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Reactivation of methionine synthase from Thermotoga maritima (TM0268) requires the downstream gene product TM0269

¹ Life Sciences Institute, University of Michigan, Ann Arbor, Michigan 48109, USA
² Biophysics Research Division, University of Michigan, Ann Arbor, Michigan 48109, USA
³ Department of Biological Chemistry, University of Michigan, Ann Arbor, Michigan 48109, USA
⁴ Joint Center for Structural Genomics, The Scripps Research Institute, La Jolla, California 92037, USA

(RECEIVED April 9, 2007; FINAL REVISION May 23, 2007; ACCEPTED May 23, 2007)

	Abstract

TOP Abstract Introduction Results Discussion Materials and Methods Acknowledgments References

 
The crystal structure of the Thermotoga maritima gene product TM0269, determined as part of genome-wide structural coverage of T. maritima by the Joint Center for Structural Genomics, revealed structural homology with the fourth module of the cobalamin-dependent methionine synthase (MetH) from Escherichia coli, despite the lack of significant sequence homology. The gene specifying TM0269 lies in close proximity to another gene, TM0268, which shows sequence homology with the first three modules of E. coli MetH. The fourth module of E. coli MetH is required for reductive remethylation of the cob(II)alamin form of the cofactor and binds the methyl donor for this reactivation, S-adenosylmethionine (AdoMet). Measurements of the rates of methionine formation in the presence and absence of TM0269 and AdoMet demonstrate that both TM0269 and AdoMet are required for reactivation of the inactive cob(II)alamin form of TM0268. These activity measurements confirm the structure-based assignment of the function of the TM0269 gene product. In the presence of TM0269, AdoMet, and reductants, the measured activity of T. maritima MetH is maximal near 80°C, where the specific activity of the purified protein is 15% of that of E. coli methionine synthase (MetH) at 37°C. Comparisons of the structures and sequences of TM0269 and the reactivation domain of E. coli MetH suggest that AdoMet may be bound somewhat differently by the homologous proteins. However, the conformation of a hairpin that is critical for cobalamin binding in E. coli MetH, which constitutes an essential structural element, is retained in the T. maritima reactivation protein despite striking divergence of the sequences.

Keywords: structural genomics; adenosylmethionine; cobalamin; structure and function

	Introduction

TOP Abstract Introduction Results Discussion Materials and Methods Acknowledgments References

 
Methionine synthases catalyze the formation of methionine from homocysteine (Hcy) and methyltetrahydrofolate (CH₃-H₄folate). Two families of methionine synthases are known: the B₁₂-dependent enzymes that use the cobalamin cofactor as an intermediate methyl carrier (Scheme 1), and the B₁₂-independent enzymes that catalyze direct methyl transfer from CH₃-H₄folate to Hcy. The best characterized B₁₂-dependent methionine synthase (MetH) is from Escherichia coli, which comprises four structural and functional modules (Banerjee et al. 1989; Drummond et al. 1993; Goulding et al. 1997; Ludwig and Matthews 1997; Matthews 1999). The two N-terminal modules bind the substrates Hcy and CH₃-H₄folate, respectively (Goulding et al. 1997) and the third module carries the essential B₁₂ prosthetic group (Banerjee et al. 1989). The C-terminal module binds AdoMet and is required for the reductive reactivation reaction that rescues the enzyme from its inactive cob(II)alamin form (Scheme 1; Drummond et al. 1993; Jarrett et al. 1998). This four-module arrangement is prevalent in nature.

View larger version (25K): [in this window] [in a new window]   Scheme 1. The catalytic cycle of MetH (red) and the reactions that deactivate and reactivate the enzyme from E. coli (green). In methionine synthesis, cobalamin serves as an intermediate methyl carrier, receiving a methyl group from CH3-H4folate and, in turn, donating the group to Hcy. Inactivation by reaction with oxygen generates the cob(II)alamin form, which must be reduced and then remethylated by AdoMet in order to return to the catalytic cycle.

