B12 Receptor Research Articles

Molecular Dissection of the Intrinsic Factor-Vitamin B12 Receptor, Cubilin, Discloses Regions Important for Membrane Association and Ligand Binding

Cubilin, the receptor for intrinsic factor-vitamin B12, is a novel type of high molecular weight receptor consisting of a 27 CUB (complement components C1r/C1s, Uegf, and bone morphogenic protein-1) domain cluster preceded by 8 epidermal growth factor repeats and a short N-terminal sequence. In addition to binding the vitamin B12-carrier complex, cubilin also binds receptor-associated protein. To delineate the structures for membrane association and ligand binding we established a panel of stable transfected Chinese hamster ovary cells expressing overlapping segments of rat cubilin. Analysis of conditioned media and cell extracts of transfected cells revealed that the N-terminal cubilin region conveys membrane association. Helical plotting of this region demonstrated a conserved amphipathic helix pattern (Lys74-Glu109) as a candidate site for hydrophobic interactions. Ligand affinity chromatography and surface plasmon resonance analysis of the secreted cubilin fragments showed ligand binding in the CUB domain region. Further dissection of binding-active fragments localized the binding site for intrinsic factor-vitamin B12 to CUB domains 5-8 and a receptor-associated protein-binding site to CUB domains 13-14. In conclusion, the N-terminal cubilin region seems crucial for membrane association, whereas the CUB domain cluster harbors distinct sites for ligand binding.

The intrinsic factor-vitamin B12 receptor, cubilin, is a high-affinity apolipoprotein A-I receptor facilitating endocytosis of high-density lipoprotein.

Cubilin is the intestinal receptor for the endocytosis of intrinsic factor-vitamin B12. However, several lines of evidence, including a high expression in kidney and yolk sac, indicate it may have additional functions. We isolated apolipoprotein A-I (apoA-I), the main protein of high-density lipoprotein (HDL), using cubilin affinity chromatography. Surface plasmon resonance analysis demonstrated a high-affinity binding of apoA-I and HDL to cubilin, and cubilin-expressing yolk sac cells showed efficient 125I-HDL endocytosis that could be inhibited by IgG antibodies against apoA-I and cubilin. The physiological relevance of the cubilin-apoA-I interaction was further emphasized by urinary apoA-I loss in some known cases of functional cubilin deficiency. Therefore, cubilin is a receptor in epithelial apoA-I/HDL metabolism.

Mutations in CUBN, encoding the intrinsic factor-vitamin B12 receptor, cubilin, cause hereditary megaloblastic anaemia 1.

Megaloblastic anaemia 1 (MGA1, OMIM 261100) is a rare, autosomal recessive disorder characterized by juvenile megaloblastic anaemia, as well as neurological symptoms that may be the only manifestations. At the cellular level, MGA1 is characterized by selective intestinal vitamin B12 (B12, cobalamin) malabsorption. MGA1 occurs worldwide, but its prevalence is higher in several Middle Eastern countries and Norway, and highest in Finland (0.8/100,000). We previously mapped the MGA1 locus by linkage analysis in Finnish and Norwegian families to a 6-cM region on chromosome 10p12.1 (ref. 8). A functional candidate gene encoding the intrinsic factor (IF)-B12 receptor, cubilin, was recently cloned; the human homologue, CUBN, was mapped to the same region. We have now refined the MGA1 region by linkage disequilibrium (LD) mapping, fine-mapped CUBN and identified two independent disease-specific CUBN mutations in 17 Finnish MGA1 families. Our genetic and molecular data indicate that mutations in CUBN cause MGA1.

