Effect of water soluble vitamins and their analogues on growth of Candida albicans II. Vitamin B12, thiamine,oxythiamine, neopyrithiamine,substituted pyrimidines and thiazoles

Summary By employing wide ranges in vitamin concentrations in biotin basal mineral synthetic medium, it was demonstrated that vitamin B₁₂ markedly stimulated the growth ofCandida albicans, the organism showing a partial dependency upon this vitamin. Growth inhibition by 5-fluorouracil was reversed non-competitively by vitamin B₁₂, suggesting that B₁₂ has a role in nucleic acid biosynthesis of the organism. Thiamine was growth stimulatory, the organism being partially dependent upon this vitamin as well. Neopyrithiamine and oxythiamine were growth inhibitory in thiamine-free biotin basal mineral synthetic medium although the halves of each inhibitor compound were non-inhibitory. Neopyrithiamine inhibition was reversed by intact thiamine but not by pyrimidine thiamine or thiazole thiamine; while oxythiamine inhibition was reversed by thiamine and pyrimidine thiamine but not by thiazole thiamine, the inference being drawn that oxythiamine selectively blocks utilization of pyrimidine thiamine. Twenty-seven different substituted pyrimidines, thiazoles and related thiamine compounds were all utilizable byC. albicans in thiamine-free basal synthetic mineral medium, the organism presumably synthesizing thiamine when presented with the constituent parts of these thiamine analogues. Substitution of sulfur of the thiazole ring with oxygen, as in -methyloxazolium, failed to produce an inhibitory compound forC. albicans. Acetylthiamine, allithiamine, cocarboxylase, tetrahydrothiamine and dihydrothiamine were equally as growth stimulatory as thiamine.     

PRODUCTION OF VITAMIN B12, THIAMINE,AND BIOTIN BY PHYTOPLANKTON1

Some ecologically important phytoplankters released vitamins into culture medium during growth. Skeletonema costatum and Stephanopyxis turris (vitamin B₁₂-requirers) produced both thiamine (vitamin B₁) and biotin when growing with either 12 or 2 ng vitamin B₁₂/liter. Gonyaulax polyedra (vitamin B₁₂-requirer) produced thiamine with 12 ng vitamin B₁₂/liter, and Coccolithus huxleyi (thiamine-requirer) produced vitamin B₁₂ and biotin with 120 ng thiamine/liter, but only biotin with 10 ng thiamine/liter. The amount of vitamin produced by an alga and rate at which it was produced varied with the phytoplankter, the concentration of the required vitamin, and incubation time. Vitamins produced during early and exponential growth were due to excretions, and those produced at stationary growth resulted from excretion and release due to cell lysis. Uptake of the required vitamin by all phytoplankters was greatest during the first few days of incubation. On continued incubation the rate of uptake/cell decreased. In the sea phytoplankters may contribute a major portion of the amount of dissolved vitamins.     

VITAMIN B12, THIAMINE,AND BIOTIN CONTENTS OF MARINE PHYTOPLANKTON1

An extraction procedure was developed for determining vitamin B₁₂, thiamine, and biotin contents of marine phytoplankton. Phytoplankters were collected either by centrifugation or by retention on a glass fiber filter, then heated at 100 C for I hr in 100 ml of vitamin-free seawater acidified to pH 3.5 with HCl. The extract, after debris removal, was filter-sterilized and analyzed, for vitamin B₁₂, thiamine, and biotin with standard vitamin assay procedures. The vitamin contents of haeodactylum tricornutum, Skeletonema costatum, Stephanopyxis turris, and occolithus liuxleyi were determined during growth in batch cultures. P. tricornutum (non-vitamin requirer) growing in aerated cultures contained 0.29–0.96 ng B₁₂, 5–15 ng thiamine, and 0.45–1.70 ng biotin/mg C. Under similar conditions S. costatum (B₁₂-requirer) contained about 0.06 ng B₁₂, 5–36 ng thiamine, and 0.16–2.10 ng biotin/mg C. The concentrations of vitamin were generally similar during some portion of the growth curve, eg, logarithmic growth. The vitamin B₁₂, content of S. costatum growing under nonaerated conditions decreased when medium B₁₂, was reduced. The biotin content did not change when medium B₁₂ was decreased. The thiamine content per unit weight of C. huxleyi (thiamine-requirer) growing with either 10 or 120 ng/liter thiamine decreased under both medium concentrations, indicating no net synthesis of the vitamin.     

