VITAMIN B12-BINDER AND OTHER ALGAL INHIBITORS1

Euglena gracilis Klebs, Poterioochromonas malhamensis (Pringsheim) Peterfi, Monochrysis lutheri Droop, Isochrysis galbana Parke and Phaeodactylum tricornutum Bohlin are known to release into the medium a substance which binds free vitamin B₁₂. The binder, apparently a glycoprotein, makes vitamin B₁₂ unavailable and inhibits growth of vitamin B₁₂-requiring microorganisms. Culture filtrates of selected marine diatoms, chrysophytes, cryptophytes, dinoflagellates and green algae contained the binder, indicating that binder release was not restricted to any algal group. However the three prokaryotic bluegreens tested do not produce B₁₂-binder. Production is also independent of the nutritional requirements of the donor, being produced by autotrophs and auxotrophs. The binders produced by these marine species have similar properties: they are heat labile; inhibition is not species-specific; it is competitive, being reversed by adding B₁₂. Production increases with density of the culture and is not restricted to stationary or scenescent cells. The marine species tested produced much less B₁₂ than the freshwater Euglena and Poterioochromonas; the inhibition is reversed by 20–50 ng · 1^?1 of B₁₂ for marine species which reach moderate densities and by 150–300 ng · 1^?1 B₁₂ for the densely growing species. Consequently the binder may affect the growth of B₁₂-requiring species only in environments like the open ocean poor in B₁₂. By contrast, the marine algae produce other inhibitors which are often heat stable and very inhibitory. These inhibitors, being species-specific and less labile, may be more important in affecting the succession of algal species in natural waters.     

Seasonal and Spatial Distribution of Vitamin B12 in a Coastal Area of Eastern Mediterranean Sea

The seasonal and spatial distribution of vitamin B₁₂ was investigated in Eastern Mediterranean (Saronicos Gulf, Aegean Sea). Vitamin B₁₂ concentration had an annual range 0.12–7.93 ng. 1⁻¹ and an annual mean 1.88 ng. 1⁻¹. The statistical analysis of data indicated significant seasonal and regional variations of vitamin B₁₂ in this area and an inverse relationship of this vitamin with chl a. The results showed that the Eastern Mediterranean Sea contains less vitamin B₁₂ than the Western Mediterranean Sea.     

GROWTH OF VITAMIN B12-REQUIRING MARINE DIATOMS IN MIXED LABORATORY CULTURES WITH VITAMIN B12-PRODUCING MARINE BACTERIA12

The vitamin B₁₂ requirement of several marine diatoms can be satisfied in B₁₂^?limited laboratory cultures by heterotrophic marine bacteria isolated from the same waters and from sediments. The bacteria can utilize diatom excretory products, or the remains of dead diatom cells, in the production of the vitamin. The growth of 12 B₁₂¹? requiring diatoms (7 genera) in mixed cultures with 14 different bacteria (without added B₁₂) was compared to the growth of those same diatoms in axenic cultures with excess added B₁₂. Diatom growth was generally rapid in the first few days, followed by sustained, slower growth. The diatom yields in mixed cultures ranged from 0.8 to 84% of the yields in axenic cultures with added B₁₂. In a detailed study of one mixed culture, increases in diatom densities were paralleled by increases in cell densities of the bacterium during the first few days of exponential diatom growth. During the period of slow diatom growth, when diatom densities oscillated but steadily increased, the decreases in diatom densities were associated with increased bacterial growth. This suggests that death of a fraction of the B₁₂-limited diatom population releases sufficient organic matter to stimulate growth of the bacteria and their subsequent excretion of B₁₂; this B₁₂ in turn stimulates further growth of the diatoms. Diatom-bacteria interactions leading to the production of B₁₂ may be important in maintaining viable populations of B₁₂-requiring diatoms in nutrient-poor waters during periods between blooms, when conditions are unfavorable for rapid growth.     

SECRETION OF VITAMINS AND AMINO ACIDS INTO THE ENVIRONMENT BY OCHROMONAS DANICA1,2

Ochromonas danica grown on a chemically defined medium under controlled conditions in the light synthesized the following vitamins: ascorbate, B₆, N⁵-methyltetrahydrofolate, tetrahydrofolate polyglutamates, oxidized folate monoglutamates, nicotinate, pantothenate, riboflavin, vitamin A, β-carotene, and vitamin E but no vitamin. B₁₂. The cells also secreted molecules into their growth medium including the vitamins ascorbate, B₆, the above folates, nicotinate, pantothenate, riboflavin, vitamin E, and the amino acids alanine, aspartic acid, leucine, and valine. The role of such secretions in nature is discussed.     