Formation of the inactive cob(II)alamin form of MetH and its conversion to the active methylcobalamin species have previously been examined in detail with E. coli MetH. Inactivation results from reaction with oxygen of the cob(I)alamin species that is formed upon methylation of Hcy and occurs about once in every 2000 turnovers (Drummond et al. 1993). Reactivation proceeds via intermediate formation of cob(I)alamin, which is generated by electron transfer from flavodoxin (Jarrett et al. 1998). The cob(I)alamin form is then remethylated by AdoMet in a step that requires the C-terminal activation domain (Drummond et al. 1993). Reduction to cob(I)alamin is thermodynamically disfavored, but the overall reaction is driven by the favorable free energy of methyl transfer from AdoMet (Banerjee et al. 1990). For in vitro assays of reactivation, the physiological reducing system, NADPH, ferredoxin(flavodoxin)-NADP⁺ oxidoreductase, and flavodoxin, can be replaced by dithiothreitol as a source of reducing equivalents and by hydroxocobalamin as a catalyst (Taylor and Weissbach 1967; Jarrett et al. 1997). The inactive cob(II)alamin enzyme can also be reduced in an electrochemical cell and remethylated by AdoMet in the presence of a functional reactivation module (Jarrett et al. 1997). Sequences coding for flavodoxin are not found in the T. maritima genome; the alternative physiological reductant of cob(II)alamin MetH in this organism has yet not been identified. Our studies of the reactivation of T. maritima MetH have, therefore, used these chemical and electrochemical reducing systems.

	Results

TOP Abstract Introduction Results Discussion Materials and Methods Acknowledgments References

 
TM0268 is expressed as a cobalamin-free apo-protein that can be reconstituted to an active species by addition of cobalamin
Histidine-tagged versions of the TM0268 and TM0269 proteins have been expressed singly and together in E. coli and have been purified from cell lysates by heat treatment and subsequent separation using Zn-NTA chromatography. Exploration of expression in a variety of hosts and media failed to elicit conditions that would support incorporation of cobalamin during growth of the host cells. However, we were successful in reconstituting the purified TM0268 apo-protein by incubation with methylcobalamin at 60°C.

The visible spectrum confirms that the reconstituted protein remains in the methylcobalamin form (Fig. 1). Measurements of methylcobalamin content based on absorbance at 536 nm, combined with determination of the protein concentration using 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) titration, indicate a 1:1 stoichiometry of protein and cobalamin. This form of the protein can be stored at –80°C for prolonged periods without loss of activity or spectral alterations. As described below, the reconstituted protein catalyzes the synthesis of methionine from Hcy in the presence of TM0269 and AdoMet.

View larger version (18K): [in this window] [in a new window]   Figure 1. (Solid line) The visible absorbance spectrum of TM0268 reconstituted with methylcobalamin. (Dashed line) For comparison, the spectrum of E. coli MetH in the methylcobalamin form.

Maximum activity of Tm MetH (TM0268) was observed at 80°C with a turnover number 15% that of the E. coli enzyme at 37°C

The maximum formation of product observed after 2 min occurs between 75°C and 80°C, where the specific activity is 3 µmol/min/mg (Fig. 2). For comparison, the specific activity of the E. coli enzyme at 37°C in the presence of the complete reactivation system is 15 µmol/min/mg, corresponding to a turnover number of 34 sec^–1. Adjusting for the relative molecular weights, the maximum observed activity of the T. maritima enzyme is 5 turnovers/sec, or 15% that of the E. coli enzyme. The optimum growth temperature for T. maritima is reported to be 80°C (Daniel and Danson 2001). The decrease in activity at higher temperatures may result not only from instability of the enzyme but also from destruction of the folate substrate at temperatures >80°C (Indrawati et al. 2005).

View larger version (24K): [in this window] [in a new window]   Figure 2. Specific activity of T. maritima methionine synthase as a function of temperature. Assay mixtures included Hcy (saturating), AdoMet, the chemical reducing system, and 1:1 mixtures of TM0268 and TM0269. After temperature equilibration for 2 min, turnover was initiated by addition of CH3-H4folate. The amount of product formed was measured in samples quenched at 2 min. (See Materials and Methods for additional details.)