The Intrinsic Factor-Vitamin B12 Receptor, Cubilin, Is Assembled into Trimers via a Coiled-coil α-Helix

A large protein was purified from bovine kidney, using selective extraction with EDTA to solubilize proteins anchored by divalent cation-dependent interactions. An antiserum raised against the purified protein labeled the apical cell surface of the epithelial cells in proximal tubules and the luminal surface of small intestine. Ten peptide sequences, derived from the protein, all matched the recently published sequences for rat (Moestrup, S. K., Kozyraki, R., Kristiansen, M., Kaysen, J. H., Holm Rasmussen, H., Brault, D., Pontillon, F., Goda, F. O., Christensen, E. I., Hammond, T. G., and Verroust, P. J. (1998) J. Biol. Chem. 273, 5235-5242) and human cubilin, a receptor for intrinsic factor-vitamin B12 complexes, identifying the protein as bovine cubilin. In electron microscopy, a three-armed structure was seen, indicating an oligomerization of three identical subunits. This model was supported by the Mr values of about 1,500,000 for the intact protein and 440,000 for its subunits obtained by analytical ultracentrifugation. In a search for a potential assembly domain, we identified a region of heptad repeats in the N-terminal part of the cubilin sequence. Computer-assisted analysis supported the presence of a coiled-coil alpha-helix between amino acids 103 and 132 of the human cubilin sequence and predicted the formation of a triple coiled-coil. We therefore conclude that cubilin forms a noncovalent trimer of identical subunits connected by an N-terminal coiled-coil alpha-helix.

Purification and Characterization of Monomeric Escherichia coli Vitamin B12 Receptor with High Affinity for Colicin E3

The btuB gene product from Escherichia coli is a 66.5-kDa integral outer membrane protein required for high-affinity uptake of cyanocobalamin and the translocation of E group colicins and colicin A. Efficient purification of overexpressed BtuB containing stoichiometric levels of bound lipopolysaccharide has been achieved through the extraction of the outer membrane with nonionic detergent followed by ion-exchange chromatography. Analysis of far UV circular dichroism spectra indicates a predominantly beta-sheet secondary structure (76 +/- 4%) with a low alpha-helical content (15 +/- 3%), providing the first direct evidence for secondary structure models derived from sequence and hydropathy analysis. Characterization of the octylglucoside-solubilized receptor by sedimentation equilibrium and sedimentation velocity analysis reveals a monodisperse protein-detergent complex of approximately 89 kDa with a sedimentation coefficient of 4.7 S which, after correction for bound detergent, indicates that BtuB is purified as a monomer. BtuB binds vitamin B12 with a stoichiometry of approximately 1:1, as observed by a shift in the sedimentation profile of the vitamin to the much faster velocity observed for the protein-detergent complex. The preincubation of colicin E3 with stoichiometric levels of BtuB protects susceptible strains from the lethal effects of the colicin and results in a complex with a sedimentation coefficient appropriate for a BtuB-detergent-colicin E3 complex, demonstrating that monomeric BtuB retains high affinity for this particular ligand after isolation.

The Intrinsic Factor-Vitamin B12 Receptor and Target of Teratogenic Antibodies Is a Megalin-binding Peripheral Membrane Protein with Homology to Developmental Proteins

The present report shows the molecular characterization of the rat 460-kDa epithelial glycoprotein that functions as the receptor facilitating uptake of intrinsic factor-vitamin B12 complexes in the intestine and kidney. The same receptor represents also the yolk sac target for teratogenic antibodies causing fetal malformations in rats. Determination of its primary structure by cDNA cloning identified a novel type of peripheral membrane receptor characterized by a cluster of eight epidermal growth factor type domains followed by a cluster of 27 CUB domains. In accordance with the absence of a hydrophobic segment, the receptor could be released from renal cortex membranes by nonenzymatic and nonsolubilizing procedures. The primary structure has no similarity to known endocytic receptors but displays homology to epidermal growth factor and CUB domain proteins involved in fetal development, e.g. the bone morphogenic proteins. Electron microscopic immunogold double labeling of rat yolk sac and renal proximal tubules demonstrated subcellular colocalization with the endocytic receptor megalin, which is expressed in the same epithelia as the 460-kDa receptor. Furthermore, megalin affinity chromatography and surface plasmon resonance analysis revealed a calcium-dependent high affinity binding of the 460-kDa receptor to megalin, which thereby may mediate its vesicular trafficking. Due to the high number of CUB domains, accounting for 88% of the protein mass, we propose the name cubilin for the novel receptor.

