Three dimensional structure of porcine pancreatic alpha-amylase at 2.9 A resolution. Role of calcium in structure and activity.

The crystal structure of porcine pancreatic alpha-amylase (PPA) has been solved at 2.9 A resolution by X-ray crystallographic methods. The enzyme contains three domains. The larger, in the N-terminal part, consists of 330 amino acid residues. This central domain has the typical parallel-stranded alpha-beta barrel structure (alpha beta)8, already found in a number of other enzymes like triose phosphate isomerase and pyruvate kinase. The C-terminal domain forms a distinct globular unit where the chain folds into an eight-stranded antiparallel beta-barrel. The third domain lies between a beta-strand and a alpha-helix of the central domain, in a position similar to those found for domain B in triose phosphate isomerase and pyruvate kinase. It is essentially composed of antiparallel beta-sheets. The active site is located in a cleft within the N-terminal central domain, at the carboxy-end of the beta-strands of the (alpha beta)8 barrel. Binding of various substrate analogues to the enzyme suggests that the amino acid residues involved in the catalytic reaction are a pair of aspartic acids. A number of other residues surround the substrate and seem to participate in its binding via hydrogen bonds and hydrophobic interactions. The 'essential' calcium ion has been located near the active site region and between two domains, each of them providing two calcium ligands. On the basis of sequence comparisons this calcium binding site is suggested to be a common structural feature of all alpha-amylases. It represents a new type of calcium-protein interaction pattern.(ABSTRACT TRUNCATED AT 250 WORDS)     

High-resolution structure of NodZ fucosyltransferase involved in the biosynthesis of the nodulation factor

The fucosyltransferase NodZ is involved in the biosynthesis of the nodulation factor in nitrogen-fixing symbiotic bacteria. It catalyzes alpha1,6 transfer of l-fucose from GDP-fucose to the reducing residue of the synthesized Nod oligosaccharide. We present the structure of the NodZ protein from Bradyrhizobium expressed in Escherichia coli and crystallized in the presence of phosphate ions in two crystal forms. The enzyme is arranged into two domains of nearly equal size. Although NodZ falls in one broad class (GT-B) with other two-domain glycosyltransferases, the topology of its domains deviates from the canonical Rossmann fold, with particularly high distortions in the N-terminal domain. Mutational data combined with structural and sequence alignments indicate residues of potential importance in GDP-fucose binding or in the catalytic mechanism. They are all clustered in three conserved sequence motifs located in the C-terminal domain.     

Mosaic structure of globular domains in the human type VI collagen alpha 3 chain: similarity to von Willebrand factor, fibronectin, actin, salivary proteins and aprotinin type protease inhibitors.

Human collagen alpha 3(VI) chain mRNA (approximately 10 kb) was cloned and shown by sequence analysis to encode a 25 residue signal peptide, a large N-terminal globule (1804 residues), a central triple helical segment (336 residues) and a C-terminal globule (803 residues). Some of the sequence was confirmed by Edman degradation of peptides. The N-terminal globular segment consists of nine consecutive 200 residue repeats (N1 to N9) showing internal homology and also significant identity (17-25%) to the A domains of von Willebrand Factor and similar domains present in some other proteins. Deletions were found in the N3 and N9 domains of several cDNA clones suggesting variation of these structures by alternative splicing. The C-terminal globule starts immediately after the triple helical segment with two domains C1 (184 residues) and C2 (248 residues) being similar to the N domains. They are followed by a proline rich, repetitive segment C3 of 122 residues, with similarity to some salivary proteins, and domain C4 (89 residues), which is similar to the type III repeats present in fibronectin and tenascin. The most C-terminal domain C5 (70 residues) shows 40-50% identity to a variety of serine protease inhibitors of the Kunitz type. The whole sequence contains 29 cysteines which are mainly clustered in short segments connecting domains N1, C1, C2 and the triple helix, and in the inhibitor domain. Five putative Arg-Gly-Asp cell-binding sequences are exclusively localized in the triple helical segment.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alternative mode of binding to phosphotyrosyl peptides by Src homology-2 domains

