DNA synthesis in relation to a varying vitamin B12 content in Propionibacterium shermanii cells

The content of DNA in Propionibacterium cells is nearly twice as low at vitamin B12 deficiency comparing with normal cells. The rate of labeled adenine incorporation into the DNA depends on vitamin B12 content in the cells. The addition of adenosylcobalamin and thymine to the medium makes DNA content rise in the cells of the B12-deficient culture. The addition of thymine to a suspension of B12-deficient cells accelerates the incorporation of labelled adenine into DNA. The authors discuss the phenomenon of bacterial "unbalanced division" and the control of replication by changing the level of DNA precursors.     

Production of Propionibacterium shermanii biomass and vitamin B12 on spent media

AIMS: The propionibacteria are commercially important due to their use in the cheese industry, and there is a growing interest for their probiotic effects. Stimulatory effects of lactic acid bacteria (LAB) on propionic acid bacteria have been observed. This study was designed to examine the possibility of using spent media previously used to grow LAB for the production of biomass and metabolites of Propionibacterium freudenreichii subsp. shermanii. METHODS AND RESULTS: Seventeen MRS and vegetable juice media were prefermented by various LAB and evaluated for their ability to subsequently support the growth of Propionibacterium, using automated spectrophotometry (AS). Growth of Propionibacterium in spent media was strongly affected by the LAB strain used to produce the spent medium. The native MRS medium (not prefermented) yielded the highest optical density values followed by prefermented media by Lactobacillus acidophilus, Bifidobacterium longum and Lactococcus lactis. Prefermented cabbage juice enabled good growth of Propionibacterium. For the production of organic acids and vitamin B12, cells of Propionibacterium were concentrated and immobilized in alginate beads in the aim of accelerating the bioconversions. More propionic acid was obtained in spent media than in native MRS. The concentration of vitamin B12 was higher in media fermented with free cells than those with immobilized cultures; with the free cells, its concentration varied from 900 to 1800 ng ml(-1) of media. CONCLUSIONS: It was demonstrated that spent media could be recycled for the production of Propionibacterium and metabolites, depending on the LAB strain that was previously grown. Media remediation is needed to improve the production of vitamin B12, especially with immobilized cells. SIGNIFICANCE AND IMPACT OF THE STUDY: This study presents an option for recycling of spent media generated by producers of LAB or producers of fermented vegetables. The propionic fermentation may result in three commercial products: biomass, vitamin B12 or organic acids, which may be used as starters, supplements or food preservatives. It is an attractive process from economical and environmental standpoints.     

Effects of maternal vitamin B12 deficiency from end of gestation to weaning on the growth and haematological and immunological parameters in mouse dams and offspring

Vitamin B12-deficiency may induce specific symptoms as neurological alterations and unspecific symptoms such as anaemia and growth retardation. In this study, maternal vitamin B12 deficiency from end of gestation to weaning was evaluated in mouse dams, which was provoked by feeding a vitamin B12-deficient diet. The animals were divided into two groups (control and deficient). The control group received the vitamin B12-deficient diet supplemented with commercial vitamin B12. Compared to the control, the vitamin B12-deficient dams and their offspring showed a significant decrease of body weight (by 20 and 39%, respectively), serum vitamin B12 concentration (by 61 and 67%, respectively), haematological values as haematocrit (25 and 26%, respectively), and IgA producer cells (by 36 and 54%, respectively). In both, vitamin B12-deficient mouse dams and their offspring, histological alterations of small intestine were observed, whereas growth retardation occurred in the offspring only. This experimental murine model allows assessing the incidence of maternal cobalamin deficiency in offspring and would be useful for evaluating novel adjuncts such as functional foods to prevent vitamin B12 deficiency.     

Factors affecting formiminoglutamic acid excretion in vitamin B12 deficiency

1. Formiminoglutamic acid, a product of the catabolism of histidine, is excreted in abnormally large amounts in the urines of vitamin B(12)-deficient rats and of vitamin B(12)-deficient sheep; the excretion is reduced to negligible amounts after administration of vitamin B(12). 2. After administration of certain methyl donors to vitamin B(12)-deficient rats or sheep urinary excretion of formiminoglutamic acid is temporarily decreased. 3. Irrespective of the pteroylglutamic acid status of the animals neither vitamin B(12)-deficient rats nor vitamin B(12)-deficient sheep have the ability to deal efficiently with histidine. 4. In sheep, urinary excretion of formiminoglutamic acid is increased after administration of aminopterin; treatment with pteroylglutamic acid restores the ability of the animal to deal with the catabolic products of histidine. 5. The possible functions of vitamin B(12) and methionine in relieving a virtual deficiency of pteroylglutamic acid are discussed.     