Neurogenic dysphagia: what is the cause when the cause is not obvious?

The potential causes of neurogenic oropharyngeal dysphagia in cases in which the underlying neurologic disorder is not readily apparent are discussed. The most common basis for unexplained neurogenic dysphagia may be cerebrovascular disease in the form of either confluent periventricular infarcts or small, discrete brainstem stroke, which may be invisible by magnetic resonance imaging. The diagnosis of occult stroke causing pharyngeal dysphagia should not be overlooked, because this diagnosis carries important treatment implications. Motor neuron disease producing bulbar palsy, pseudobulbar palsy, or a combination of the two can present as gradually progressive dysphagia and dysarthria with little if any limb involvement. Myopathies, especially polymyositis, and myasthenia gravis are potentially treatable disorders that must be considered. A variety of medications may cause or exacerbate neurogenic dysphagia. Psychiatric disorders can masquerade as swallowing apraxia. The basis for unexplained neurogenic dysphagia can best be elucidated by methodical evaluation including careful history, neurologic examination, videofluoroscopy of swallowing, blood studies (CBC, chemistry panel, creatine kinase, B12, thyroid screening, and anti-acetylcholine receptor antibodies), electromyography, and magnetic resonance imaging (MRI) of the brain, plus additional procedures such as lumbar puncture and muscle biopsy as indicated. Little is known about aging and neurogenic dysphagia, specifically the relative contributions of natural age-related changes in the oropharynx and of diseases of the elderly, including periventricular MRI abnormalities, in producing dysphagia symptoms and videofluoroscopic abnormalities in this population.

Elimination of the vitamin B12 uptake or synthesis pathway does not diminish the virulence of Escherichia coli K1 or Salmonella typhimurium in three model systems.

The role of iron in infection is of great importance and is well understood. During infection, both the host and the pathogen go through many complicated changes to regulate iron levels. Iron and vitamin B12 share certain features. For example, Escherichia coli has similar transport systems for both nutrients, and binding proteins for both are located in gastric juice, liver, saliva, granulocytes, and milk. It is because of such parallels between iron and B12 that we have explored the role of B12 in virulence. A btuB::Tn10 insertion which disrupts the gene encoding the vitamin B12 receptor from E. coli K-12 was P1 transduced into a virulent E. coli K1 strain. In both an infant-rat model and a chicken embryo model, no difference in virulence between the wild-type and the mutant strains was found. Strains of Salmonella typhimurium with mutations in the cobalamin synthesis pathway (Cob) and in btuB were used in a mouse model of virulence. Mutation of the Cob locus or of btuB does not decrease virulence. Interestingly, the inability to synthesize vitamin B12 actually increases virulence compared with the wild type in the S. typhimurium model. This effect is independent of the B12 intake of the mice.

Separate regulatory systems for the repression of metE and btuB by vitamin B12 in Escherichia coli.

Synthesis of the btuB-encoded outer membrane receptor for vitamin B12 and the metE-encoded homocysteine methyltransferase is repressed by growth of Escherichia coli in the presence of vitamin B12. The regulation by vitamin B12 of the production of beta-galactosidase in strains carrying btuB-lac or metE-lac operon fusions indicated that repression of both genes operates at the transcriptional level. Selection for expression of these fusions under repressive conditions allowed isolation of second-site mutations in which repressibility by vitamin B12 had been lost. Mutations in metH and metF prevented vitamin B12-dependent regulation of metE, but not that of btuB. Mutations in btuB and other genes involved in uptake of the vitamin eliminated or reduced repression. Mutations in the newly identified gene, btuR, controlled the repressibility of btuB, but had no effect on metE regulation. The btuR gene resides at 27.9 min on the genetic map in the gene order cysB-topA-btuR-trp; it acts in a trans-dominant manner and appears to encode a repressor of btuB transcription.

Regulation of expression of the gene for vitamin B12 receptor cloned on a multicopy plasmid in Escherichia coli.

