Identification of the Periplasmic Cobalamin-Binding Protein BtuF of Escherichia coli

Cells of Escherichia coli take up vitamin B(12) (cyano-cobalamin [CN-Cbl]) and iron chelates by use of sequential active transport processes. Transport of CN-Cbl across the outer membrane and its accumulation in the periplasm is mediated by the TonB-dependent transporter BtuB. Transport across the cytoplasmic membrane (CM) requires the BtuC and BtuD proteins, which are most related in sequence to the transmembrane and ATP-binding cassette proteins of periplasmic permeases for iron-siderophore transport. Unlike the genetic organization of most periplasmic permeases, a candidate gene for a periplasmic Cbl-binding protein is not linked to the btuCED operon. The open reading frame termed yadT in the E. coli genomic sequence is related in sequence to the periplasmic binding proteins for iron-siderophore complexes and was previously implicated in CN-Cbl uptake in SALMONELLA: The E. coli yadT product, renamed BtuF, is shown here to participate in CN-Cbl uptake. BtuF protein, expressed with a C-terminal His(6) tag, was shown to be translocated to the periplasm concomitant with removal of a signal sequence. CN-Cbl-binding assays using radiolabeled substrate or isothermal titration calorimetry showed that purified BtuF binds CN-Cbl with a binding constant of around 15 nM. A null mutation in btuF, but not in the flanking genes pfs and yadS, strongly decreased CN-Cbl utilization and transport into the cytoplasm. The growth response to CN-Cbl of the btuF mutant was much stronger than the slight impairment previously described for btuC, btuD, or btuF mutants. Hence, null mutations in btuC and btuD were constructed and revealed that the btuC mutant had a strong impairment similar to that of the btuF mutant, whereas the btuD defect was less pronounced. All mutants with defective transport across the CM gave rise to frequent suppressor variants which were able to respond at lower levels of CN-Cbl but were still defective in transport across the CM. These results finally establish the identity of the periplasmic binding protein for Cbl uptake, which is one of few cases where the components of a periplasmic permease are genetically separated.     

Mutual inhibition of cobalamin and siderophore uptake systems suggests their competition for TonB function.

Vitamin B12 (CN-Cbl) and iron-siderophore complexes are transported into Escherichia coli in two energy-dependent steps. The first step is mediated by substrate-specific outer membrane transport proteins and the energy-coupling TonB protein complex, and the second step uses separate periplasmic permeases for transport across the cytoplasmic membrane. Genetic and biochemical evidence suggests that the TonB-dependent outer membrane transporters contact TonB directly, and thus they might compete for limiting amounts of functional TonB. The transport of iron-siderophore complexes, such as ferrichrome, causes a partial decrease in the rate of CN-Cbl transport. Although CN-Cbl uptake does not inhibit ferrichrome uptake in wild-type cells, in which the amount of the outer membrane ferrichrome transporter FhuA far exceeds that of the cobalamin transporter BtuB, CN-Cbl does inhibit ferrichrome uptake when BtuB is overexpressed from a multicopy plasmid. This inhibition by CN-Cbl is increased when the expression of FhuA and TonB is repressed by growth with excess iron and is eliminated when BtuB synthesis is repressed by CN-Cbl. The mutual inhibition of CN-Cbl and ferrichrome uptake is overcome by increased expression of TonB. Additional evidence for interaction of the Cbl and iron transport systems is provided by the strong stimulation of the BtuB- and TonB-dependent transport of CN-Cbl into a nonexchangeable, presumably cytoplasmic pool by preincubation of cells with the iron(II) chelator 2,2'-dipyridyl. Other metal ion chelators inhibited CN-Cbl uptake across the outer membrane. Although the effects of chelators are multiple and complex, they indicate competition or interaction among TonB-dependent transport systems.     

Observations on the calcium dependence and reversibility of cobalamin transport across the outer membrane of Escherichia coli

The calcium dependence of cobalamin (Cbl) binding to the BtuB protein of Escherichia coli and the reversibility of its function in the transport of Cbl across the outer membrane have been examined. The results show that the two calcium-binding sites in BtuB that were identified previously by others are responsible for the calcium dependence of high affinity Cbl binding. The affinity of the pure BtuB protein for Cbl was approximately 1000-fold higher in the presence of saturating levels of calcium than in its absence. The affinities of BtuB for both Cbl and calcium were decreased by insertion of alanine residues at position 51 of the mature protein and were increased by several mutations and deletions in the TonB box. Experiments on the uptake of Cbl into the periplasmic space showed that this process is reversible and that the exit of Cbl back into the medium does not require the protonmotive force. Our interpretation of these results is that the role of the TonB-ExbB-ExbD complex, potentiated by the protonmotive force, is to reduce the affinity of the Cbl-binding site, thus increasing the rate of Cbl release into the periplasmic space. The evidence also indicates that access of the Cbl-binding site of BtuB to the periplasmic space does not require removal of the hatch domain from the barrel.     