Influence of Vitamin B12 and Cocultures on the Growth of Dehalococcoides Isolates in Defined Medium

Bacteria belonging to the genus Dehalococcoides play a key role in the complete detoxification of chloroethenes as these organisms are the only microbes known to be capable of dechlorination beyond dichloroethenes to vinyl chloride (VC) and ethene. However, Dehalococcoides strains usually grow slowly with a doubling time of 1 to 2 days and have complex nutritional requirements. Here we describe the growth of Dehalococcoides ethenogenes 195 in a defined mineral salts medium, improved growth of strain 195 when the medium was amended with high concentrations of vitamin B₁₂, and a strategy for maintaining Dehalococcoides strains on lactate by growing them in consortia. Although strain 195 could grow in defined medium spiked with ~0.5 mM trichloroethene (TCE) and 0.001 mg/liter vitamin B₁₂, the TCE dechlorination and cellular growth rates doubled when the vitamin B₁₂ concentration was increased 25-fold to 0.025 mg/liter. In addition, the final ratios of ethene to VC increased when the higher vitamin concentration was used, which reflected the key role that cobalamin plays in dechlorination reactions. No further improvement in dechlorination or growth was observed when the vitamin B₁₂ concentration was increased to more than 0.025 mg/liter. In defined consortia containing strain 195 along with Desulfovibrio desulfuricans and/or Acetobacterium woodii and containing lactate as the electron donor, tetrachloroethene (~0.4 mM) was completely dechlorinated to VC and ethene and there was concomitant growth of Dehalococcoides cells. In the cultures that also contained D. desulfuricans and/or A. woodii, strain 195 cells grew to densities that were 1.5 times greater than the densities obtained when the isolate was grown alone. The ratio of ethene to VC was highest in the presence of A. woodii, an organism that generates cobalamin de novo during metabolism. These findings demonstrate that the growth of D. ethenogenes strain 195 in defined medium can be optimized by providing high concentrations of vitamin B₁₂ and that this strain can be grown to higher densities in cocultures with fermenters that convert lactate to generate the required hydrogen and acetate and that may enhance the availability of vitamin B₁₂.     

Formation of cobalt-porphyrin by Corynebacterium simplex grown on hydrocarbon media

A vitamin B₁₂-producing and hydrocarbon-utilizing bacterium, Corynebacterium simplex, accumulated an appreciable amount of cobalt-porphyrin in cultural filtrates when grown on a n-hexadecane medium containing sufficient amounts of cobaltous sulfate and an appropriate detergent. When grown without the detergent, the cobalt-porphyrin was found only in the cells of the organism. In the latter case, the content of cobalt-porphyrin was comparable to that of vitamin B₁₂ and 7 times lower than that of iron-porphyrin. Though the organism required cobaltous sulfate for optimal growth, the requirement could be efficiently replaced by the supplementation of cobalt-porphyrin and partly of vitamin B₁₂. The porphyrin moieties of extra- and intracellular cobalt-porphyrin were identified as coproporphyrin III in both cases.     

STUDIES ON CHLOROPLAST DEVELOPMENT AND REPLICATION IN EUGLENA : I. Vitamin B12 and Chloroplast Replication

When Euglena gracilis is grown under vitamin B₁₂ deficiency conditions, the amount of protein and of chlorophyll per cell increase with decrease of B₁₂ in the medium and consequently in the cell. The increase in cell protein is proportional to and precedes an increase in the number of chloroplasts per cell. This replication of the chloroplasts under deficiency conditions is not accompanied by nuclear or cell division. It is concluded that chloroplast replication in Euglena gracilis is independent of nuclear and cellular replication, at least under B₁₂ deficiency conditions. We established a graph of the growth of Euglena under different concentrations of vitamin B₁₂ added to the growth medium, which permitted us to calculate that at least 22,000 molecules of vitamin B₁₂ per cell are required to give normal growth.     