The btuB gene of Escherichia coli codes for a protein (BtuB) located in the outer membrane. BtuB is the receptor for vitamin B12 (cyanocobalamin). We have cloned the btuB gene into pUC8 using transposon Tn5 as the marker to first isolate several parts of the relevant DNA fragment from the specialized transducing phage lambda darg13. After reconstitution of the gene, Tn5 was removed by selecting for spontaneous excision. The partial nucleotide sequence and transcriptional start of the btuB gene were determined. The BtuB+ plasmid allowed a large amplification of the synthesis of BtuB, resulting in a 65-fold increased level of vitamin B12 binding. The level of vitamin B12 binding was reduced by a factor of 22 when cells were grown in the presence of high concentrations of vitamin B12. The regulation of the gene was studied in more detail by the use of a protein fusion between the extreme amino-terminus of BtuB and beta-galactosidase of E. coli. The kinetics of repression and derepression were consistent with the presence in the cells of a large amount of a regulatory molecule exhibiting an apparent Km for vitamin B12 of 3 microM.

Transport of vitamin B12 in Escherichia coli: cloning of the btuCD region.

The transport of vitamin B12 in Escherichia coli requires a specific vitamin B12 receptor protein in the outer membrane and the tonB gene product. In addition, the btuC gene, located at min 38 on the genetic map, has been found to influence vitamin B12 uptake or utilization. The btuC function is required for the growth response to vitamin B12 when the outer membrane transport process (btuB or tonB function) is defective. However, even in a wild-type strain, btuC is required for proper transport of vitamin B12. Additional mutations in the vicinity of btuC were isolated as lac fusions that produced a phenotype similar to that of a btuC mutant. The btuC region was cloned by selection for complementation of a btuC mutation. Complementation testing with plasmids carrying various deletions or transposon Tn1000 insertions demonstrated that the new mutations defined a separate, independently expressed locus, termed btuD. The coding regions for both genes were identified on a 3.4-kilobase HindIII-HincII fragment and were 800 to 1,000 base pairs in length. They were separated by a 600- to 800-base-pair region. The gene order in this portion of the chromosome map was found to be pps-zdh-3::Tn10-btuD-btuC-pheS. Expression of beta-galactosidase in the btuD-lac fusion-bearing strains, whether proficient or defective in vitamin B12 transport, was not regulated by the presence of vitamin B12 in the growth medium.

Nucleotide sequence of the gene for the vitamin B12 receptor protein in the outer membrane of Escherichia coli.

The nucleotide sequence of a 2220-base-pair fragment containing the btuB gene of Escherichia coli was determined. There was a single open reading frame which was translated into a 614-amino-acid polypeptide, the first 20 amino acids of which comprised a typical leader sequence. The putative mature or processed form had a molecular weight (66,400) and a composition in close agreement with that determined for the purified receptor. The distribution of amino acids in the receptor protein was similar to that of other outer membrane proteins, showing a fairly even distribution of charged residues and the absence of extensive hydrophobic stretches. The btuB451 mutation appears to alter the receptor to eliminate its ability to function in vitamin B12 uptake without affecting its ligand binding properties. The sequence of the DNA from this mutant was determined and revealed a leucine-to-proline (C-to-T transition) change in the eighth amino acid of the mature form.

Cloning and expression of the gene for the vitamin B12 receptor protein in the outer membrane of Escherichia coli.

The transport of cyanocobalamin (vitamin B12) in cells of Escherichia coli is dependent on a receptor protein (BtuB protein) located in the outer membrane. A 9.1-kilobase pair BamHI fragment carrying the btuB gene was cloned from a specialized transducing phage into multicopy plasmids. Insertions of transposon Tn1000 which prevented production of the receptor localized btuB to a 2-kilobase pair region. Further subcloning allowed isolation of this region as a 2.3-kilobase pair Sau3A fragment. The BtuB+ plasmids were shown by maxicell analysis to encode a polypeptide with a molecular weight of 66,000 in the outer membrane. This polypeptide was missing in cells with Tn1000 insertions in btuB and was reduced in amount upon growth of plasmid-bearing cells in repressing concentrations of vitamin B12. Several Tn1000 insertions outside the 5' end of the coding region exhibited reduced production of receptor. A deletion at the 3' end of btuB resulted in formation of an altered receptor. Amplified production of this polypeptide was associated with increased levels of binding of the receptor's ligands (vitamin B12 and phage BF23), increased rates of vitamin B12 uptake, and altered susceptibility to the group E colicins. Deficiency in various major outer membrane proteins did not affect production of the btuB product, and the amplified levels of this protein partially reversed the tolerance to E colicins seen in these mutants.