Improvement of vitamin B(12) fermentation by reducing the inhibitory metabolites by cell recycle system and a mixed culture

The major problem in vitamin B(12) production using Propionibacterium is the growth inhibition of the cell due to the accumulation of inhibitory metabolites such as propionic acid and acetic acid. In the present paper, we considered several approaches of controlling the propionic acid concentration at low level. Namely: (1) the periodic cultivation of Propionibacterium where dissolved oxygen (DO) concentration was alternatively changed between 0 and 1ppm; (2) cell recycle system using hollow fiber module; and (3) mixed culture using Propionibacterium and Ralstonia eutropha where the latter microorganism assimilates the propionic acid produced by the former. It was found that the productivity of vitamin B(12) was the highest for the cell recycle system, while if the performance was evaluated based on the amount of vitamin B(12) produced per medium used, the mixed culture system gave the far highest value.     

Ribonucleotide reductase activity in vitamin B12-deficient Euglena gracilis.

The ribonucleotide reductase activities in vitamin B12-sufficient and -deficient cells of Euglena gracilis were measured. We found that the cells progress into vitamin B12 deficiency the enzyme activity increases, reaching a maximum value of 20-fold in advanced deficiency. No signigicant differences in the activities were found to result as a consequence of different growth conditions. We propose that the increased activity in vitamin B12-deficient cells is due to an increase in enzyme protein.     

Folic acid metabolism in vitamin B12-deficient sheep. Effects of injected methionine on liver constituents associated with folate metabolism

1. A study was made of the effects of injected l-methionine on the activity of several enzymes of folate metabolism, and on the transport of methotrexate in liver preparations from vitamin B(12)-deficient ewes and their pair-fed controls receiving vitamin B(12). 2. The activities of dihydrofolate reductase (EC 1.5.1.3) and 5-methyltetrahydrofolate-homocysteine transmethylase were significantly decreased in the liver of vitamin B(12)-deficient animals, but were unaffected by l-methionine. 3. The concentration of S-adenosyl-l-methionine in the liver of deficient animals was about one-half of that in normal animals, and was restored to normal by either vitamin B(12) or l-methionine. 4. Methylenetetrahydrofolate reductase (EC 1.1.1.68) from sheep liver was inhibited by S-adenosyl-l-methionine in vitro, but not by concentrations of S-adenosyl-l-methionine found in the liver of vitamin B(12)-deficient animals after injection of physiological amounts of l-methionine. 5. Pteroylpolyglutamate synthetase activity was significantly increased in the liver of vitamin B(12)-deficient animals, and was decreased by intravenous injections of l-methionine. 6. l-Methionine injections increased the initial rate of uptake of methotrexate in liver slices from deficient animals and acted synergistically with vitamin B(12) to increase the quantity taken up in 40min. The failure of folate metabolism in vitamin B(12) deficiency can be satisfactorily explained if l-methionine similarly affects the membrane transport of naturally occurring folates. 7. Further details of the results have been deposited as Supplementary Publication SUP 50028 (4 pages) at the British Library (Lending Division), (formerly the National Lending Library for Science and Technology), Boston Spa, Yorks. LS23 7BQ, U.K., from whom copies may be obtained on the terms given in Biochem. J. (1973) 131, 5.     

The role of vitamin B12 in the metabolism of Euglena gracilis var. bacillaris

1. The concentrations of RNA, DNA and protein are decreased in cells of Euglena gracilis var. bacillaris grown on suboptimum concentrations of vitamin B(12). 2. The addition of vitamin B(12) to deficient cells stimulates the incorporation of [(14)C]formate into the above cell components as well as into thymine of DNA and serine and methionine of protein. 3. In a cell-free system from vitamin B(12)-deficient cells, the incorporation of labelled formate into thymidylate is decreased to a greater extent with uridine than with deoxyuridine as the substrate. 4. The addition of unlabelled glutamate dilutes the radioactivity incorporated into thymine from labelled formate. 5. These results are interpreted to mean that, in DNA synthesis, vitamin B(12) has a greater role in the reduction of ribotides to deoxyribotides than in the reduction of formate to thymine methyl and that the vitamin B(12)-dependent conversion of glutamate into beta-methylaspartate also contributes to thymine synthesis.     

