[Me-(14)C]trimethylaminopentanoate and 6-N-[Me-(14)C]trimethylaminohexanoate were administered to rats in amounts similar to the [(14)C]trimethyl-lysine, suggesting that they were not free intermediates.     

The role of the gut flora in the metabolism of cyclamate

1. [(14)C]Cyclamate was not metabolized when incubated with the liver, spleen, kidney or blood of rats of rabbits kept on a cyclamate-containing diet, and that had become converters of cyclamate into cyclohexylamine. 2. [(14)C]Cyclamate was converted into cyclohexylamine when incubated under anaerobic conditions with the contents of the caecum, colon or rectum or with the faeces of cyclamate-pretreated rats. Similar results were obtained with cyclamate-pretreated rabbits. With cyclamate-pretreated guinea pigs, which did not readily convert cyclamate into cyclohexylamine, the colon contents showed only low activity in this respect. 3. The faeces of a human converter of [(14)C]cyclamate into cyclohexylamine were also very active, but became less active when cyclamate was removed from his diet. 4. On subculturing the organisms from the contents of the colon and rectum of rats, the ability to convert cyclamate into cyclohexylamine was lost during three subcultures, but the loss of the activity was considerably decreased by subculturing in the presence of cyclamate. 5. Incubation of rat faeces in broths containing cyclamate increased their ability to metabolize cyclamate, but similar treatment of rabbit and human faeces suppressed this activity. 6. When rats are kept on a cyclamate diet the number of clostridia in the faeces increased considerably. In human dietary cyclamate did not appear to alter the counts of various faecal micro-organisms. 7. The gut organisms that appear to develop the ability to convert cyclamate into cyclohexylamine are clostridia in rats, enterobacteria in rabbits and enterococci in man. 8. [(14)C]Cyclohexylamine injected into the caecum or colon of rats is readily absorbed and excreted in the urine. 9. It appears that on continued intake of cyclamate the gut flora develop the ability to convert cyclamate into cyclohexylamine, which is then absorbed and excreted mainly in the urine, although a small proportion is metabolized to other compounds.     

Biosynthesis of trigonelline from nicotinate mononucleotide in mungbean seedlings

To determine the biosynthetic pathway to trigonelline, the metabolism of [carboxyl-(14)C]nicotinate mononucleotide (NaMN) and [carboxyl-(14)C]nicotinate riboside (NaR) in protein extracts and tissues of embryonic axes from germinating mungbeans (Phaseolus aureus) was investigated. In crude cell-free protein extracts, in the presence of S-adenosyl-L-methionine, radioactivity from [(14)C]NaMN was incorporated into NaR, nicotinate and trigonelline. Activities of NaMN nucleotidase, NaR nucleosidase and trigonelline synthase were also observed in the extracts. Exogenously supplied [(14)C]NaR, taken up by embryonic axes segments, was readily converted to nicotinate and trigonelline. It is concluded that the NaMN-->NaR-->nicotinate-->trigonelline pathway is operative in the embryonic axes of mungbean seedlings. This result suggests that trigonelline is synthesised not only from NAD but also via the de novo biosynthetic pathway of pyridine nucleotides.     

Evaluation of the contribution of dietary cholesterol to hypercholesterolemia in diabetic rats and of sitosterol as a recovery standard for cholesterol absorption

The contribution of dietary cholesterol to hypercholesterolemia in diabetic rats fed chow ad libitum was evaluated. Diabetes was induced with streptozotocin, and the intake, absorption, and subsequent tissue distribution of dietary cholesterol were measured. Absorption was measured as the difference between [3H]cholesterol intake and fecal 3H-labeled neutral sterol excretion, using both [14C]sitosterol (added to diet) and [14C]cholesterol (added to feces) as recovery markers. [3H]Cholesterol absorption was underestimated by 1-3% using [14C]sitosterol as a recovery standard, due to the 7-8% absorption of sitosterol. After 3 weeks of diabetes, rats were hyperphagic, thereby increasing dietary cholesterol intake 2-fold. [3H]Cholesterol absorption was significantly increased from 69% in controls to 78% in diabetics, whereas [14C]sitosterol absorption was unaffected. With increased dietary cholesterol intake and decreased whole body cholesterol synthesis (Diabetes. 1983. 32: 811-819), influx from diet equaled for exceeded influx from synthesis. The amounts of 3H-labeled neutral sterol recovered from the small intestine, periphery, and plasma were increased 3- to 4-fold in the diabetic rats. Furthermore, the degree of hypercholesterolemia in diabetic rats was directly related to the fraction of plasma cholesterol derived from the diet. We conclude that the 2.3-fold increase in absorbed dietary cholesterol resulting from hyperphagia and, to a lesser extent, from increased fractional absorption, contributes to the hypercholesterolemia of diabetic rats fed chow ad libitum.     