Strain and temperature-dependent variation in the amount of BtuB polypeptide in theEscherichia coliK-12 outer membrane

The outer membrane protein BtuB of Escherichia coli K-12 is the receptor for vitamin B12; it is normally present in approx. 200 copies per cell. We describe here the conditions by which BtuB was readily observed in electropherograms of outer membrane preparations. These conditions are as follows. (1) Incorporation of 8 M urea in sodium dodecyl sulfate-polyacrylamide gel systems improved detection of the polypeptide. (2) In most E. coli K-12 strains examined, BtuB was most abundant when cells were grown at 27°C. This thermoregulation of BtuB was independent of envZ and envY, two regulatory genes for outer membrane proteins.

Outer membrane-dependent transport systems in Escherichia coli: effect of repression or cessation of colicin receptor synthesis on colicin receptor activities.

Proteins in the outer membrane of gram-negative bacteria serve as general porins or as receptors for specific nutrient transport systems. Many of these proteins are also used as receptors initiating the processes of colicin or phage binding and uptake. The functional activities of several outer membrane proteins in Escherichia coli K-12 were followed after cessation or repression of their synthesis. Cessation of receptor synthesis was accomplished with a thermolabile suppressor activity acting on amber mutations in btuB (encoding the receptor for vitamin B(12), the E colicins, and phage BF23) and in fepA (encoding the receptor for ferric enterochelin and colicins B and D). After cessation of receptor synthesis, cells rapidly became insensitive to the colicins using that receptor. Treatment with spectinomycin or rifampin blocked appearance of insensitive cells and even increased susceptibility to colicin E1. Insensitivity to phage BF23 appeared only after a lag of about one division time, and the receptors remained functional for B(12) uptake throughout. Therefore, possession of receptor is insufficient for colicin sensitivity, and some interaction of receptor with subsequent uptake components is indicated. Another example of physiological alteration of colicin sensitivity is the protection against many of the tonB-dependent colicins afforded by provision of iron-supplying siderophores. The rate of acquisition of this nonspecific protection was found to be consistent with the repression of receptor synthesis, rather than through direct and immediate effects on the tonB product or other components of colicin uptake or action.

9] Solubilization of the receptor for intrinsic factor—B12 complex from guinea pig intestinal mucosa

Publisher Summary This chapter discusses an overview of solubilization of the receptor for intrinsic factor-B 12 complex from guinea pig intestinal mucosa. The absorption of dietary vitamin B 12 from the intestine in many animal species requires the presence of intrinsic factor (IF), a glycoprotein secreted by the gastric mucosa. Normally, this protein is produced in large excess over actual requirements and is rarely a limiting factor in absorption. In vitro studies employing everted intestinal sacs, mucosal homogenates, and microvillous membranes prepared from the distal, but not the proximal, small bowel show uptake of IF-B 12 complex in the presence of a physiologic pH and calcium ions. The implication of this is that a receptor for IF-B 12 complex exists at the surface of the ileal cell. This chapter describes solubilization of guinea pig ileal mucosal homogenates employing the detergent Triton X-100. A particle-free solution was obtained that contained all the IF-B 12 receptors estimated to be present on the starting intestinal membranes. It is expected that better quantitation of IF- B12 receptor will help investigators to elucidate the mechanisms of B 12 absorption and malabsorption. The method employed for assaying and quantitating this solubilized receptor is also described in the chapter.

Proceedings of the Australian Society for Medical Research.

Proceedings of the Australian Society for Medical Research.