Evaluation of biosynthetic pathways to delta-aminolevulinic acid in Propionibacterium shermanii based on biosynthesis of vitamin B12 from D-[1-13C]glucose

Analysis of the (13)C nuclear magnetic resonance (NMR) spectrum of (13)C-labeled vitamin B(12) biosynthesized from D-[1-(13)C]glucose by Propionibacterium shermanii provided evidence suggesting that delta-aminolevulinic acid (ALA) incorporated in the (13)C-labeled vitamin B(12) may have been synthesized via both the Shemin pathway and the C5 pathway under anaerobic conditions in the ratio of 1 < [(ratio of ALA biosynthesis from the Shemin pathway)/(that from the C5 pathway)] < 1.8. The D-ribose moiety of vitamin B(12) was labeled with (13)C at R-1, R-3, and R-5. The aminopropanol moiety of vitamin B(12) was labeled on Pr-1 and Pr-2, but not Pr-3.     

Use of Cheese Whey for Vitamin B12 Production: I. Whey Solids and Yeast Extract Levels1

The suitability of cheese whey as a substrate for vitamin B(12) production by Propionibacterium shermanii was studied. It was found that with a given level of whey solids a definite amount of yeast extract was required to give maximal yields of vitamin B(12). Of the levels of materials studied, 10% whey solids and 1.5% yeast extract gave the best yields of vitamin B(12). Most of the lactose of the whey had been utilized in all flask cultures after 168 hr at 29 C.     

Folic acid metabolism in vitamin B12-deficient sheep. Effects of injected methionine on liver constituents associated with folate metabolism

1. The effects of injected l-methionine (2g every second day for 28 days) on liver folates and other constituents of liver associated with folate metabolism were studied in vitamin B(12)-deficient ewes and their pair-fed controls receiving vitamin B(12). The dose rate of methionine used was sufficient to restore almost to normal the elevated excretion in the urine of formiminoglutamate in the deficient animals. 2. Liver folates active for Lactobacillus casei, Streptococcus faecalis R and Pediococcus cerevisiae were severely depressed in deficient livers and were partly restored by methionine. Analysis of the folates after ion-exchange chromatography showed that the major effect of methionine was to increase the concentrations of tetrahydrofolates and formyltetrahydrofolates. Methyltetrahydrofolates were also increased, but there was no effect of methionine on the small amounts of incompletely reduced folates present in deficient livers. The folates present were predominantly penta-, hexa- and hepta-glutamates whether or not animals received vitamin B(12) or methionine. 3. Concentrations of ATP, NAD(+), NADH and NADPH were lower in freeze-clamped liver from vitamin B(12)-deficient sheep than in liver from pair-fed, vitamin B(12)-treated sheep. These changes were not affected by methionine which was also without effect on the elevated K(+)/Na(+) ratios found in deficient livers. 4. The livers of vitamin B(12)-deficient animals contained lower concentrations of choline and higher concentrations of lipid than their pair-fed controls. These effects were reversed by methionine.     

Gluconeogenesis from propionate in kidney and liver of the vitamin B12-deficient rat

1. Kidney-cortex slices and the perfused livers of vitamin B(12)-deficient rats removed propionate from the incubation and perfusion media at 33 and 17% respectively of the rates found with tissues from rats receiving either a normal or a vitamin B(12)-supplemented diet. There was a corresponding fall in the rates of glucose synthesis from propionate in both tissues. 2. The addition of hydroxocobalamin or dimethylbenzimidazolylcobamide coenzyme to kidney-cortex slices from vitamin B(12)-deficient rats in vitro failed to restore the normal capacity for propionate metabolism. 3. Although the vitamin B(12)-deficient rat excretes measurable amounts of methylmalonate, no methylmalonate production could be detected (probably because of the low sensitivity of the method) when kidney-cortex slices or livers from deficient rats were incubated or perfused with propionate. 4. The addition of methylmalonate (5mm) to kidney-cortex slices from rats fed on a normal diet inhibited gluconeogenesis from propionate by 25%. 5. Methylmalonate formation is normally only a small fraction of the flux through methylmalonyl-CoA. This fraction increases in vitamin B(12)-deficient tissues (as shown by the urinary excretion of methylmalonate) presumably because the concentration of methylmalonyl-CoA rises as a result of low activity of methylmalonyl-CoA mutase (EC 5.4.99.2). Slow removal of methylmalonyl-CoA might depress propionate uptake owing to the reversibility of the steps leading to methylmalonyl-CoA formation.     