Substrate-induced transmembrane signaling in the cobalamin transporter BtuB

The outer membranes of Gram-negative bacteria possess transport proteins essential for uptake of scarce nutrients. In TonB-dependent transporters, a conserved sequence of seven residues, the Ton box, faces the periplasm and interacts with the inner membrane TonB protein to energize an active transport cycle. A critical mechanistic step is the structural change in the Ton box of the transporter upon substrate binding; this essential transmembrane signaling event increases the affinity of the transporter for TonB and enables active transport to proceed. We have solved crystal structures of BtuB, the outer membrane cobalamin transporter from Escherichia coli, in the absence and presence of cyanocobalamin (vitamin B(12)). In these structures, the Ton box is ordered and undergoes a conformational change in the presence of bound substrate. Calcium has been implicated as a necessary factor for the high-affinity binding (K(d) approximately 0.3 nM) of cyanocobalamin to BtuB. We observe two bound calcium ions that order three extracellular loops of BtuB, thus providing a direct (and unusual) structural role for calcium.     

Transport-defective mutations alter the conformation of the energy-coupling motif of an outer membrane transporter.

The bacterial outer membrane transporter for vitamin B(12), BtuB, derives its energy for transport by interacting with the trans-periplasmic membrane protein TonB. This interaction with TonB occurs in part through an N-terminal segment in the BtuB sequence called the Ton box. In the present study, site-directed spin labeling of intact outer membrane preparations was used to investigate the conformation of the Ton box in wild-type BtuB and in two transport-defective mutants, L8P and V10P. In the wild-type protein, the Ton box is folded into the barrel of the transporter. The conformation of this segment is dramatically different in the transport-defective mutants L8P and V10P, where the Ton box is found to be flexible, and undocked from the transporter barrel with a greater exposure to the periplasm. In the wild-type protein, vitamin B(12) induces an undocking of the Ton box, but its addition to these transport defective mutants produces little or no change in the conformation of the Ton box. Proline substitutions at positions that do not alter transport do not alter the wild-type conformation of the Ton box; thus, the effect of substituting proline at positions 8 and 10 on the docked state of the Ton box appears to be unique. The failure of these mutants to execute the B(12) transport cycle may be a result of the altered conformation of the Ton box.     

Interdependence of calcium and cobalamin binding by wild-type and mutant BtuB protein in the outer membrane of Escherichia coli.

The binding of calcium and cobalamin to outer membranes from cells of Escherichia coli that contained amplified levels of wild-type or mutant btuB was studied. The mutant (BBam50) had an aspartyl-prolyl dipeptide inserted after the original 50th amino acid residue of the mature BtuB protein, which is within a region that shows extensive homology with the ferric siderophore receptors. This insertion resulted in cleavage of the BtuB in two places. The larger form retained the insertion but had lost 11 amino acid residues from the amino terminus. The smaller form was cut at the insertion site. Both the wild-type protein and the larger form of mutant BtuB showed calcium-dependent cobalamin binding with the same affinity for cobalamin, although the mutant had a much lower affinity for calcium. The smaller form of the mutant BtuB protein had a greatly reduced affinity for cobalamin, which was probably the result of inactivation of the cobalamin-dependent calcium-binding site. Cobalamin-dependent calcium binding was measured in wild-type BtuB preparations and was found to have the same corrinoid specificity and response to various corrinoid concentrations as shown previously for cobalamin binding. The results are consistent with a role for calcium in the cobalamin pump of the outer membrane of E. coli and show that a conserved part of the BtuB protein is required for the cobalamin-dependent binding of calcium.     