Nutrition of Volvulina Playfair*

SYNOPSIS. Vitamin B₁₂, biotin and thiamine requirements of 10 strains of Volvulina steinii and 1 strain of V. pringsheimii were studied. Vitamin B₁₂ is required for growth of both species, thiamine stimulates growth slightly, and biotin has no discernible effect on growth. The minimum concentration of vitamin B₁₂ giving a growth response in V. steinii, strain SC-2, was 10^?8 g/ml, and maximum growth response was obtained with 1.1 × 10^?7 g/ml. An organic carbon source is required for growth of V. steinii but not of V. pringsheimii. Growth of V. steinii, strain SC-2, occurred in 20 of 21 carbon sources tested. Optimal growth with each carbon source was largely dependent upon pH. Except for pyruvate, acetate, and ethanol, carbon source utilization was light-dependent, and growth in ethanol was reduced in the dark. Isocitric lyase activity was detected in V. steinii grown on acetate medium.     

EFFECTS OF CERTAIN LIMITING CONDITIONS ON THE SYNTHESIS OF B VITAMINS BY YEAST

In yeast crops which were grown in the presence of various inhibitors, there was considerable variation in content of the various B vitamins. A higher degree of parallelism in variation in content was found to exist between thiamine and niacin than between any other pair of vitamins; this has been interpreted as indicating that the predominant functions of these two vitamins are their established rôles in fermentation. Values for inositol indicate that it may be involved in fermentation processes, but this is not the case for other members of the B complex. Biotin appears to be unique since in no case did the biotin content of yeast grown in the presence of an inhibitor fall below that of the control yeast. There was some evidence of synthesis of biotin, or a material with biotin activity, in the presence of certain inhibitors, the most striking instance being with sulfaguanidine. An exogenous supply of biotin was essential for extensive proliferation of F. B. yeast, and yeast grown in a medium to which biotin was the only added vitamin contained the B vitamins in amounts very similar to those found in the control yeast, the most marked differences being in increased vitamin B₆ and p-aminobenzoic acid contents. In the absence of biotin, significant amounts of all of the B vitamins except biotin were synthesized, both in the presence and absence of certain other members of the B complex. The addition of thiamine, pyridoxine, inositol, and β-alanine to the culture medium caused a reduction in the amounts of vitamin B₆ and p-aminobenzoic acid synthesized. F. B. yeast was able to grow in a xylose medium only when certain of the B vitamins were present, and even then growth was limited. Evidence was obtained for some synthesis of all of the vitamins investigated except biotin and vitamin B₆. The most significant differences in vitamin content between galac yeast and the parent F. B. strain were in folic acid and vitamin B₆, the former being considerably reduced in amount, the latter being increased.     

Effect of water soluble vitamins and their analogues on growth of candida albicans. III. Para-aminobenzoic acid,nicotinic acid,inositol and their analogues

Summary By using high concentrations of vitamins in biotin basal synthetic mineral medium,Candida albicans was shown to possess a partial dependency forp-aminobenzoic acid, nicotinic acid and inositol. Sodium gantrisin [N¹-3,4-dimethyl-5-isoxazolyl sulfanilamide)] was growth inhibitory in the absence ofp-aminobenzoic acid and its effect was reversed byp-aminobenzoic acid. Similarly, pyridine-3-sulfonic acid was growth inhibitory to the organism in the absence of nicotinic acid and its effect was reversed by nicotinic acid. Additions of biotins, thiamine, vitamin B₁₂, nicotinic acid,p-amino-benzoic acid and inositol to basal synthetic medium showed clear-cut growth stimulation for each vitamin. Parallel omission type experiments on the other hand, demonstrated a masking effect of one vitamin on another. Ascorbic acid, riboflavin, calcium pantothenate choline, folic acid and thioctic acid were without effect. A new procedure for the determination of microbial vitamin requirements was outlined.     