View larger version (11K): [in this window] [in a new window]   Figure 3. Reactivation of activity of TM0268 requires TM0269 and AdoMet. TM0268 in the cob(II)alamin form was generated by reaction of the methylcobalamin form with homocysteine under aerobic conditions at 64°C. Assays were performed with 9.2 nM TM0268 in the presence of (•) equimolar TM0269 and 19 µM AdoMet; () AdoMet only; () TM0269 only; or () neither.

View larger version (16K): [in this window] [in a new window]   Figure 4. Electrochemical methylation of TM0268 in the cob(II)alamin form requires TM0269. TM0268 in the cob(III)alamin form was generated by aerobic photolysis (Jarrett et al. 1996) and then incubated under argon in the presence of 1 mM AdoMet and 500 µM methylviologen at –0.450 V versus standard hydrogen electrode for 45 min at 25°C in the presence or absence of TM0269. Following incubation, the proteins were subjected to gel filtration to remove AdoMet and methylviologen, and the spectra were recorded. (Blue line) The absorbance of the hydroxycob(III)alamin form of TM0268 before electrochemical methylation; (black line) the TM0268 absorbance in the cob(II)alamin form after incubation in the absence of TM0269; (red line) the absorbance observed after incubation in the presence of equimolar TM0269. The black line indicates that incubation in the absence of TM0269 results in the formation of cob(II)alamin, which is characterized by an absorbance peak at 477 nm. The red line indicates that TM0268 is converted to methylcobalamin in the presence of TM0269 and AdoMet.

	Discussion

TOP Abstract Introduction Results Discussion Materials and Methods Acknowledgments References

 
The experiments reported here have documented functional similarities in the reactivation systems of the disparate E. coli and T. maritima MetH species, and the availability of the structures of both modules allows a detailed comparison. Although the structure of TM0269, deposited in the Protein Data Bank (1J6R [PDB] ), did not contain bound AdoMet, our functional studies and the conservation of the AdoMet-binding region in both structures allows identification of the AdoMet-binding site in TM0269.

Although the reactivation module of the E. coli enzyme reacts in cis, we have shown that the corresponding module of the T. maritima enzyme is actually a separate protein, TM0269, that reacts in trans. It is intriguing that the two-protein reactivation system from T. maritima functions adequately in trans, whereas it has not been possible to reactivate E. coli MetH when the activation domain has been cleaved from the catalytic domains by specific tryptic digestion (Drummond et al. 1993). Preliminary experiments suggest that the TM0268 and TM0269 proteins do not form tight aggregates; the proteins are readily separated from one another on a MonoQ anion exchange column or on sizing columns.

In attempts to induce incorporation of the cobalamin cofactor during expression of TM0268 in E. coli hosts, we co-transfected cells with plasmids bearing coding sequences for both TM0268 and TM0269. This tactic failed to increase significantly the yield of soluble TM0268 or the incorporation of cobalamin, implying that TM0269 does not exert any chaperone-like effects on TM0268. For human MetH, Yamada and coworkers (Yamada et al. 2006) have recently shown that cofactor incorporation can be enhanced significantly by coexpression with methionine synthase reductase, a large protein bearing a flavodoxin-like domain that serves as electron donor for reactivation of inactive cob(II)alamin MetH. The physiological reductase for Tm MetH might play a similar role, but, as already noted, it remains to be identified.

Structural similarities and differences between TM0269 and the reactivation domain of MetH from E. coli have been analyzed by comparing the structural models (Fig. 5). The lengths and sequences of the two functional modules are very different. The Tm protein is only 197 residues in length, compared with the 327 residues that comprise the reactivation domain of E. coli MetH. Sequence identities between residues aligned on the basis of their positions in the structures are also surprisingly low, being only 15% identical. However, conserved conformations in central regions of the structure can account for the similar functional properties of the two proteins. A highly conserved core region includes the fourth strand of the major central sheet (8 in the E. coli sequence) (Fig. 5A) and the very long 6-helix that carries some of the AdoMet binding determinants, as defined for the E. coli domain (Dixon et al. 1996). Also closely reproduced in both structures is a proline-rich "hook," 1134–1140 in the E. coli sequence, and a hairpin formed by residues 1163–1173 of E. coli MetH and 175–186 of TM0269. The hook forms a highly conserved part of the binding site for the adenine moiety of AdoMet. Sequences of the hairpin are not well conserved, but the hairpin conformations are remarkably similar despite the insertion of one residue in the T. maritima structure. In the E. coli reactivation complex (Bandarian et al. 2002), this hairpin contacts the cobalamin-binding domain and pries the corrin ring away from His759. Dissociation of the His ligand from the cobalt of cobalamin presumably facilitates reduction of cob(II)alamin. Structural similarities in the hairpin of TM0269 imply that association of the cobalamin domain of TM0268 with TM0269 likewise perturbs cobalt ligation in TM0268.