Metabolic effects of propionate in normal and vitamin B12-deficient rats

1. Administration of propionate caused a twofold increase in the concentrations of lactate and pyruvate in the blood of vitamin B(12)-deficient rats, whereas there was a slight decrease in lactate and a 50% increase in pyruvate in normal rats. 2. Concentrations of total ketone bodies in the blood of normal rats were not significantly altered by propionate administration but the [3-hydroxybutyrate]/[acetoacetate] ratio decreased from 3.0 to 2.0. In the vitamin B(12)-deficient rats there was a 40% decrease in total ketone bodies and a change in the ratio from 3.4 to 1.2. 3. The changes in the concentration of ketone bodies in freeze-clamped liver preparations were similar in pattern to those observed in blood. 4. Propionate administration caused a decrease in the concentration of acetyl-CoA in the livers of both groups of animals, but the absolute decrease was greater in the vitamin B(12)-deficient group. The decrease in the concentration of CoA was similar in both groups. 5. As in blood, there were threefold increases in the concentrations of lactate and pyruvate in the livers of the vitamin B(12)-deficient rats after propionate administration, whereas there was no significant change in the concentrations of these metabolites in the normal rats. 6. There was a 50% inhibition of glucose synthesis in perfused livers from vitamin B(12)-deficient rats when lactate and propionate were substrates as compared with lactate alone. 7. It is concluded that the conversion of lactate into glucose is inhibited in vitamin B(12)-deficient rats after propionate administration, and that this effect is due to inhibition of the pyruvate carboxylase step resulting from a decrease in acetyl-CoA concentration and a postulated increase in methylmalonyl-CoA concentration.     

Folic acid metabolism in vitamin B12-deficient sheep. Depletion of liver folates

1. Metabolism of folate was studied in six ewes in an advanced state of vitamin B(12) deficiency as judged by voluntary food intake and in their pair-fed controls receiving vitamin B(12). A group of four animals that were maintained throughout the experiment at pasture was also studied. 2. After 34-40 weeks on the cobalt-deficient diet urinary excretion of formiminoglutamate by four deficient animals was about 3.2mmol/day and this was not significantly decreased by injection of three of them with about 4.5mug of [2-(14)C]folate/kg body weight per day for 5 days. Three days after the last injection retention of [2-(14)C]folate by the livers of the deficient animals (5.5% of the dose) was lower than that of their pair-fed controls (26% of the dose) but there was no evidence of net retention of injected folate in the livers of either group. Urinary excretion of (14)C indicated that renal clearance of folate may have been impaired in very severe vitamin B(12) deficiency. 3. As estimated by microbiological assays total folates in the livers of animals at pasture (12.9mug/g) included about 24% of 5-methyltetrahydrofolate as compared with about 72% of a total of 12.5mug/g in three further ewes fed on a stock diet of wheaten hay-chaff and lucerne-chaff. Liver folates of vitamin B(12)-deficient animals (0.5mug/g) included about 88% of 5-methyltetrahydrofolate as compared with about 51% of a total of 5.2mug/g in pair-fed animals treated with vitamin B(12). 4. Chromatography of liver folates of the pair-fed animals permitted quantitative estimates of the pteroylglutamates present. The results showed that the vitamin B(12)-deficient livers were more severely depleted of tetrahydrofolates and formyltetrahydrofolates than of methyltetrahydrofolates and that as the deficiency developed they were more severely depleted of the higher polyglutamates than of the monoglutamate within each of these classes. Results from animals injected with [2-(14)C]folate indicated an impairment of the exchange between pteroylmonoglutamates and pteroylpolyglutamates in the livers of deficient animals. 5. In vitamin B(12)-deficient animals with food intakes below 200g/day some of the liver folates were not completely reduced and some degradation of pteroylpolyglutamates was detected. The latter condition may have been associated with fatty liver. 6. The results are discussed in relation to current theories of vitamin B(12)-folate interactions.     

The effect of antimetabolites on the microbial biosynthesis of vitamin B12 and related compounds

Summary Two compounds which are both antimetabolites and precursors of vitamin B12, o-phenylendiamine, and 5,6-dimethylbenzimidazole, stimulated the production of vitamin B12 by Propionibacterium freudenreichii at concentrations which were subinhibitory for growth. The stimulatory effect of the compounds depended not only on their concentration, but also on the time of addition. During cultivation, two chromatographically distinguishable fractions with vitamin B12 activity were formed. At concentrations which stimulated production of vitamin B12, only the biosynthesis of true vitamin B12 (cyanocobalamin) took place, while the biosynthesis of the analogue with a higher molecular weight was inhibited.     