Pyridine nucleotide cycle and trigonelline (N-methylnicotinic acid) synthesis in developing leaves and fruits of Coffea arabica

We examined the biosynthesis of trigonelline in leaves and fruits of Arabica coffee ( Coffea arabica ) plants. [³H]Quinolinic acid, which is an intermediate of de novo pyridine nucleotide synthesis, and [¹⁴C]nicotinamide and [¹⁴C]nicotinic acid, which are degradation products of NAD, were converted to trigonelline and pyridine nucleotides. These tracer experiments suggest that the pyridine nucleotide cycle, nicotinamide → nicotinic acid → nicotinic acid mononucleotide (NaMN) → nicotinic acid adenine dinucleotide (NaAD) → NAD → nicotinamide mononucleotide (NMN) → nicotinamide, operates in coffee plants, and trigonelline is synthesized from nicotinic acid formed in the cycle. Trigonelline accumulated up to 18 µmol per leaf in developed young leaves, and then decreased with age. Although the biosynthetic activity of trigonelline from exogenously supplied [¹⁴C]nicotinamide was observed in aged leaves, the endogenous supply of nicotinamide may be limited, reducing the contents in these leaves. Trigonelline is synthesized and accumulated in fruits during development. The trigonelline synthesis in pericarps is much higher than that in seeds, but its content in seeds is higher than pericaps, so that some of the trigonelline synthesized in the pericarps may be transported to seeds. Trigonelline in seeds may be utilized during germination, as its content decreases. Trigonelline synthesis from [¹⁴C]nicotinamide was also found in Theobroma cacao plants, but instead of trigonelline, nicotinic acid-glucoside was synthesized from [¹⁴C]nicotinamide in Camellia sinensis plants.     

Evaluation of Polyethylene Glycol as a Water-soluble Marker: Absorption and Excretion of 14C-labeled Polyethylene Glycol in Rats

The absorbability of polyethylene glycol (PEG), a water-soluble nutritional marker, from the gastrointestinal tract of rat was examined using the [¹⁴C]-labeled compound ([¹⁴C]PEG) having a molecular weight of 4000. Intravenously injected [¹⁴C]PEG was readily excreted and recovered almost completely in the urine and neither hepatic nor renal uptake of the PEG was observed. Intragastrically administered [¹⁴C]PEG was eliminated in the urine with an average recovery of only 0.43 ± 0.13% (Mean ± S.D., n= 10) of the dose over 24 hr. From the gel column chromatographic profile of the radioactivity excreted in the urine after an oral dose, [¹⁴C]PEG was suggested to be absorbed in two forms, as an original form and as a low molecular weight component. The latter component might be the degraded product of PEG in the gastrointestinal tract. From these results it was confirmed that PEG with a molecular weight of 4000 is a satisfactory marker because of its low absorbability.     

Metabolism of 3-deoxyglucosone,an intermediate compound in the Maillard reaction,administered orally or intravenously to rats

Tha Amadori rearrangement compound, the product in the early step of the Maillard reaction of proteins with glucose, is known to be degraded into 3-deoxyglucosone (3DG), a 2-oxoaldehyde. In order to elucidate the metabolic pathway of 3DG, [¹⁴C]3DG was synthesized from [¹⁴C]-glucose and administered to rats orally and intravenously. 2 h after oral administration of [¹⁴C]3DG, the percentages of radioactivity (RaI%) in stomach, small intestine and urine were 3.9, 60 and 6.4%, respectively, while RaI% in liver, kidney, spleen, blood and CO₂ were less than 0.5%. The absorption rate of 3DG was obviously lower in comparison with that of glucose. 3 h after intravenous administration of [¹⁴C]3DG, the RaI% in urine was 72% and those in liver, kidney, spleen, blood and CO₂ were less than 1%. It therefore appeared that the absorbed 3DG was not biologically utilized by the rats, but was rapidly excreted in the urine. Some metabolites of [¹⁴C]3DG were detected in urine by TLC-autoradiography. The main metabolite was purified and identified as 3-deoxyfructose by FD-MS and ¹³C-NMR spectroscopy, indicating that the aldehyde group of 3DG was reduced to an alcohol.     

Effect of wheat bran on excretion of radioactively labeled estradiol-17 beta and estrone-glucuronide injected intravenously in male rats.