B12 SPECIFICITY OF MARINE CENTRIC DIATOMS1, 2

Twenty-one species (23 isolates) of marine diatoms were examined for their capacity to utilize analogs of cyanocobalamin for growth at the ecologically significant concentration of 4 ng 1-¹. Yields due to the analogs were compared to those produced by B₁₂. Responses of the various clones to the analogs were not all-or-none, but varied continuously; thus, assigning the clones to the conventional B₁₂ specificity types is a convenient but arbitrary classification. The use of 10 and 1% levels of response is suggested for such classification. At the 10% level of response, 11 clones had coliform, 4 lactobacillus, and 8 mammalian specificity patterns. At the 1% response level, 14 had coliform, 5 lactobacillus, and 4 mammalian specificities. All clones exceed the 10% response level on all benzimi-dazole-containine analogs tested. Few clones showed definite enough patterns of response to make them potentially useful for differential bioassay. The clones suggested are clone 675-D (Bidclulphia sp.?), clone F^;-3 (Fragilaria sp.?), and the estuarine clone of Cyclotella nana (3H).     

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.     

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.     

EFFECT OF HORMONES AND VITAMIN B12 ON GAMETOPHORE DEVELOPMENT IN THE MOSS PYLAISIELLA SELWYNII

Bud formation in the moss Pylaisiella selwynii is greatly enhanced by cytokinins at concentrations as low as 10⁻¹²m , yet these buds usually fail to develop into normal gametophores. Various ratios at different concentrations of the cytokinin N-6-γ,γ-dimethylallylaminopurine to indoleacetic acid failed to enhance bud initiation over that obtained with cytokinin alone or to permit normal gametophore development. Deletion of the cobaltous ions from the culture medium prevented the appearance of the few gametophores usually formed in the complete medium, but different amounts of cobaltous ion did not significantly enhance initiation of gametophore development. Bud initiation was enhanced 3- to 20-fold by vitamin B₁₂ at 10⁻⁵m or by B₁₂ coenzyme at 10⁻⁴m , and the time of appearance of these buds was advanced by 6–12 days compared to control plants. At these concentrations of the B₁₂ compounds the buds formed normal gametophores, but at 10⁻⁴m vitamin B₁₂ they grew into callus-like masses similar to those obtained with cytokinins. Although the effects of B₁₂ on bud initiation and development mimicked those of cytokinins, except in permitting normal development, no additive or synergistic effects were observed when they were tested together. It is suggested that B₁₂ may play a regulatory role in the control of gametophore initiation and development in mosses.     

Studies on the vitamin B12 auxotrophy of Rhodocyclus purpureus and two other vitamin B12-requiring purple nonsulfur bacteria

The vitamin B₁₂ requirement of Rhodocyclus purpureus 6770, Rhodospirillum tenue 1/67, and Rhodopseudomonas palustris G 53/2 was determined. A wide variety of biogenetic precursors of the vitamin including cobinamide, cobyric acid, cobinic acid and several partially amidated cobyrinic acids showed growth-promoting activity in all three strains. In R. purpureus vitamin B₁₂ could even be substituted by cobyrinic acid which is the first cobalt-containing precursor of vitamin B₁₂ so far established. Neither methionine, deoxynucleosides, dimethylbenzimidazole nor increased amounts of cobalt could replace vitamin B₁₂ as growth factor.Cupribalamin, which is a strong antimetabolite of vitamin B₁₂ in Escherichia coli 113-3 and Lactobacillus leichmannii ATCC 7830, exhibited only a weak antagonistic effect on growth of R. purpureus and R. tenue. Growth of R. palustris was not inhibited by cupribalamin. The cells of all three strains were shown to contain metal-free corrinoids in addition to cobalt-containing corrinoids. The principal products were identified as 5-deoxyadenosylcobalamin and hydrogenobalamin, the metal free analogue of vitamin B₁₂. The latter does not originate from the vitamin by removal of cobalt but is de novo biosynthesized as could be demonstrated in the case of R. purpureus by a labelling experiment with [¹³C] methyl-l-methionine.     