View larger version (36K): [in this window] [in a new window]   Figure 5. (A) The structure of TM0269 (1J6R, yellow) is superimposed on the structure of the C-terminal domain of MetH from E. coli (1MSK, blue) (Dixon et al. 1996), with bound AdoMet displayed in ball-and-stick mode (1MSK). Residues used to match the structures are from a structurally conserved core that includes the E. coli helices 5 and 6 and strands 2, 5, and 8 shown in the sequence alignment C. The hairpin that positions cobalamin in the structure of the reactivation complex from E. coli (1163–1173) is above and to the right of the adenine ring in this view. (B) Close-up view of the binding site for AdoMet in TM0269. (C) Structure-based sequence alignment of TM0269 and the activation domain of E. coli MetH. Similar structural elements that overlay each other or show small displacements in A are blue, and identities are highlighted. Italicized sections of the T. maritima sequence are structurally dissimilar to the E. coli structure and demonstrate the shortened loops of the thermophile.

Structural comparisons also indicate differences in the AdoMet-binding determinants used by TM0269 and the reactivation domain of E. coli MetH. It is evident (Fig. 5A,C) that apart from the long helix, the polypeptide backbones are arranged differently in the vicinity of the Met moiety. No residue in TM0268 is equivalent to Asp946, which binds the amino group of AdoMet. Arg131, from a different segment of the structure, occupies a position that corresponds approximately to Asp946. Glu124 "replaces" the Arg1094 that binds the carboxyl group of AdoMet in the E. coli complex. These substitutions may, therefore, alter the orientation and conformation of bound AdoMet in its complex with TM0269, but possible conformations are restricted by the requirement to juxtapose the methyl group of AdoMet in an orientation suitable for transfer to cobalamin.

Long stretches of E. coli sequence are absent from TM0269 (Fig. 5C), primarily in the region shown at the bottom of the molecule in Figure 5A. In this region, the first 28 and last 43 residues of the E. coli sequence are missing, and the loops and strands comprising residues 1000–1050 in E. coli are contracted to 25 residues. Remaining deletions shorten the distal helices and remove some short helices (as shown in the upper left of Fig. 5A, 7 beginning at residue1125 in the E. coli sequence and the 3₁₀-helix between 3 and 4 beginning at residue 962). Decreasing the length of surface loops is one strategy used by thermophiles to enhance protein stability (Thompson and Eisenberg 1999). The major changes (at the bottom of the view in Fig. 5A) occur where the cobalamin-binding domain is attached in E. coli MetH, suggesting that these features may be important for orienting the (covalently linked) modules of E. coli MetH with respect to one another. We speculate that they contribute to domain interfaces in some members of the ensemble of conformations required for catalysis (Bandarian et al. 2003; Evans et al. 2004).

	Materials and Methods

TOP Abstract Introduction Results Discussion Materials and Methods Acknowledgments References

 
Vectors for TM0268 and TM0269
A pBad vector specifying TM0269 with a MGSDKIHHHHHH leader sequence was constructed at the Joint Center for Structural Genomics. The coding region corresponding to the full-length TM0268 protein (residues 1–768) was PCR-amplified from genomic DNA (a gift of James Bardwell, University of Michigan, Ann Arbor). DNA sequence analysis verified that the PCR product coded for the correct sequence. The PCR product was inserted into Pet29a to generate a C-terminal His6 fusion with an AAALV insertion.