Purification of 7-Keto-8-aminopelargonic Acid-7,8-Diaminopelargonic Acid Aminotransferase,an Enzym Involved in Biotin Biosynthesis,from Brevibacterium divaricatum

Vitamin B₆ is synthesized by green Cytisus scoparius callus and green Phellodendron amurense callus cultured on Linsmaier and Skoog Agar-medium with 10^?5m of ±-naphthaleneacetic acid (NAA) and 10^?6 m of 6-benzyladenine (BA). Even when thiamine and inositol were omitted from this medium, the growth and vitamin B₆ content of Cytisus scoparius callus did not change. Vitamin B₆ contents of clones of the calluses varied and were unstable during long-term subculture. Clonal selection was repeated to obtain stable strains with high vitamin B₆ content, and the vitamin B₆ content of one strain of green Cytisus scoparius callus became 4-times higher than that of the green leaves.     

Uptake and accumulation of B-group vitamers in Saccharomyces cerevisiae in ethanol-stat fed-batch culture

The uptake and accumulation of the B-group vitamins thiamine, riboflavin, nicotinamide, pantothenic acid and pyridoxine in Saccharomyces cerevisiae was studied by gradually increasing the specific dosage of vitamins in an ethanol-stat fed-batch culture. Thiamine, nicotinamide, pantothenic acid, and pyridoxine were almost completely taken up at low vitamin dosages. Thiamine was determined to be the major accumulating form of vitamin B₁ while most of the assimilated nicotinamide and pantothenic acid accumulated in cofactor forms. Despite the obvious uptake of pyridoxine, accumulation of B₆ vitamers was not observed. In contrast with the other vitamins studied, riboflavin began accumulating in the culture medium immediately after vitamin addition was initiated. By the end of the experiment, the apparent uptake of all vitamins exceeded their accumulation in the cells. Variations in the growth rate of yeast at different vitamin dosages demonstrate the importance of balancing the vitamins in the media during cultivation.     

Growth phase-dependent active transport of pyridoxine in a fission yeast, Schizosaccharomyces pombe

Schizosaccharomyces pombe showed maximum pyridoxine uptake activity around 10 h after starting cultivation. High concentrations of thiamine and pyridoxine in the medium did not affect the activity or the time but changed intracellular levels of vitamin B₆ compounds. Pyridoxine was taken up by a saturable mechanism with two kinds of affinity (K_m 22.4 μM and 118 μM). The uptake depended on the energy produced anaerobically with an optimum pH of 4.5. The uptake was completely inhibited by amiloride, sodium azide or 2,4-dinitrophenol. The uptake system of the fission yeast was different in various respects from that of a budding yeast.     

Cytokinin activation of thiamine biosynthesis in tobacco callus cultures

Bioassays of tissue extracts show that high (500-1000 μg/liter) kinetin concentrations which permit growth of tobacco callus cultures on media without added thiamine activate the biosynthesis of this vitamin by the tissues. Although the tissue concentration of thiamine may fall appreciably, it is maintained at a level adequate for survival and slow growth of the cultures, and there is a large net increase in total thiamine content per culture with time. In the second and subsequent passages of tissue on a thiamine free medium, growth is obtained only when high kinetin concentrations are maintained. Effective inhibition of growth by antithiamines suggests that thiamine is utilized by the high-kinetin tissue.

In the presence of low (30-100 μg/liter) kinetin concentrations, which would be optimal for growth in the presence of thiamine, growth only occurs early in the first passage of tissue from a medium with the vitamin to one without it. The thiamine concentration in the tissues falls to low levels, and no net biosynthesis is apparent. The tissues turn dark and die after 2 to 3 weeks. In contrast with this, in the absence of both added thiamine and kinetin no appreciable growth occurs, but the tissues keep their normal appearance, retain their thiamine content, and may stay alive for several weeks.