Src homology-2 (SH2) domains recognize specific phosphotyrosyl (pY) proteins and promote protein-protein interactions. In their classical binding mode, the SH2 domain makes specific contacts with the pY residue and the three residues immediately C-terminal to the pY, although for a few SH2 domains, residues N-terminal to pY have recently been shown to also contribute to the overall binding affinity and specificity. In this work, the ability of an SH2 domain to bind to the N-terminal side of pY has been systematically examined. A pY peptide library containing completely randomized residues at positions -5 to -1 (relative to pY, which is position 0) was synthesized on TentaGel resin and screened against the four SH2 domains of phosphatases SHP-1 and SHP-2. Positive beads that carry high-affinity ligands of the SH2 domains were identified using an enzyme-linked assay, and the peptides were sequenced by partial Edman degradation and matrix-assisted laser desorption ionization mass spectrometry. The N-terminal SH2 domain of SHP-2 binds specifically to peptides of the consensus sequence (H/F)XVX(T/S/A)pY. Further binding studies with individually synthesized pY peptides show that pY and the five residues N-terminal to pY, but not any of the C-terminal residues, are important for binding. The other three SH2 domains also bound to the library beads, albeit more weakly, and the selected peptides did not show any clear consensus. These results demonstrate that at least some SH2 domains can bind to pY peptides in an alternative mode by recognizing only the residues N-terminal to pY.     

Dimeric Crystal Structure of Rabbit l-Gulonate 3-Dehydrogenase/λ-Crystallin: Insights into the Catalytic Mechanism

l-Gulonate 3-dehydrogenase (GDH) is a bifunctional dimeric protein that functions not only as an NAD⁺-dependent enzyme in the uronate cycle but also as a taxon-specific λ-crystallin in rabbit lens. Here we report the first crystal structure of GDH in both apo form and NADH-bound holo form. The GDH protomer consists of two structural domains: the N-terminal domain with a Rossmann fold and the C-terminal domain with a novel helical fold. In the N-terminal domain of the NADH-bound structure, we identified 11 coenzyme-binding residues and found 2 distinct side-chain conformers of Ser124, which is a putative coenzyme/substrate-binding residue. A structural comparison between apo form and holo form and a mutagenesis study with E97Q mutant suggest an induced-fit mechanism upon coenzyme binding; coenzyme binding induces a conformational change in the coenzyme-binding residues Glu97 and Ser124 to switch their activation state from resting to active, which is required for the subsequent substrate recruitment. Subunit dimerization is mediated by numerous intersubunit interactions, including 22 hydrogen bonds and 104 residue pairs of van der Waals interactions, of which those between two cognate C-terminal domains are predominant. From a structure/sequence comparison within GDH homologues, a much greater degree of interprotomer interactions (both polar and hydrophobic) in the rabbit GDH would contribute to its higher thermostability, which may be relevant to the other function of this enzyme as λ-crystallin, a constitutive structural protein in rabbit lens. The present crystal structures and amino acid mutagenesis studies assigned the role of active-site residues: catalytic base for His145 and substrate binding for Ser124, Cys125, Asn196, and Arg231. Notably, Arg231 participates in substrate binding from the other subunit of the GDH dimer, indicating the functional significance of the dimeric state. Proper orientation of the substrate-binding residues for catalysis is likely to be maintained by an interprotomer hydrogen-bonding network of residues Asn196, Gln199, and Arg231, suggesting a network-based substrate recognition of GDH.     

Cell surface anchorage and ligand-binding domains of the Saccharomyces cerevisiae cell adhesion protein alpha-agglutinin, a member of the immunoglobulin superfamily.

alpha-Agglutinin is a cell adhesion glycoprotein expressed on the cell wall of Saccharomyces cerevisiae alpha cells. Binding of alpha-agglutinin to its ligand a-agglutinin, expressed by a cells, mediates cell-cell contact during mating. Analysis of truncations of the 650-amino-acid alpha-agglutinin structural gene AG alpha 1 delineated functional domains of alpha-agglutinin. Removal of the C-terminal hydrophobic sequence allowed efficient secretion of the protein and loss of cell surface attachment. This cell surface anchorage domain was necessary for linkage to a glycosyl phosphatidylinositol anchor. A construct expressing the N-terminal 350 amino acid residues retained full a-agglutinin-binding activity, localizing the binding domain to the N-terminal portion of alpha-agglutinin. A 278-residue N-terminal peptide was inactive; therefore, the binding domain includes residues between 278 and 350. The segment of alpha-agglutinin between amino acid residues 217 and 308 showed significant structural and sequence similarity to a consensus sequence for immunoglobulin superfamily variable-type domains. The similarity of the alpha-agglutinin-binding domain to mammalian cell adhesion proteins suggests that this structure is a highly conserved feature of adhesion proteins in diverse eukaryotes.     

Structure of the Escherichia coli TolB protein determined by MAD methods at 1.95 A resolution.