Expression and purification of TM0268
Protein was overexpressed in transformed C41 cells grown in LB medium at 37°C. Expression levels were higher in this host strain than in BL21 (DE3) Gold cells, and the protein eluted from Zn-NTA columns was purer. At 0.6–0.7 OD₆₀₀, cultures were induced with 750 µM IPTG and allowed to grow for 8 h at 37°C. Cells were lysed by sonication. All buffers used for purification and dialysis contained 1 mM TCEP. The lysate was heated for 10 min at 70°C and then centrifuged at 96,000g for 75 min in a Beckman L-70 ultracentrifuge. The supernatant was passed through a 0.45-µm filter and loaded onto a Hi-Trap Zn-NTA column (Amersham) in 100 mM Tris buffer (pH 8.0) containing 500 mM NaCl. After washing the column with loading buffer, the tagged protein was eluted with 1.5 M glycine and dialyzed against 50 mM Tris (pH 8.0). The protein was concentrated with a 30K cutoff Amicon concentrator to 60 mg/mL (as determined by the DTNB assay) and was 100% zinc replete according to the zinc assay. Cobalamin content after reconstitution was determined from the visible spectrum (Fig. 1), as described below.

Expression of TM0269 and coexpression of both proteins
To optimize expression of soluble protein and to examine effects of coexpression on yields, the pBad and pET 29a vectors carrying TM0269 and TM0268 were transfected and cotransfected into several cell lines, including BL21 (DE3), BL21 Gold (DE3), and C41 (DE3), and Rosetta. Routinely, protein expression was induced with 750 µM IPTG (for TM0268) and/or 0.02% arabinose (for TM0269) in the BL21 (DE3) Gold cells.

Analyses of protein concentration, zinc content, and cobalamin content
Protein concentration was determined by titration with 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) in 6 M guanidinium hydrochloride buffered with 0.05 M Tris chloride (pH 8.0) as described (Bandarian and Matthews 2001). This procedure measures the three cysteines in TM0268 and has provided accurate estimates of MetH concentrations in our hands. The extinction coefficient at 412 nm for the thio-2-nitrobenzoate anion released on reaction with cysteine thiols was taken to be 13,600 M^–1· cm^–1. It was necessary to modify the published procedure (Bandarian and Matthews 2001) to correct for the absorbance of cobalamin at 412 nm. Zinc content was determined by titrating with 4-(2-pyridylazo)resorcinol in the presence of 4-hydroxymercuribenzoate (Aldrich) (Goulding and Matthews 1997) except that this compound was substituted for 4-hydroxymercuriphenylsulfonate, which is no longer available. Concentrations of bound methylcobalamin were determined from absorbance at 536 nm using an extinction coefficient of 8910 M^–1 ·cm^–1.

Reconstitution of holo-TM0268
In a typical reconstitution of apo-TM0268, a 200-µL aliquot of 0.3–0.5 mM apo-protein in a 1-mL microfuge tube was preheated for 2 min at 60°C in 50 mM Tris chloride buffer (pH 8). Following addition of a 10-fold excess of methylcobalamin, the sample was maintained for an additional 3 min at 60°C. Excess methylcobalamin was removed by eluting the protein from a Econo-pac 10DG Bio-gel P-6 column (Bio-Rad) equilibrated with 10 mM potassium phosphate buffer (pH 7.2). The protein was concentrated in the same buffer and stored at –80°C.

Conversion of methylated enzyme to the cob(II)alamin form
Reaction with Hcy to form methionine demethylates the methylcobalamin enzyme. Under aerobic conditions, the resulting cob(I)alamin enzyme is converted to the cob(II)alamin species. Conversion from methylcobalamin to the cob(II)alamin species can be observed spectrophotometrically by changes in absorbance at 536 nm (the absorbance maximum for the methylcobalamin of TM0268) or 477 nm [the absorbance maximum for the cob(II)alamin form].