Utilisation of tomato pomace as a substrate for the production of vitamin B12--a preliminary appraisal

The cellulose fraction in tomato pomace was hydrolysed using Trichoderma reesei, and the resultant sugars were fermented with Propionibacterium shermanii to produce vitamin B12. A multifactorial experiment revealed that aeration of the culture of T. reesei gave substantial improvements in cellulase activity as did higher concentrations of available nitrogen, but a rapid drop in pH appeared to inhibit extensive hydrolysis; after 14 days, the maximum level of cellulose degradation was only 34.4% of the total available, and the highest level of reducing sugars achieved was 15 g l(-1). When flasks with the latter concentration of reducing sugars were inoculated with P. shermanii, 11.1 mg l(-1) of B12 were produced under optimum conditions. If the degree of hydrolysis of the cellulose could be increased, then sufficient vitamin B12 might be generated to justify extraction but, even if purification does not prove to be economically feasible, a fermented tomato pomace (dried) with 50-55 mg kg(-1) or more of B12 could prove a useful feedstuff for animals.     

Biosynthesis of vitamin B12 by Propionibacterium freudenreichii subsp. shermanii ATCC 13673 using liquid acid protein residue of soybean as culture medium

Vitamin B12 deficiency still persists, mainly caused by low intake of animal food products affecting vegetarians, vegans, and populations of underdeveloped countries. In this study, we investigate the biosynthesis of vitamin B12 by potential probiotic bacterium using an agroindustry residue, the liquid acid protein residue of soybean (LAPRS), as a low-cost, animal derivate-free alternative culture medium. Cultures of Propionibacterium freudenreichii subsp. shermanii ATCC 13673 growing in LAPRS for vitamin B12 biosynthesis were studied using the Plackett–Burman experimental approach, followed by a central composite design 2² to optimize the concentration of significant variables. We also performed a proteolytic treatment of LAPRS and evaluated the optimized–hydrolyzed medium influence on the microbial growth and metabolism in shaker flask and bioreactor experiments. In this all-plant source medium, P. freudenreichii subsp. shermanii produced high concentrations of cells and high amounts of vitamin B12 (0.6 mg/g cells) after process optimization. These results suggest the possibility of producing vitamin B12 by a potential probiotic bacterium in a very cheap, animal derivate-free medium to address the needs of specific population groups, at the same time reducing the production costs of this essential vitamin.     

Effect of propionate pathway metabolites on the oxidative activity of liver mitochondria under normal conditions and in vitamin B12 deficiency]

We performed a comparative investigation in vivo and in vitro of the propionate and methylmalonate effect on oxidative activity of liver mitochondria in control and vitamin B12-deficient rats and found that efficiency of the effects were less pronounced in vitamin B12-deficient rats. It is also shown that the rates of respiration and phosphorylation decreased in liver mitochondria of vitamin B12-deficient rats.     

Effect of high levels of dietary folic acid on folate metabolism in vitamin B12 deficiency

The effect of administering high levels of folic acid to vitamin B12-deficient animals was studied. In B12 deficiency histidine oxidation is decreased. This is the result of both decreased liver folate levels and increases in the proportion of methyltetrahydrofolates. The purpose of this study was to determine if the addition of very high levels of folic acid to B12-deficient diets could increase liver folates and thereby restore histidine oxidation. Rats were fed a soy protein B12-deficient diet containing 10% pectin which has been shown previously to accelerate B12 depletion. When this diet was supplemented with B12 and folic acid, histidine oxidation was 5.4% in 2 h and the livers contained 3.49 micrograms of folate/g. In the absence of B12, the histidine oxidation rate was 0.34% and the liver folate level was 1.33 micrograms/g. When 200 mg/kg of folic acid was added to the B12-deficient diet there was no increase in histidine oxidation (0.35%) but the liver folates were increased to 3.68 micrograms which is about the same as that with B12 supplementation. The percentage tetrahydrofolate of the total liver folates was the same with and without a high level of dietary folic acid. Thus there was an increase in the absolute level of tetrahydrofolate without any increase in folate function as measured by histidine oxidation. Red cell folate levels were the same with and without B12, which is in contrast to the markedly lower liver folate levels in B12 deficiency. These data suggest a difference between B12 regulation of folate metabolism in the liver and in the bone marrow.     

Polyamine concentrations in the brain of vitamin B12-deficient rats

To study the pathophysiology of the neuronal degeneration in vitamin B12 deficiency, we investigated the concentrations of the polyamines putrescine, spermidine, and spermine in brain regions and liver using high-performance liquid chromatography with fluorescence detection. Male Wistar rats were fed either a control or vitamin B12-deficient diet for 20 weeks. No remarkable behavioral changes were observed. Serum vitamin B12 and hepatic methionine concentrations were significantly lower and hepatic homocysteine was elevated in rats fed vitamin B12-deficient diet than in controls. Vitamin B12 deficiency was associated with decreased concentrations of spermidine, spermidine in liver and some regions of brain, although there were no observed abnormalities in behavior. These results suggest that vitamin B12 deficiency may play a role in neuronal degeneration through the disturbance of polyamine concentrations in rat brain.