EFFECT OF THE SINKING RATE OF TWO DIATOMS (THALASSIOSIRA SPP.) ON UPTAKE FROM LOW CONCENTRATIONS OF PHOSPHATE1

The effect of the sinking rate, or rate of medium flow (φ) on the rate of phosphate incorporation (V) by the planktonic diatoms Thalassiosira fluviatilis Hust. and T. pseudonana Hasle & Heimdal in batch and chemostat cultures was determined by passing medium at defined flow rates (0.5–25.0 mm·min^?1) over algae on membrane filters. At concentrations from 1 to 100 μg phosphorus·l^?1 V, increases with increasing velocity of flow, approaching a maximum value (V_m) as described by the empirical relationship: where K_φ is the sinking rate value when V = 1/2 V_m+ V_o and V_o is the uptake at 0 rate of flow. By comparing uptake at controlled flow with uptake in a vigorously stirred medium, the phosphate concentration in the cell boundary layer can be determined. The sinking rate that reduces the phosphate concentration in the boundary layer to half of nominal concentration in the medium is much lower for the larger T. fluviatilis than for T. pseudonana. For both diatoms, it is inversely related to the nominal concentration.     

Production of extracellular vitamin B-12 compounds from methanol by Methanosarcina barkeri

Summary Production of vitamin B-12 compounds from methanol was carried out by Methanosarcina barkeri Fusaro, an anaerobic methanogen. The methanogen released about 40% to 70% of corrinoids irrespective of the culture medium used. The use of cysteine instead of Na₂S as the sole sulphur source for cell growth led to an increase in the cobalt chloride concentration in the culture medium up to 16 times the normal (0.6 mg·l^-1) without medium precipitation. This in turn resulted in an intracellular vitamin B-12 content of 5.6 mg·g dry cell^-1, the rest being discharged into the culture supernatant; this was 87 mg·l^-1, 73% of the total corrinoids after 20 repeated intermittently fed cultures and the final cell concentration was 5.8 g dry cell·l^-1. Taking advantage of this, continuous production of extracellular vitamin B-12 compounds was attempted with a fixed-bed bioreactor (carrier: diatomaceous clay). At a steady state operation at space velocity of 9 to 11 day^-1, the concentration of the discharged corrinoid was 6.8 to 7.9 mg·l^-1, having a vitamin B-12 activity of about 4 mg·l^-1. Total cell mass retained in the reactor was 39.6 g dry cell l-reactor^-1. Identification of the corrinoids revealed that 19% of the total corrinoids was comprised of the vitamin B-12 Factor III (5-hydroxybenzimidazolyl cobamide) and the remainder were mainly the base-free vitamin B-12 Factor B (cobinamide and its derivatives).     

Vitamin B12-dependent Methionine Biosynthesis and Its Metabolic Role in Corynebacterium simplex ATCC 6946, a Vitamin B12-producing and Hydrocarbon-utilizable Bacterium

A vitamin B₁₂-dependent N⁵-methyltetrahydrofoIate-homocysteine methyltransferase was found in cell-free extracts of Corynebacterium simplex ATCC 6946 grown aerobically in a medium containing hydrocarbon as a sole carbon source and the enzyme was partially purified. Absolute requirements for S-adenosylmethionine and an appropriate reducing system were observed for the transmethylation from N⁵-methyltetrahydrofolate. The same preparation catalyzed also the formation of methionine from homocysteine and methyl-B₁₂ under both aerobic and anaerobic conditions. The concentration of cobalt ion in the growth medium had a pronounced effect on the intracellular vitamin B₁₂ level and the activity of the vitamin-dependent methionine-synthesizing system in the bacterium. The relationship between the methionine synthesis and the methyl branched-chain fatty acid formation was discussed.     

A SURVEY OF AUXOTROPHY IN FIVE FRESHWATER DINOFLAGELLATES (PYRRHOPHYTA)1

Peridiniopsis polonicum (Wolosz.) Bourrelly requires vitamin B₁₂, and Peridinium limbatum (Stokes) Lemm. requires thiamin for growth. Unlike marine Peridinium species, Peridinium willei Huit.-Kaas, P. volzii Lemm., and P. inconspicuum Lemm. do not display auxotrophy. Peridinium volzii is strongly inhibited by concentrations of biotin above 1 μg L^?1.     

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.     