Mechanics of force propagation in TonB-dependent outer membrane transport

For the uptake of scarce yet essential organometallic compounds, outer membrane transporters of Gram-negative bacteria work in concert with an energy-generating inner membrane complex, thus spanning the periplasmic space to drive active transport. Here, we examine the interaction of TonB, an inner membrane protein, with an outer membrane transporter based upon a recent crystal structure of a TonB-transporter complex to characterize two largely unknown steps of the transport cycle: how energy is transmitted from TonB to the transporter and how energy transduction initiates transport. Simulations of TonB in complex with BtuB reveal that force applied to TonB is transmitted to BtuB without disruption of the very small connection between the two, supporting a mechanical mode of coupling. Based on the results of different pulling simulations, we propose that the force transduction instigates a partial unfolding of the pore-occluding luminal domain of the transporter, a potential step in the transport cycle. Furthermore, analysis of the electrostatic potentials and salt bridge interactions between the two proteins during the simulations hints at involvement of electrostatic forces in long-range interaction and binding of TonB and BtuB.     

Solutes alter the conformation of the ligand binding loops in outer membrane transporters

The binding and recognition of ligands by bacterial outer membrane transport proteins is mediated in part by interactions made through their extracellular loops. Here, site-directed spin labeling (SDSL) and electron paramagnetic resonance (EPR) spectroscopy were used to examine the effect of stabilizing solutes on the extracellular loops in BtuB, the vitamin B12 transporter, and FecA, the ferric citrate transporter. EPR spectra from the extracellular loops of FecA and BtuB arise from dynamic backbone segments, and distance measurements made by double electron-electron resonance indicate that the second extracellular loop in BtuB samples a wide range of conformations. These conformations are dramatically restricted upon substrate binding. In addition, the EPR spectra from nitroxide labels attached to the extracellular loops in BtuB and FecA are highly sensitive to solutes, and at every site examined the motion of the label is significantly reduced in the presence of stabilizing osmolytes, such as polyethylene glycols. For the second extracellular loop in BtuB, the solute-induced structural changes are small, but they are sufficient to bring spin-labeled side chains into tertiary contact with other portions of the protein. The spectroscopic changes seen by SDSL suggest that high concentrations of stabilizing solutes, such as those used to generate membrane protein crystals, result in a more compact and ordered state of the protein than is seen under more physiological conditions.     

Enzymatic E-colicins bind to their target receptor BtuB by presentation of a small binding epitope on a coiled-coil scaffold

Toxins and viruses often initiate their attacks by binding to specific proteins on the surfaces of target cells. Bacterial toxins (e.g. bacteriocins) and viruses (bacteriophages) targeting Gram-negative bacteria typically bind to outer membrane proteins. Bacterial E-colicins target Escherichia coli by binding to the outer membrane cobalamin transporter BtuB. Colicins are tripartite molecules possessing receptor-binding, translocation, and toxin domains connected by long coiled-coil alpha-helices. Surprisingly, the crystal structure of colicin E3 does not possess a recognizable globular fold in its receptor-binding domain. We hypothesized that the binding epitope of enzymatic E-colicins is a short loop connecting the two alpha-helices that comprise the coiled-coil region and that this flanking coiled-coil region serves to present the loop in a binding-capable conformation. To test this hypothesis, we designed and synthesized a 34-residue peptide (E-peptide-1) corresponding to residues Ala366-Arg399 of the helix-loop-helix region of colicin E3. Cysteines placed near the ends of the peptide (I372C and A393C) enabled crosslinking for reduction of conformational entropy and formation of a peptide structure that would present the loop epitope. A fluorescent analog was also made for characterization of binding by measurement of fluorescence polarization. Our analysis shows the following. (i). E-peptide-1 is predominantly random coil in aqueous solution, but disulfide bond formation increases its alpha-helical content in both aqueous buffer and solvents that promote helix formation. (ii). Fluorescein-labeled E-peptide-1 binds to purified BtuB in a calcium-dependent manner with a Kd of 43.6 +/- 4.9 nm or 2370 +/- 670 nm in the presence or absence of calcium, respectively. (iii). In the presence of calcium, cyanocobalamin (CN-Cbl) displaces E-peptide-1 with a nanomolar inhibition constant (Ki = 78.9 +/- 5.6 nm). We conclude that the BtuB binding sites for cobalamins and enzymatic E-colicins are overlapping but inequivalent and that the distal loop and (possibly) the short alpha-helical flanking regions are sufficient for high affinity binding.     