Assays of methionine synthase activity
Activity was measured at selected time points by spectrophotometric determination of the methenyl-tetrahydrofolate derived from the product H₄folate by reaction with formic acid (Jarrett et al. 1997). Assay mixtures contained 100 mM potassium phosphate buffer (pH 7.2), 25 mM dithiothreitol, 0.019 mM AdoMet (where desired), 0.05 mM hydroxocobalamin, 0.5 mM Hcy, and 0.25 mM CH₃-H₄folate.

Two different assay protocols were used in these studies: (1) To determine temperature dependence of activity, mixtures containing the enzyme(s) and all components except the CH₃-H₄folate substrate were preincubated under aerobic conditions for 2 min at the desired temperature, and reactions were initiated by addition of CH₃-H₄folate, which was added last because of its lability at elevated temperatures (Indrawati et al. 2005). Use of this protocol allows deactivation (by reaction with Hcy) and reactivation (in the presence of AdoMet, TM0269, and the chemical reducing system) during temperature equilibration. (2) To follow rates of reaction and the dependence of rates on AdoMet and/or TM0269 at 64°C, all components of the assay except the protein(s) were combined, flushed with argon for 10 min, and brought to the desired assay temperature by incubation for 2 min. Enzyme(s) were added to initiate turnover.

Electrochemical methylation
TM0268 in the hydroxycob(III)alamin form was converted to the methylcobalamin form by reductive methylation in the presence of AdoMet, as previously described (Jarrett et al. 1996). The enzyme (50–200 µM in 0.1 M potassium phosphate buffer at pH 7.2, containing 0.2 M KCl) was mixed with AdoMet (1 mM) and methylviologen (500 µM) under argon in an electrochemical cell and poised at –450 mV versus the standard hydrogen electrode for 45 min at 25°C. After reaction, the protein was purified in the dark by gel filtration and then equilibrated with 10 mM potassium phosphate buffer (pH 7.2) and concentrated in a Centricon 30 Concentrator (Amicon).

	Footnotes

 
⁵ Deceased.

Reprint requests to: Rowena Matthews, 4002 Life Sciences Institute, University of Michigan, 210 Washtenaw Avenue, Ann Arbor, MI 48109-2216, USA; e-mail: rmatthew{at}umich.edu; fax: (734) 763-6492.

Abbreviations: AdoMet, S-adenosylmethionine; DTNB, 5,5'-dithiobis(2-nitrobenzoic acid); Hcy, homocysteine; CH₃-H₄folate, 5-methyltetrahydrofolate.

Article and publication are at http://www.proteinscience.org/cgi/doi/10.1110/ps.072936307.

	Acknowledgments

TOP Abstract Introduction Results Discussion Materials and Methods Acknowledgments References

 
This work has been funded in part by GM16429 (to M.L.), GM24908 (to R.M.), and P50-62411 and U54 GM074898 (to I.A.W., S.A.L., and the J.C.S.G.).

	References

TOP Abstract Introduction Results Discussion Materials and Methods Acknowledgments References

 
Bandarian, V. and Matthews, R.G. 2001. Quantitation of rate enhancements attained by the binding of cobalamin to methionine synthase. Biochemistry 40: 5056–5064.[CrossRef][Medline]

Bandarian, V., Ludwig, M.L., and Matthews, R.G. 2003. Factors modulating conformational equilibria in large modular proteins: A case study with cobalamin-dependent methionine synthase. Proc. Natl. Acad. Sci. 100: 8156–8163.[Abstract/Free Full Text]

Bandarian, V., Pattridge, K.A., Lennon, B.W., Huddler, D.P., Matthews, R.G., and Ludwig, M.L. 2002. Domain alternation switches B₁₂-dependent methionine synthase to the activation conformation. Nat. Struct. Biol. 9: 53–56.[CrossRef][Medline]

Banerjee, R.V., Johnston, N.L., Sobeski, J.K., Datta, P., and Matthews, R.G. 1989. Cloning and sequence analysis of the Escherichia coli metH gene encoding cobalamin-dependent methionine synthase and isolation of a tryptic fragment containing the cobalamin-binding domain. J. Biol. Chem. 264: 13888–13895.[Abstract/Free Full Text]