BACKGROUND: The periplasmic protein TolB from Escherichia coli is part of the Tol-PAL (peptidoglycan-associated lipoprotein) multiprotein complex used by group A colicins to penetrate and kill cells. TolB homologues are found in many gram-negative bacteria and the Tol-PAL system is thought to play a role in bacterial envelope integrity. TolB is required for lethal infection by Salmonella typhimurium in mice. RESULTS: The crystal structure of the selenomethionine-substituted TolB protein from E. coli was solved using multiwavelength anomalous dispersion methods and refined to 1. 95 A. TolB has a two-domain structure. The N-terminal domain consists of two alpha helices, a five-stranded beta-sheet floor and a long loop at the back of this floor. The C-terminal domain is a six-bladed beta propeller. The small, possibly mobile, contact area (430 A(2)) between the two domains involves residues from the two helices and the first and sixth blades of the beta propeller. All available genomic sequences were used to identify new TolB homologues in gram-negative bacteria. The TolB structure was then interpreted using the observed conservation pattern. CONCLUSIONS: The TolB beta-propeller C-terminal domain exhibits sequence similarities to numerous members of the prolyl oligopeptidase family and, to a lesser extent, to class B metallo-beta-lactamases. The alpha/beta N-terminal domain shares a structural similarity with the C-terminal domain of transfer RNA ligases. We suggest that the TolB protein might be part of a multiprotein complex involved in the recycling of peptidoglycan or in its covalent linking with lipoproteins.     

Subunit gamma of the oxaloacetate decarboxylase Na(+) pump: interaction with other subunits/domains of the complex and binding site for the Zn(2+) metal ion.

The oxaloacetate decarboxylase Na(+) pump of Klebsiella pneumoniae is an enzyme complex composed of the peripheral alpha subunit and the two integral membrane-bound subunits beta and gamma. The alpha subunit consists of the N-terminal carboxyltransferase domain and the C-terminal biotin domain, which are connected by a flexible proline/alanine-rich linker peptide. To probe interactions between the two domains of the alpha subunit and between alpha-subunit domains and the gamma subunit, the relevant polypeptides were synthesized in Escherichia coli and subjected to copurification studies. The two alpha-subunit domains had no distinct affinity toward each other and could, therefore, not be purified as a unit on avidin-sepharose. The two domains reacted together catalytically, however, performing the carboxyl transfer from oxaloacetate to protein-bound biotin. This reaction was enhanced up to 6-fold in the presence of the Zn(2+)-containing gamma subunit. On the basis of copurification with different tagged proteins, the C-terminal biotin domain but not the N-terminal carboxyltransferase domain of the alpha subunit formed a strong complex with the gamma subunit. Upon the mutation of gamma H78 to alanine, the binding affinity to subunit alpha was lost, indicating that this amino acid may be essential for formation of the oxaloacetate decarboxylase enzyme complex. The binding residues for the Zn(2+) metal ion were identified by site-directed and deletion mutagenesis. In the gamma D62A or gamma H77A mutant, the Zn(2+) content of the decarboxylase decreased to 35% or 10% of the wild-type enzyme, respectively. Less than 5% of the Zn(2+) present in the wild-type enzyme was found if the two C-terminal gamma-subunit residues H82 and P83 were deleted. Corresponding with the reduced Zn(2+) contents in these mutants, the oxaloacetate decarboxylase activities were diminished. These results indicate that aspartate 62, histidine 77, and histidine 82 of the gamma subunit are ligands for the catalytically important Zn(2+) metal ion.     

Variant specific glycoprotein of Trypanosoma brucei consists of two domains each having an independently conserved pattern of cysteine residues

The complete amino acid sequences for nine variant specific glycoproteins (VSGs) of Trypanosoma brucei are presented. These have more than doubled the size of the VSG sequence data base and have enabled a new and more rigorous comparison to be made between amino acid sequences of different VSGs. Each VSG can be defined as a combination of an N-terminal domain type and a C-terminal domain type, based on the distribution of cysteine residues within the molecule. This identifies three N-terminal domain types and at least four C-terminal domain types. Different combinations of N and C-terminal domains can be formed; for example, in the sequences presented here, two different N-terminal domains are found in association with each of three different C-terminal domains. The biological context of the domain structure of VSGs is discussed.     