Multiple extracellular loops contribute to substrate binding and transport by the Escherichia coli cobalamin transporter BtuB

The Escherichia coli outer membrane TonB-dependent transporters for iron complexes and cobalamins recognize their multiple and diverse substrates with high specificity and affinity. The X-ray crystallographic structures of several transporters show that the substrate-binding surfaces are comprised of residues from the internal globular domain and multiple extracellular loops. The extracellular loops on the N-terminal half of the transmembrane beta-barrel of the cobalamin transporter BtuB participate in binding of the cofactor calcium atoms and undergo substantial conformation changes upon substrate binding. The functional relevance of the five C-terminal loops was examined by examining the effects of short in-frame deletions. Each loop contributed in different ways to the binding of BtuB substrates. Deletions in loops 7, 8, 9, and 11 strongly decreased cobalamin binding and transport, whereas deletions in loops 8, 9, and 10 affected binding and entry of phage BF23. None of the loops were essential for the action of colicin E1 or E3, which is consistent with the crystallographic observation that the colicin E3 receptor-binding domain can contact almost all of the loops. A deletion in loop 9 or 11 eliminated the ability of cobalamin to inhibit the action of colicin E1. These phenotypes show that there are multiple independent binding elements and point out similarities and differences in binding properties among the TonB-dependent transporters.     

Substrate-dependent unfolding of the energy coupling motif of a membrane transport protein determined by double electron-electron resonance

BtuB is a TonB-dependent transport protein that binds and carries vitamin B(12) across the outer membrane of Gram negative bacteria such as Escherichia coli. Previous work has demonstrated that the Ton box, a highly conserved segment near the N-terminus of the protein, undergoes an order-to-disorder transition upon the binding of substrate. Here, we incorporate pairs of nitroxide spin labels into membrane reconstituted BtuB and utilize a four-pulse double electron-electron resonance (DEER) experiment to measure distances between the Ton box and the periplasmic surface of the transporter with and without substrate. During reconstitution, the labeled membrane protein was diluted with wild-type protein, which significantly reduced the intermolecular electron spin-spin relaxation rate and increased the DEER signal-to-noise ratio. In the absence of substrate, each spin pair gives rise to a single distribution of distances that is consistent with the crystal structure obtained for BtuB; however, distances that are much longer are found in the presence of substrate, and the data are consistent with the existence of an equilibrium between folded and unfolded states of the Ton box. From these distances, a model for the position of the Ton box was constructed, and it indicates that the N-terminal end of the Ton box extends approximately 20 to 30 A into the periplasm upon the addition of substrate. We propose that this substrate-induced extension provides the signal that initiates interactions between BtuB and the inner membrane protein TonB.     

A requirement for calcium in the transport of cobalamin across the outer membrane of Escherichia coli

Cobalamin (Cbl) transport across the outer membrane of cells of Escherichia coli consists of high affinity Cbl binding to the btuB protein of the Cbl receptor, followed by the proton motive force- and tonB-dependent release of the Cbl into the periplasmic space. During a search for experimental conditions that would mimic this release in vitro with isolated cell envelope particles, we found that calcium was required for the high affinity Cbl binding, and subsaturating calcium concentrations resulted in the decreased affinity of the Cbl receptor for Cbl. The apparent affinity of the Cbl receptor for calcium (KD, approximately 30 nM at pH 6.6) decreased with decreasing pH, resulting in decreased affinity for Cbl at lower pH values. With suboptimal levels of calcium, Cbl binding was decreased by millimolar levels of magnesium.     

The effect of calcium on the conformation of cobalamin transporter BtuB

BtuB is a β‐barrel membrane protein that facilitates transport of cobalamin (vitamin B12) from the extracellular medium across the outer membrane of Escherichia coli. It is thought that binding of B12 to BtuB alters the conformation of its periplasm‐exposed N‐terminal residues (the TonB box), which enables subsequent binding of a TonB protein and leads to eventual uptake of B12 into the cytoplasm. Structural studies determined the location of the B12 binding site at the top of the BtuB's β‐barrel, surrounded by extracellular loops. However, the structure of the loops was found to depend on the method used to obtain the protein crystals, which—among other factors—differed in calcium concentration. Experimentally, calcium concentration was found to modulate the binding of the B12 substrate to BtuB. In this study, we investigate the effect of calcium ions on the conformation of the extracellular loops of BtuB and their possible role in B12 binding. Using all‐atom molecular dynamics, we simulate conformational fluctuations of several X‐ray structures of BtuB in the presence and absence of calcium ions. These simulations demonstrate that calcium ions can stabilize the conformation of loops 3–4, 5–6, and 15–16, and thereby prevent occlusion of the binding site. Furthermore, binding of calcium ions to extracellular loops of BtuB was found to enhance correlated motions in the BtuB structure, which is expected to promote signal transduction. Finally, we characterize conformation dynamics of the TonB box in different X‐ray structures and find an interesting correlation between the stability of the TonB box structure and calcium binding. Proteins 2010. © 2009 Wiley‐Liss, Inc.     