Utilization of Hydrocarbons and Vitamin B12 Production by Bacillus badius

The accumulation of vitamin B₁₂ by Bacillus badins grown on hydrocarbon was investigated. The bacterium could assimilate n-alkanes of C₁₁–C₁₈, ethanol, fumarate, α-ketoglutarate and malate. n-Alkanes of C₁₆–C₁₈, were the best for vitamin B₁₂ production. The bacterium utilized well all of the nitrogen sources tested. Above all, ammonium dihydrogen phosphate was the best for the bacteria] growth and vitamin B₁₂ production. Addition of organic nutrients such as malt extract and meat extract, and addition of metal ions such as ferrous and cobalt promoted the growth and vitamin B₁₂ production. Interestingly, vitamin B₁₂ was produced mostly in the supernatant. The cyanoform of the corrinoid predominantly formed in the supernatant would confirm the identity with cobalamin.     

Polymorphism of vitamin B12 [57Col binding proteins in rabbit serum

When rabbit serum labelled with vitamin B₁₂[⁵⁷Co] was subjected to starch gel electrophoresis and au;oradiography, three phenotypes of proteins capable of binding vitamin B₁₂ were observed. Family data revealed that these phenotypes (called TC-A, TC-AB and TC-B) are controlied by two codominant alleles (TC^A and TC^B), at an autosomic locus. Proteins capable of binding vitamin B₁₂ both in vivo and in vitro are commonly referred to as Transcobalamins and can be found in the serum of numerous animal species (for a review, see Glass, 1974; Allen, 1975; Stenman, 1975). Furthermore, Daiger et al. (1975a) have described seven different patterns of vitamin B₁₂ binding proteins which occur in human plasma and which are presumably controlled by four alleles. The present paper describes experiments in which both starch gel electrophoresis and autoradiography are used to identify three phenotypes of rabbit serum proteins responsible for binding vitamin B₁₂ in vitro. It was found that these three phenotypes are controlled by two allelic codominant genes, at an autosomic locus. Individual serum samples (30 μl), obtained from 385 White New Zealand rabbits varying in age from one month to three years, were incubated with 0.1 ng of vitamin B₁₂[⁵⁷Co] (specific activity: 180 μCi/μg; Lot 247; Radiochemical Centre, Amersham, England) at 37°C for 30 minutes. Starch gel electrophoresis and autoradiography were performed as described by Geldermann (1970) and Daiger et al. (1975b), respectively. Electrofocusing (pH range 3.5–9.5) was conducted in the 2117 Multiphor apparatus (LKB, Bromma, Sweden) according to the manufacturer's instructions. The resulting pH gradient was measured with a surface pH electrode (Ingold, Zürich, Switzerland).     

Production of 3‐hydroxypropionic acid from glycerol by recombinant Klebsiella pneumoniae ΔdhaTΔyqhD which can produce vitamin B12 naturally

3‐Hydroxypropionic acid (3‐HP) is an important platform chemical that can be used to synthesize a range of chemical compounds. A previous study demonstrated that recombinant Escherichia coli stains can produce 3‐HP from glycerol in the presence of vitamin B₁₂ (coenzyme B₁₂), when overexpressed with a coenzyme B₁₂‐dependent glycerol dehydratase (DhaB) and an aldehyde dehydrogenase. The present study examined the production of 3‐HP in recombinant Klebsiella pneumoniae strains, which naturally synthesizes vitamin B₁₂ and does not require supplementation of the expensive vitamin. The NAD⁺‐dependent gamma‐glutamyl‐gamma‐aminobutyraldehyde dehydrogenase (PuuC) of K. pneumoniae alone or with its DhaB was overexpressed homologously, and two major oxidoreductases, DhaT and YqhD, were disrupted. Without vitamin B₁₂ addition, the recombinant K. pneumoniae ΔdhaTΔyqhD overexpressing PuuC could produce ～3.8 g/L 3‐HP in 12 h of flask culture. However, this was possible only under the appropriate aeration conditions; 1,3‐propanediol (1,3‐PDO) (instead of 3‐HP) was mainly produced when aeration was insufficient, whereas a very small amount of both 3‐HP and 1,3‐PDO were produced when aeration was too high. The production of a small amount of 3‐HP under improper aeration conditions was attributed to either slow NAD⁺ regeneration (under low aeration) or reduced vitamin B₁₂ synthesis (under high aeration). In a glycerol fed‐batch bioreactor experiment under a constant DO of 5%, the strain, K. pneumoniae ΔdhaTΔyqhD, overexpressing both PuuC and DhaB could produce >28 g/L 3‐HP in 48 h with a yield of >40% on glycerol. Only small amount of 3‐HP was produced when cultivation was carried out at a constant aeration of 1 vvm or constant 10% DO. These results show that K. pneumoniae is potentially useful for the production of 3‐HP in an economical culture medium that does not require vitamin B₁₂. The results also suggest that the aeration conditions should be optimized carefully for the efficient production of 3‐HP while using this strain. Biotechnol. Bioeng. 2013; 110: 511–524. © 2012 Wiley Periodicals, Inc.     