The crystal structure of DR2241 from Deinococcus radiodurans at 1.9 A resolution reveals a multi-domain protein with structural similarity to chelatases but also with two additional novel domains

A unique family of proteins have been identified in the Deinococcus genus with an N-terminal cobalamin (vitamin B(12)) chelatase domain denoted CbiX and an additional unique C-terminal domain with unknown function. Here we report the first crystal structure from this new family of proteins with the structure of Deinococcus radiodurans protein DR2241. The structure reveals a multi-domain protein where domains A (residues 1-132) has the same fold as the small CbiX (CbiX(S)), domains A and B (residues 1-272) follow the chelatase super-family fold and the two additional unique domains C and D have no structural homologues. Domain D harbours the sequence motifs CxxC and CxxxC, in which DR2241 gives the first evidence that these motifs bind a [4Fe-4S] iron-sulphur cluster. In solution there are indications of multimeric forms, and in the crystallographic asymmetric unit a tetramer is found where domains C and D are involved in stabilising the tetrameric assembly.     

Structural studies of MFE-1: the 1.9 A crystal structure of the dehydrogenase part of rat peroxisomal MFE-1

The 1.9 A structure of the C-terminal dehydrogenase part of the rat peroxisomal monomeric multifunctional enzyme type 1 (MFE-1) has been determined. In this construct (residues 260-722 and referred to as MFE1-DH) the N-terminal hydratase part of MFE-1 has been deleted. The structure of MFE1-DH shows that it consists of an N-terminal helix, followed by a Rossmann-fold domain (domain C), followed by two tightly associated helical domains (domains D and E), which have similar topology. The structure of MFE1-DH is compared with the two known homologous structures: human mitochondrial 3-hydroxyacyl-CoA dehydrogenase (HAD; sequence identity is 33%) (which is dimeric and monofunctional) and with the dimeric multifunctional alpha-chain (alphaFOM; sequence identity is 28%) of the bacterial fatty acid beta-oxidation alpha2beta2-multienzyme complex. Like MFE-1, alphaFOM has an N-terminal hydratase part and a C-terminal dehydrogenase part, and the structure comparisons show that the N-terminal helix of MFE1-DH corresponds to the alphaFOM linker helix, located between its hydratase and dehydrogenase part. It is also shown that this helix corresponds to the C-terminal helix-10 of the hydratase/isomerase superfamily, suggesting that functionally it belongs to the N-terminal hydratase part of MFE-1.     

The crystal structure of leucyl/phenylalanyl-tRNA-protein transferase from Escherichia coli

Leucyl/phenylalanyl-tRNA-protein transferase (L/F-transferase) is an N-end rule pathway enzyme, which catalyzes the transfer of Leu and Phe from aminoacyl-tRNAs to exposed N-terminal Arg or Lys residues of acceptor proteins. Here, we report the 1.6 A resolution crystal structure of L/F-transferase (JW0868) from Escherichia coli, the first three-dimensional structure of an L/F-transferase. The L/F-transferase adopts a monomeric structure consisting of two domains that form a bilobate molecule. The N-terminal domain forms a small lobe with a novel fold. The large C-terminal domain has a highly conserved fold, which is observed in the GCN5-related N-acetyltransferase (GNAT) family. Most of the conserved residues of L/F-transferase reside in the central cavity, which exists at the interface between the N-terminal and C-terminal domains. A comparison of the structures of L/F-transferase and the bacterial peptidoglycan synthase FemX, indicated a structural homology in the C-terminal domain, and a similar domain interface region. Although the peptidyltransferase function is shared between the two proteins, the enzymatic mechanism would differ. The conserved residues in the central cavity of L/F-transferase suggest that this region is important for the enzyme catalysis.     

The C-terminal domain of dnaQ contains the polymerase binding site

The Escherichia coli dnaQ gene encodes the 3'-->5' exonucleolytic proofreading (epsilon) subunit of DNA polymerase III (Pol III). Genetic analysis of dnaQ mutants has suggested that epsilon might consist of two domains, an N-terminal domain containing the exonuclease and a C-terminal domain essential for binding the polymerase (alpha) subunit. We have created truncated forms of dnaQ resulting in epsilon subunits that contain either the N-terminal or the C-terminal domain. Using the yeast two-hybrid system, we analyzed the interactions of the single-domain epsilon subunits with the alpha and theta subunits of the Pol III core. The DnaQ991 protein, consisting of the N-terminal 186 amino acids, was defective in binding to the alpha subunit while retaining normal binding to the theta subunit. In contrast, the NDelta186 protein, consisting of the C-terminal 57 amino acids, exhibited normal binding to the alpha subunit but was defective in binding to the theta subunit. A strain carrying the dnaQ991 allele exhibited a strong, recessive mutator phenotype, as expected from a defective alpha binding mutant. The data are consistent with the existence of two functional domains in epsilon, with the C-terminal domain responsible for polymerase binding.     