Urinary and fecal estrogen excretion were studied in male rats fed a non-fiber wheat starch diet (dietary fiber less than 1%; NF group; n = 4), a low-fiber wheat flour diet (dietary fiber 2%; LF group; n = 4) or a high-fiber wheat bran diet (dietary fiber 11.6%; HF group; n = 3). Short-term effects of the experimental diet on estrogen excretion were studied after i.v. injection of 5 microCi (0.185 MBq) of [14C]estradiol-17 beta (E2) into the tail vein of the rats fed the diets for 2 days. After 3 weeks on the experimental diets, the long-term effects were studied after injection of 5 microCi of [14C]E2 and 10 microCi of [3H]estrone-3-glucuronide (E1-gluc). The diet was found to affect estrogen excretion. The short-term effect indicated that rats fed the HF diet excreted a relatively large amount of labeled compounds in the feces during the first day after injection, while rats fed the NF or the LF diets excreted about half that amount over the same period. On the other hand, urinary excretion of labeled compounds was significantly higher in the NF and LF rats. The long-term effect resulted in steeper slopes (P less than 0.05) of the fecal excretion profiles of rats fed the HF diet as compared with rats fed the NF and LF diets, indicating an accelerated fecal excretion of labeled compounds in the HF rats. The kinetic profiles of 14C and 3H radioactivity in blood plasma indicated a fast decrease (t1/2 of less than 2 min) for both [14C]E2 and [3H]E1-gluc. It was concluded that, owing to the short-term effect of wheat bran intake, during the first 24 h after i.v. administration relatively large amounts of radioactively labeled compounds are excreted in feces of rats fed the HF diet. In contrast, excretion is lower in urine of these rats. When the microflora is adapted to the experimental diet the wheat bran diet still results in an accelerated fecal excretion of labeled compounds, which might be attributed to an interruption of the enterohepatic circulation of estrogens. This might result in lowered plasma and/or tissue estrogen levels and hence a decreased exposure of estrogen-sensitive tissue to estrogens, which might decrease risk on mammary (breast) cancer development.     

Trigonelline biosynthesis and the pyridine nucleotide cycle in Coffea arabica fruits: Metabolic fate of [carboxyl-C]nicotinic acid riboside

Trigonelline is a major component in coffee seeds and may contribute to the bitter taste of the resultant beverage. To determine the trigonelline biosynthetic pathway in coffee fruits, we investigated the metabolic fate of [carboxyl-¹⁴C]nicotinic acid riboside and in situ activity of related enzymes. Exogenously supplied [carboxyl-¹⁴C]nicotinic acid riboside was rapidly converted to nicotinic acid mononucleotide and was utilized for NAD synthesis. Nicotinic acid riboside was also used for trigonelline synthesis, but this process took longer than NAD synthesis. These results indicate that an efficient nicotinic acid riboside salvage system functions in coffee fruits, and that trigonelline is synthesized mainly from nicotinic acid produced by the degradation of NAD.     

The metabolism of N-triphenylmethylmorpholine in the dog and rat

1. Rats were given N-triphenyl[(14)C]methylmorpholine, triphenyl[(14)C]carbinol, N-triphenylmethyl[G-(3)H]morpholine or [G-(3)H]morpholine as single oral doses; the routes of excretion were examined. 2. Dogs were given single oral doses of N-triphenyl[(14)C]methylmorpholine. 3. (14)C-labelled metabolites were excreted mainly in the faeces in both rats and dogs; no (14)CO(2) was expired and less than 3% remained in the carcass and skin after 96hr. 4. (3)H-labelled metabolites were excreted rapidly in urine; part of the label was found in the expired gases and over 10% remained in the carcass and skin after 96hr. 5. Differences in excretion pattern between the sexes were noticed in rats but not in dogs. 6. N-Triphenylmethylmorpholine was rapidly hydrolysed to form triphenylcarbinol and morpholine in the stomach; morpholine was absorbed rapidly and excreted largely unchanged, though some was degraded, since some of the (3)H was found in water. 7. Triphenylcarbinol was absorbed only slowly and was oxidized to p-hydroxyphenyldiphenylcarbinol. 8. Both triphenylcarbinol and its p-hydroxy derivative were found in urine, bile and faeces in the free form and conjugated with glucuronic acid. The proportion of conjugates was higher in rat bile than in faeces. 9. Traces of o-hydroxyphenyldiphenylcarbinol and m-hydroxyphenyldiphenylcarbinol were detected as metabolites both free and conjugated.     