Effect of colchicine on guinea pig intrinsic factor-vitamin B12 receptor

Colchicine can induce the malabsorption of vitamin B12 and other nutrients. Previous investigations have suggested but not proved that this malabsorption was due to a lesion in the ileal mucosa. Employing the receptor assay of M. Katz and B. A. Cooper (J Clin Invest 54:733–739, 1974), the authors have observed a dose-related, reversible reduction in the quantity of intrinsic factor-vitamin B12 (IF-B12) receptor (from 5.78 ng to 1.3 ng of B12 binding) in the intestinal mucosa of guinea pigs fed 0.05–0.25 mg/100 g colchicine/day for 3 days. Malabsorption of vitamin B12 was also demonstrated in vivo in similarly treated animals. Increasing intestinal motility with cascara sagrada had no effect on the IF-B12 receptor. The quantity of IF-B12 receptor and the amount of vitamin B12 absorbed increased markedly to greater than normal levels during recovery from a 3-day course of colchicine. The total number of intestinal cells decreased after colchicine administration and increased during recovery; however, the fluctuations observed were not sufficient to explain the changes in the quantity of receptor. Histologic examination of the ileal mucosa showed a decrease in the population of villus cells after colchicine. The correlation between the changes in receptor quantity and in vivo B12-absorption prove that the IF-B12 receptor is a critical limiting factor in B12 absorption.

Repression of synthesis of the vitamin B12 receptor in Escherichia coli

Growth of Escherichia coli K-12 strains in the presence of the vitamin cyanocobalamin (B12) resulted in an 80 to 90% reduction in B12 uptake activity of washed cells. Coincident with the decline in uptake activity was the depression of B12-binding activity in energy-poisoned cells, suggesting that growth in B12 resulted in the repression of synthesis of the B12 receptor protein in the outer membrane. Growth in the presence of B12 led to marked reduction in sensitivity to the E colicins, whose adsorption to cells requires the B12 receptor, and to a decrease in the amount of a band on electropherograms of outer membrane proteins. That polypeptide was also missing from mutants altered at btuB, the locus encoding the B12 receptor. Addition of B12 to growing cultures resulted in the exponential decline in specific activity of B12 uptake, as expected for dilution of functional receptors by further growth. Repression of receptor synthesis appears to be regulated by the level of intracellular, rather than extracellular, B12 and is separate from the regulation of the methionine biosynthetic pathway. Mutants altered in btuC, which are defective in accumulation and retention of B12, exhibit a much lower degree of repressibility.

Genetic Analysis of Components Involved in Vitamin B 12 Uptake in Escherichia coli

The products of three genes are involved in cyanocobalamin (B(12)) uptake in Escherichia coli. btuB (formerly bfe), located at min 88 on the Escherichia coli linkage map, codes for a protein component of the outer membrane which serves as receptor for B(12), the E colicins, and bacteriophage BF23. Four phenotypic classes of mutants varying in response to these agents were found to carry mutations that, based on complementation and reversion analyses, reside in the single btuB cistron. In one mutant class, ligand binding to the receptor appeared to be normal, but subsequent B(12) uptake was defective. The level of receptor and rate of uptake were responsive to btuB gene dosage. Previous studies showed that the tonB product was necessary for energy-dependent B(12) uptake but not for its binding. Other than those in tonB, no mutations that conferred insensitivity to group B colicins affected B(12) utilization. The requirement for the btuB and tonB products could be bypassed by elevated levels of B(12) (>1 muM) or by mutations compromising the integrity of the outer membrane as a permeability barrier. Utilization of elevated B(12) concentrations in strains lacking the btuB-tonB uptake system was dependent on the function of the btuC product. This gene was located at 37.7 min on the linkage map, with the order pps-btuC-pheS. Strains altered in btuC but with an intact btuB-tonB system were only slightly impaired in B(12) utilization, being defective in its accumulation. This defect was manifested as inability to retain B(12), such that intracellular label was almost completely lost by exchange or efflux. It is proposed that btuC encodes a transport system for B(12) in the periplasm.