Banerjee, R.V., Harder, S.F., Ragsdale, S.W., and Matthews, R.G. 1990. Mechanism of reductive activation of cobalamin-dependent methionine synthase: An electron paramagnetic resonance spectroelectrochemical study. Biochemistry 29: 1129–1133.[CrossRef][Medline]

Daniel, R.M. and Danson, M.J. 2001. Assaying activity and assessing thermostability of hyperthermophilic enzymes. Methods Enzymol. 334: 283–293.[Medline]

Dixon, M.M., Huang, S., Matthews, R.G., and Ludwig, M. 1996. The structure of the C-terminal domain of methionine synthase: Presenting S-adenosylmethionine for reductive methylation of B₁₂ . Structure 4: 1263–1275.[Medline]

Drummond, J.T., Huang, S., Blumenthal, R.M., and Matthews, R.G. 1993. Assignment of enzymatic function to specific protein regions of cobalamin-dependent methionine synthase from Escherichia coli . Biochemistry 32: 9290–9295.[CrossRef][Medline]

Evans, J.C., Huddler, D.P., Hilgers, M.T., Romanchuk, G., Matthews, R.G., and Ludwig, M.L. 2004. Structures of the N-terminal modules imply large domain motions during catalysis by methionine synthase. Proc. Natl. Acad. Sci. 101: 3729–3736.[Abstract/Free Full Text]

Goulding, C.W. and Matthews, R.G. 1997. Cobalamin-dependent methionine synthase from Escherichia coli: Involvement of zinc in homocysteine activation. Biochemistry 36: 15749–15757.[CrossRef][Medline]

Goulding, C.W., Postigo, D., and Matthews, R.G. 1997. Cobalamin-dependent methionine synthase is a modular protein with distinct regions for binding homocysteine, methyltetrahydrofolate, cobalamin, and adenosylmethionine. Biochemistry 36: 8082–8091.[CrossRef][Medline]

Indrawati, I., Van Loey, A., and Hendrickx, M. 2005. Pressure and temperature stability of 5-methyltetrahydrofolic acid: A kinetic study. J. Agric. Food Chem. 53: 3081–3087.[CrossRef][Medline]

Jarrett, J.T., Amaratunga, M., Drennan, C.L., Scholten, J.D., Sands, R.H., Ludwig, M.L., and Matthews, R.G. 1996. Mutations in the B₁₂-binding region of methionine synthase: How the protein controls methylcobalamin reactivity. Biochemistry 35: 2464–2475.[CrossRef][Medline]

Jarrett, J.T., Goulding, C.W., Fluhr, K., Huang, S., and Matthews, R.G. 1997. Purification and assay of cobalamin-dependent methionine synthase from Escherichia coli . Methods Enzymol. 281: 196–213.[Medline]

Jarrett, J.T., Hoover, D.M., Ludwig, M.L., and Matthews, R.G. 1998. The mechanism of adenosylmethionine-dependent activation of methionine synthase: A rapid kinetic analysis of intermediates in reductive methylation of Cob(II)alamin enzyme. Biochemistry 37: 12649–12658.[CrossRef][Medline]

Ludwig, M.L. and Matthews, R.G. 1997. Structure-based perspectives on B₁₂-dependent enzymes. Annu. Rev. Biochem. 66: 269–313.[CrossRef][Medline]

Matthews, R.G. 1999. Cobalamin-dependent methionine synthase. In Chemistry and biochemistry of B₁₂ (ed. R. Banerjee), pp. 681–706. John Wiley, New York.

Taylor, R.T. and Weissbach, H. 1967. N ⁵-Methyltetrahydrofolate-homocysteine transmethylase: Partial purification and properties. J. Biol. Chem. 242: 1502–1508.[Abstract/Free Full Text]

Thompson, M.J. and Eisenberg, D. 1999. Transproteomic evidence of a loop-deletion mechanism for enhancing protein thermostability. J. Mol. Biol. 290: 595–604.[CrossRef][Medline]

Yamada, K., Gravel, R.A., Toraya, T., and Matthews, R.G. 2006. Human methionine synthase reductase is a molecular chaperone for human methionine synthase. Proc. Natl. Acad. Sci. 103: 9476–9481.[Abstract/Free Full Text]

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