Trafficking of dietary fat in obesity-prone and obesity-resistant rats

The trafficking of dietary fat was assessed in obesity-prone (OP) and obesity-resistant (OR) male and female rats. Test meals containing [1-(14)C]palmitate were delivered through gastric feeding tubes while rats consumed a high-carbohydrate diet (HCD) or after 5 days of a high-fat diet (HFD). Over the subsequent 24 h, the appearance of (14)C was followed in the GI tract, skeletal muscles (SM), liver, adipose tissues (AT), and expired CO(2). There was no difference in the production of (14)CO(2) between OP and OR rats consuming a HCD. However, after 5 days on HFD, OR rats produced significantly more (14)CO(2) after the test meal than OP rats (P < 0.001 females, P = 0.03 males). The differential oxidation of dietary fat between OP and OR rats on HFD was not due to differences in absorption but rather was associated with preferential disposition of tracer to AT in OP rats. Measurements of lipoprotein lipase in part explained increased tracer uptake by AT in OP rats but were not consistent with increased SM tracer uptake in OR rats. Surprisingly, female rats oxidized more tracer than male rats irrespective of phenotype or diet. These results are consistent with the notion that differences in the partitioning of dietary fat between storage in AT and oxidation in SM and liver that develop shortly after the introduction of a HFD may in part underlie the differential tendency for OR and OP rats to gain weight on this diet.     

Fatty acid synthesis and generation of glycerol-3-phosphate in brown adipose tissue from rats fed a cafeteria diet

In vivo fatty acid synthesis and the pathways of glycerol-3-phosphate (G3P) production were investigated in brown adipose tissue (BAT) from rats fed a cafeteria diet for 3 weeks. In spite of BAT activation, the diet promoted an increase in the carcass fatty acid content. Plasma insulin levels were markedly increased in cafeteria diet-fed rats. Two insulin-sensitive processes, in vivo fatty acid synthesis and in vivo glucose uptake (which was used to evaluate G3P generation via glycolysis) were increased in BAT from rats fed the cafeteria diet. Direct glycerol phosphorylation, evaluated by glycerokinase (GyK) activity and incorporation of [U-14C]glycerol into triacylglycerol (TAG)-glycerol, was also markedly increased in BAT from these rats. In contrast, the cafeteria diet induced a marked reduction of BAT glyceroneogenesis, evaluated by phosphoenolpyruvate carboxykinase-C activity and incorporation of [1-14C]pyruvate into TAG-glycerol. BAT denervation resulted in an approximately 50% reduction of GyK activity, but did not significantly affect BAT in vivo fatty acid synthesis, in vivo glucose uptake, or glyceroneogenesis. The data suggest that the supply of G3P for BAT TAG synthesis can be adjusted independently from the sympathetic nervous system and solely by reciprocal changes in the generation of G3P via glycolysis and via glyceroneogenesis, with no participation of direct phosphorylation of glycerol by GyK.     

Effects of lactation on L-leucine metabolism in the rat. Studies in vivo and in vitro.

1. The turnover rate of L-[1-14C]leucine was increased by 35% in lactating rats compared with virgin rats. Starvation or removal of pups (24 h) returned the value to that of the virgin rat. 2. Incorporation of L-[U-14C]leucine into lipid and protein of mammary glands of lactating rats in vivo increased 7-fold and 6-fold respectively compared with glands of virgin rats. Lactation caused no change in the incorporation of L-[U-14C]leucine into hepatic lipid and protein. 3. The production of 14CO2 from L[l-14C]leucine (in the presence of glucose) was similar in isolated acini from glands of fed (chow) and starved lactating rats. Feeding with a 'cafeteria' diet caused a slight decrease, and removal of pups a large decrease, in the oxidative decarboxylation of leucine. 4. Oxidation of L-[2-14C]leucine to 14CO2 was increased about 3-fold in acini from starved lactating rats or lactating rats fed on a 'cafeteria' diet compared with rats fed on a chow diet. Insulin decreased the formation of 14CO2 in all three situations. 5. Incorporation of L-[U-14C]- and [2-14C]-leucine into lipid was decreased in acini from starved lactating rats and lactating rats fed on a 'cafeteria' diet. Insulin tended to increase the conversion of [2-14C]leucine into lipid, but this was significant only in the case of the acini from 'cafeteria'-fed rats. 6. Experiments with (-)-hydroxycitrate indicate that the major route for conversion of leucine carbon into lipid in acini is via citrate translocation from the mitochondria. 7. The physiological implications of these findings are discussed.     