     

Effect of methionine and vitamin B-12 on the activities of methionine biosynthetic enzymes in metJ mutants of Escherichia coli K12

The effects of supplementation of growth medium with high concentrations of methionine (5 mm) and/or vitamin B₁₂ (10 nm) on the activities of five enzymes of the methionine regulon were measured in wild-type Escherichia coli K12, a metJ prototrophic and three metJ methionine auxotrophic derivatives. Growth on vitamin B₁₂ causes lowering of the activities of the non-B₁₂ methyltransferase while growth on methionine causes elevation of its activity in all four metJ mutants. The previous observation that this enzyme is not repressed by vitamin B₁₂ addition in metH mutants together with our observation that vitamin B₁₂ causes repression in mutants (metF) unable to synthesize the donor for homocysteine methylation supports the model of Kung et al. (10) that the holo-B₁₂-methyltransferase functions as a repressor of synthesis of the non-B₁₂-methyltransferase. Growth on methionine causes lowering of cystathionase activity, and growth on vitamin B₁₂ results in elevation of cystathionase activity in a metJ prototroph and one metJ auxotroph. The metJmetA strain (RG326) has a higher than normal level of cystathionase while the metJmetF strain (RG191) has lower than normal cystathionase activity. These results indicate the existence of a metJ independent system that modulates the activity of cystathionase possibly in response to changes in concentration of unidentified metabolite(s).     

Iron salts and transferrin are specifically required for cell division of cultured 3T6 cells.

3T6 Swiss mouse fibroblasts can be plated in medium without serum. Prostaglandin F₂^∞, fibroblastic growth factor, epidermal growth factor and insulin stimulate DNA synthesis in medium containing vitamin B₁₂. A combination of these factors, however, does not stimulate cell division under our conditions. Iron salts and transferrin or low concentrations of serum are required to be concurrently present with the growth factors before cell division is observed.     

Chemically Defined Minimal Medium for Growth of the Anaerobic Cellulolytic Thermophile Clostridium thermocellum

A minimal chemically defined medium has been developed for Clostridium thermocellum. The growth factors required are biotin, pyridoxamine, vitamin B₁₂, and p-aminobenzoic acid.     

The Relationship of Cobalt Requirement to Vitamin B12-dependent Methionine Synthesis in Rhizobium meliloti

As a growth factor, Rhizobium meliloti required cobalt ion, or vitamin B₁₂ which was found to be incorporated into the cells without decomposition to cobalt ion. Trial of replacement for cobalt ion by the addition of various compounds to the cobalt-deficient medium revealed that methionine could substitute for cobalt ion and promote the growth in response to its concentration. Furthermore, B₁₂-dependent methionine synthetase was demonstrated in the cell-free extracts of this microorganism. The morphological change of R. meliloti by the additions to the medium was observed microscopically.     

Sinorhizobium meliloti Cells Require Biotin and either Cobalt or Methionine for Growth

Sinorhizobium meliloti is usually cultured in rich media containing yeast extract. It has been suggested that some components of yeast extract are also required for growth in minimal medium. We tested 27 strains of this bacterium and found that none were able to grow in minimal medium when methods to limit carryover of yeast extract were used during inoculation. By fractionation of yeast extract, two required growth factors were identified. Biotin was found to be absolutely required for growth, whereas previously the need for this vitamin was considered to be strain specific. All strains also required supplementation with cobalt or methionine, consistent with the requirement for a vitamin B₁₂-dependent homocysteine methyltransferase for methionine biosynthesis.     

The Thiamine Content of Phytoplankton Cells Is Affected by Abiotic Stress and Growth Rate

Thiamine (vitamin B₁) is produced by many plants, algae and bacteria, but by higher trophic levels, it must be acquired through the diet. We experimentally investigated how the thiamine content of six phytoplankton species belonging to five different phyla is affected by abiotic stress caused by changes in temperature, salinity and photon flux density. Correlations between growth rate and thiamine content per cell were negative for the five eukaryotic species, but not for the cyanobacterium Nodularia spumigena. We demonstrate a high variability in thiamine content among phytoplankton species, with the highest content in N. spumigena. Salinity was the factor with the strongest effect, followed by temperature and photon flux density, although the responses varied between the investigated phytoplankton species. Our results suggest that regime shifts in phytoplankton community composition through large-scale environmental changes has the potential to alter the thiamine availability for higher trophic levels. A decreased access to this essential vitamin may have serious consequences for aquatic food webs.