The structure of BtuB with bound colicin E3 R-domain implies a translocon

Cellular import of colicin E3 is initiated by the Escherichia coli outer membrane cobalamin transporter, BtuB. The 135-residue 100-A coiled-coil receptor-binding domain (R135) of colicin E3 forms a 1:1 complex with BtuB whose structure at a resolution of 2.75 A is reported. Binding of R135 to the BtuB extracellular surface (DeltaG(o) = -12 kcal mol(-1)) is mediated by 27 residues of R135 near the coiled-coil apex. Formation of the R135-BtuB complex results in unfolding of R135 N- and C-terminal ends, inferred to be important for unfolding of the colicin T-domain. Small conformational changes occur in the BtuB cork and barrel domains but are insufficient to form a translocation channel. The absence of a channel and the peripheral binding of R135 imply that BtuB serves to bind the colicin, and that the coiled-coil delivers the colicin to a neighboring outer membrane protein for translocation, thus forming a colicin translocon. The translocator was concluded to be OmpF from the occlusion of OmpF channels by colicin E3.     

Cobalamin (vitamin B12) binding, phylogeny, and synteny of human transcobalamin

Selected residues in a highly conserved 15-residue region, 174SVDTAAMAGLAFTC L188 of human transcobalamin (TC), a cobalamin (Cbl: vitamin B12) binding protein, were subjected to site-directed mutagenesis. The mutant constructs were expressed in TC-deficient fibroblasts or in vitro to assess the effect of these mutations on Cbl binding. Phylogenetic analyses and protein parsimony indicated that TC evolved earlier than other mammalian Cbl-binding proteins, intrinsic factor and haptocorrins, and divergence occurred between mouse/rat and human dispersing TC gene to different chromosomes. These studies show that (a) two of the three polar residues, S174, T177, or D176 and two of the three conserved alanine residues, A179 and A184 present in the 15-residue evolutionary conserved region are essential for Cbl-binding by human TC, and (b) TC gene is transferred in a syntenic manner to different chromosomes, at least before the divergence of mouse/rat and human.     

APS facilitates c-Cbl tyrosine phosphorylation and GLUT4 translocation in response to insulin in 3T3-L1 adipocytes

APS is a Cbl-binding protein that is tyrosine phosphorylated by the insulin receptor kinase. Insulin-stimulated phosphorylation of tyrosine 618 in APS is necessary for its association with c-Cbl and the subsequent tyrosine phosphorylation of Cbl by the insulin receptor in both 3T3-L1 adipocytes and CHO-IR cells. When overexpressed in these cells, wild-type APS but not an APS/Y(618)F mutant facilitated the tyrosine phosphorylation of coexpressed Cbl and its association with Crk upon insulin stimulation. APS-facilitated phosphorylation occurred on tyrosines 371, 700, and 774 in the Cbl protein. APS also interacted directly with the c-Cbl-associated protein (CAP) and colocalized with the protein in cells. The association was dependent on the SH3 domains of CAP and was independent of insulin treatment. Overexpression of the APS/Y(618)F mutant in 3T3-L1 adipocytes blocked the insulin-stimulated tyrosine phosphorylation of endogenous Cbl and binding to Crk. Moreover, the translocation of GLUT4 from intracellular vesicles to the plasma membrane was also inhibited by overexpression of the APS/Y(618)F mutant. These data suggest that APS serves as an adapter protein linking the CAP/Cbl pathway to the insulin receptor and, further, that APS-facilitated Cbl tyrosine phosphorylation catalyzed by the insulin receptor is a crucial event in the stimulation of glucose transport by insulin.     

Sequences of the Escherichia coli BtuB protein essential for its insertion and function in the outer membrane.