Metabolic fate of 14C-labelled nicotinamide and adenine in germinating propagules of the mangrove Bruguiera gymnorrhiza

We studied the metabolic fate of [carbonyl-14C]nicotinamide and [8-(14)C]adenine in segments taken from young and developing leaves, stem, hypocotyls, and roots of a shoot-root type emerging propagule of the mangrove plant Bruguiera gymnorrhiza. Thin-layer chromatography was used together with a bioimaging analyser system. During 4 h of incubation, incorporation of radioactivity from [carbonyl-14C]nicotinamide into NAD and trigonelline was found in all parts of the propagules; the highest incorporation rates into NAD and trigonelline were found in newly emerged stem and young leaves, respectively. Radioactivity from [8-(14)C]adenine was distributed mainly in the salvage products (adenine nucleotides and RNA), and incorporation was less in catabolites (allantoin, allantoic acid, and CO2). Adenine salvage activity was higher in young leaves and stem than in hypocotyls and roots. Over a short time, the effect of 500 mM NaCl on nicotinamide and adenine metabolism indicated that NaCl inhibits both salvage and degradation activities in roots.     

Folate deficiency and pancreatic acinar cell function

The present study was designed to determine the effect of folate deficiency on pancreatic acinar cell function. In the first series of experiments, three groups of rats were fed ad libitum regular rat feed, folate-deficient diet, or an equivalent amount of folate-sufficient diet. In the second series of experiments, rats were either fed ad libitum or rendered folate deficient by a purified folate-deficient diet; half of the folate-deficient group was replenished with oral folate. Body weight, pancreatic weight, DNA [methyl-14C]thymidine incorporation into DNA, RNA, [8-14C]adenine incorporation into RNA, protein content, synthesis of proteins, amylase content, and basal and bethanechol-stimulated amylase secretion were determined. The parameters were the same in the rats fed a folate-sufficient diet as in those fed a regular rat feed. Feeding a folate-deficient diet resulted in impaired DNA synthesis as evidenced by diminished incorporation of [methyl-14C]thymidine into DNA. There was no change in secretion of amylase. Similar results were obtained in the second series of experiments. These studies indicate that folate deficiency (rather than antibiotic content of the diet) impaired pancreatic function. Folate deficiency may therefore contribute to pancreatic injury in malnutrition and alcoholism.     

Pancreatic fate of 14C-labelled hexoses

In order to assess the respective contribution of the exocrine and endocrine moieties of the pancreas to the overall net uptake of selected monosaccharides by the pancreatic gland, the apparent distribution space of L-[1-14C]glucose, 3-O-[14C-methyl]-D-glucose, D-[U-14C]glucose, D-[U-14C]mannose and D-[U-14C]fructose was measured in pieces of pancreas obtained from either control rats or animals injected with streptozotocin. Although the time course for the uptake of 3-O-[14C-methyl]-D-glucose, D-[U-14C]glucose, D-[U-14C]mannose and D-[U-14C]fructose was much slower in the pieces of pancreas than that previously documented in isolated pancreatic islets, no significant difference could, as a rule, be detected between the results obtained in pancreatic pieces of control and streptozotocin rats. A comparable situation prevailed in the pancreas of animals examined 3 min after the intravenous injection of 3-O-[14C-methyl]-D-glucose. D-Glucose inhibited the uptake of 3-O-[14C-methyl]-D-glucose and that of D-[U-14C]fructose. Likewise, 3-O-methyl-D-glucose inhibited the uptake of D-[U-14C]glucose. Cytochalasin B (20 microm) also inhibited the uptake of 3-O-[14C-methyl]-D-glucose and D-[U-14C]glucose, but not that of D-[U-14C]fructose. D-Mannoheptulose hexaacetate, but not the unesterified heptose, inhibited the metabolism of tritiated and 14C-labelled D-glucose, as well as the net uptake of D-[U-14C]glucose and D-[U-14C]mannose and, to a lesser extent, that of D-[U-14C]fructose. These findings indicate that despite marked differences between endocrine and exocrine pancreatic cells in terms of both the time course for the uptake of several hexoses and the inhibition of their phosphorylation by D-mannoheptulose, little or no preferential labelling of the endocrine moiety of the pancreas by the 14C-labelled hexoses is observed, at least when judged from their distribution space in pancreatic pieces or the whole pancreatic gland. Nevertheless, the findings made with D-mannoheptulose and its hexaacetate ester raise the view that this heptose could conceivably be used to achieve a sizeable preferential labelling of the endocrine pancreas under the present experimental conditions.