EFFECT OF VITAMIN CONCENTRATIONS ON GROWTH AND DEVELOPMENT OF VITAMIN-REQUIRING ALGAE1

Vitamin-requiring marine algae, Cyclotella nana, Monochrysis lutheri, and Amphidinium carterae, were grown in batch culture with limiting concentrations of vitamin B₁₂, thiamine, and biotin, respectively. Cell numbers, average cell volumes, biomasses, ¹¹CO₂ uptake rates, and chlorophyll a contents were determined daily. Maximum ¹⁴CO₂ uptake rates in most vitamin concentrations were obtained at 2 days with C. nana and M. lutheri and at 4 days with A. carterae after starved cultures were exposed to the vitamin. Radiocarbon uptake rates approximately reflect biomass increases. Cell numbers were proportional to vitamin concentrations when cells were incubated for 2 to 3 more days. Cell sizes varied depending on time of incubation. Chlorophyll a content did not always reflect vitamin concentrations. Maximum carbon assimilation rates (K_m) and saturation constants (K_s) determined from ¹⁴CO₂, uptake rates in different vitamin concentrations during early incubation were higher than when determined from cell number in log phase growth. Dissolved vitamin B₁₂, thiamine, and biotin in many samples of seawaters were in the ranges which influence the growth rate, cell size, and chlorophyll a content of C. nana, M. lutheri, and A. carterae, respectively, in laboratory studies. The effects of vitamins on these algae in situ may be similar.     

Simulation of fermentation conditions for vitamin B12 biosynthesis from whey

Vitamin B₁₂ production in fermentation of Propionibacterium shermanii and Propionibacterium arl AKU 1251 in whey permeate medium has been studied. The observed results and simulated expected values obtained by fitting statistical equations to the recorded data showed that 24 h old inoculum, 5 mg iron l^?1 and 4% whey lactose were optimal for vitamin B₁₂ biosynthesis in both strains when fermentation was carried out under anerobic (84 h) and aerobic (84 h) conditions at 30°C. The supplementation of whey medium with 0.5% (NH₄)₂HPO₄ enhanced further the metabolite yield; however, the preference for a mixed carbon source (lactose + d-glucose or lactose + d-fructose) at different levels varied in the strains under study. P. shermanii, under optimal cultural conditions, was found to be a better strain than Propionibacterium arl AKU, 1251 in fermenting whey lactose for product (vitamin B₁₂) formation.     

Enrichment of some B-vitamins in plants with application of organic fertilizers

A review of the literature showed that plants grown with organic fertilizers often contain higher concentrations of vitamins B₁ (thiamin) and B₁₂ (cyanocobalamin) as compared with plants grown with inorganic fertilizers. Since plant roots were recently shown to be able to absorb B₁ and B₁₂, it was thus suspected that organic fertilizers (such as manure of diverse sources or sewage sludges which often contain relatively high concentrations of several vitamins) introduce additional vitamins into the soil which in turn leads to increased vitamins in the plants. This possibility was studied by measuring the B₁₂ content in the seeds of soybean and barley and in the leaves of spinach plants grown in soils amended with pure B₁₂ or cow dung (which is naturally rich in B₁₂). The addition of pure B₁₂ or cow dung did not alter the B₁₂ content in the soybean seeds but significantly increased that in the barley kernels and in the spinach leaves. For example, the addition of cow dung at the rate of 10 g kg^–1 increased the B₁₂ content in barley kernels by more than threefold (from 2.6 to 9.1 ng g^–1 DW) and in spinach leaves by close to twofold (from 6.9 to 17.8 ng g^–1 DW). Long-term addition of organic fertilizers to the soil also significantly increased the soil content of this vitamin. Since plants cannot synthesize B₁₂ and thus plant foods are normally fully devoid of (or have very low concentrations of) this vitamin, the finding that plants grown with organic fertilizers may contain relatively higher concentrations of this vitamin may have nutritional consequences in that the consumption of these plants by humans would inadvertently increase their intake of this vitamin. This may be of special benefit to people living by choice or by necessity on strict vegetarian diets who are known to be in danger of B₁₂ deficiency.