The Escherichia coli btuB gene encodes the outer membrane transporter for vitamin B12, the E colicins, colicin A, and bacteriophage BF23. Several series of mutant forms of BtuB resulting from the insertion of dipeptide sequences and from overlapping in-frame deletions and duplications were constructed. Strains expressing the variant genes in single and multiple copy numbers were analyzed for BtuB function, for the level of BtuB polypeptide in the outer membrane, and for changes in the outer membrane permeability barrier. Most dipeptide insertions had normal transport function and assembly in the membrane. Only 2 of the 27 deletions spanning residues 5 and 514 possessed transport function, and most of the remainder were not stably inserted in the membrane. Most duplications (19 of 21) retained transport function and were inserted in the outer membrane, although some were subject to proteolysis. Even long duplications containing as many as 340 repeated amino-terminal residues retained function, suggesting considerable plasticity in the sequence requirements for membrane insertion of BtuB. Expression of many deletion and duplication proteins conferred increased susceptibility to structurally unrelated inhibitors that are normally excluded by the outer membrane. These results could be consistent with the mutational disruption of extracellular loops or transmembrane segments of BtuB that constitute a gated channel, but the finding that alterations throughout the length of BtuB affect membrane permeability properties suggests that the altered proteins might perturb the outer membrane structure itself.     

Sequence changes in the ton box region of BtuB affect its transport activities and interaction with TonB protein

Uptake of cobalamins by the transporter protein BtuB in the outer membrane of Escherichia coli requires the proton motive force and the transperiplasmic protein TonB. The Ton box sequence near the amino terminus of BtuB is conserved among all TonB-dependent transporters and is the only known site of mutations that confer a transport-defective phenotype which can be suppressed by certain substitutions at residue 160 in TonB. The crystallographic structures of the TonB-dependent transporter FhuA revealed that the region near the Ton box, which itself was not resolved, is exposed to the periplasmic space and undergoes an extensive shift in position upon binding of substrate. Site-directed disulfide bonding in intact cells has been used to show that the Ton box of BtuB and residues around position 160 of TonB approach each other in a highly oriented and specific manner to form BtuB-TonB heterodimers that are stimulated by the presence of transport substrate. Here, replacement of Ton box residues with proline or cysteine revealed that residue side chain recognition is not important for function, although replacement with proline at four of the seven Ton box positions impaired cobalamin transport. The defect in cobalamin utilization resulting from the L8P substitution was suppressed by cysteine substitutions in adjacent residues in BtuB or in TonB. This suppression did not restore active transport of cobalamins but may allow each transporter to function at most once. The uncoupled proline substitutions in BtuB markedly affected the pattern of disulfide bonding to TonB, both increasing the extent of cross-linking and shifting the pairs of residues that can be joined. Cross-linking of BtuB and TonB in the presence of the BtuB V10P substitution became independent of the presence of substrate, indicating an additional distortion of the exposure of the Ton box in the periplasmic space. TonB action thus requires a specific orientation for functional contact with the Ton box, and changes in the conformation of this region block transport by preventing substrate release and repeated transport cycles.     

Mechanism of conversion of human apo- to holomethionine synthase by various forms of cobalamin.

Methionine synthase catalyzes the conversion of N5-methyltetrahydrofolate and homocysteine to tetrahydrofolate and methionine. Methylcobalamin (Me-Cbl) is tightly bound to methionine synthase and is required for enzymatic activity. When added to crude tissue homogenates, Me-Cbl stimulates methionine synthase but similar stimulation is observed with hydroxocobalamin, cyanocobalamin (CN-Cbl), and adenosyl-Cbl, although the mechanisms involved are unknown. We prepared human apomethionine synthase and studied its activation in the presence of [14C]CN-Cbl and [14CH3]Me-Cbl with concentrations of 2-mercaptoethanol ranging from 0.15 to 100 mM. We observed that the removal of the labeled upper axial ligands from CN-Cbl and Me-Cbl both paralleled the activation of human apomethionine synthase. Spectral studies employing CN-Cbl and Me-Cbl showed that both forms of Cbl must be converted to Cob(II)alamin before they can bind to human apomethionine synthase and convert it to its activated holoenzyme form. Studies with 14 different Cbl analogues with alterations in various portions of the corrin ring and the nucleotide showed that all of the analogues were able to fully activate human methionine synthase when they were reduced with 2-mercaptoethanol. Full activation occurred at lower concentrations of many of the Cbl analogues than occurred with Cbl itself. We conclude that Me-Cbl and other forms of Cob(III)alamin do not bind to human apomethionine synthase and that all must first be reduced to Cob(II)alamin before such binding can occur. The fact that human methionine synthase shows little absolute specificity for alterations in various portions of the Cbl molecule suggests that the potent inhibition of mammalian methionine synthase activity observed in vivo with various Cbl analogues is due to inhibition of intracellular Cbl transport or to inhibition of the enzymatic formation of Cob(II)alamin rather than to direct inhibition of mammalian methionine synthase itself.