Structures of the platelet calcium- and integrin-binding protein and the alphaIIb-integrin cytoplasmic domain suggest a mechanism for calcium-regulated recognition; homology modelling and NMR studies

Calcium- and integrin-binding protein (CIB) binds to the 20-residue alphaIIb cytoplasmic domain of platelet alphaIIbbeta3 integrin. Amino acid sequence similarities with calmodulin (CaM) and calcineurin B (CnB) allowed the construction of homology-based models of calcium-saturated CIB as well as apo-CIB. In addition, the solution structure of the alphaIIb cytoplasmic domain in 45% aqueous trifluoroethanol was solved by conventional two-dimensional NMR methods. The models indicate that the N-terminal domain of CIB possesses a number of positively charged residues in its binding site that could interact with the acidic carboxy-terminal LEEDDEEGE sequence of alphaIIb. The C-terminal domain of CIB seems well-suited to bind the sequence WKVGFFKR, which forms a well-structured alpha helix; this is analogous to calmodulin and calcineurin B, which also bind alpha helices. Similarities between the C-terminal domains of CIB and calmodulin suggest that binding of CIB to the cytoplasmic domain of alphaIIb may be affected by fluctuations in the intracellular calcium concentration.     

Structure of the C-terminal domain from Trypanosoma brucei variant surface glycoprotein MITat1.2

The variant surface glycoprotein (VSG) of African trypanosomes has a structural role in protecting other cell surface proteins from effector molecules of the mammalian immune system and also undergoes antigenic variation necessary for a persistent infection in a host. Here we have reported the solution structure of a VSG type 2 C-terminal domain from MITat1.2, completing the first structure of both domains of a VSG. The isolated C-terminal domain is a monomer in solution and forms a novel fold, which commences with a short alpha-helix followed by a single turn of 3(10)-helix and connected by a short loop to a small anti-parallel beta-sheet and then a longer alpha-helix at the C terminus. This compact domain is flanked by two unstructured regions. The structured part of the domain contains 42 residues, and the core comprises 2 disulfide bonds and 2 hydrophobic residues. These cysteines and hydrophobic residues are conserved in other VSGs, and we have modeled the structures of two further VSG C-terminal domains using the structure of MITat1.2. The models suggest that the overall structure of the core is conserved in the different VSGs but that the C-terminal alpha-helix is of variable length and depends on the presence of charged residues. The results provided evidence for a conserved tertiary structure for all the type 2 VSG C-terminal domains, indicated that VSG dimers form through interactions between N-terminal domains, and showed that the selection pressure for sequence variation within a conserved tertiary structure acts on the whole of the VSG molecule.     

Three-dimensional structure of cyclodextrin glycosyltransferase from Bacillus circulans at 3.4 A resolution

Cyclodextrin glycosyltransferase (EC 2.4.1.19) from Bacillus circulans has been purified, crystallized and analyzed by X-ray diffraction. The enzyme is monomeric. SDS/polyacrylamide gel electrophoresis gave an Mr of 73,600(+/- 1000), corresponding to 670(+/- 10) amino acid residues. The structure of the crystalline enzyme has been elucidated at a resolution of 3.4 A, using multiple isomorphous replacement and solvent flattening for phase determination. The resulting electron density map allowed tracing of the polypeptide chain; 664 residue positions have been assigned. The chain fold has been subdivided into five domains. The N-terminal domain forms a (beta alpha)8-barrel, which contains the second domain of about 55 residues as an insert after the third beta-strand. The three remaining domains form almost exclusively beta-pleated sheet structures and consist of about 90, 80 and 95 residues. The chain fold of the three N-terminal domains of 492 residues resembles closely the two known structures of alpha-amylases. This geometric similarity corresponds to the observed amino acid sequence homology. On the basis of the sequence homology with alpha-amylases, the active center can be located. The fourth domain has an immunoglobulin fold and is far away from the active center, while the fifth domain participates in the formation of the broad depression at the active center. Accordingly, the cyclodextrin glycosyltransferase chain fold can be considered as an alpha-amylase chain fold with two additional domains.     

Expression and aggregation of recombinant alpha A-crystallin and its two domains.

The 20 kDa alpha A and alpha B subunits of alpha-crystallin from mammalian eye lenses form large aggregates with an average molecular weight of 800,000. To get insight into the interactions responsible for aggregate formation, we expressed in Escherichia coli the putative N- and C-terminal domains of alpha A-crystallin, as well as the intact alpha A-crystallin chain. The proteins are expressed in a stable form and in relatively high amounts (20-60% of total protein). Recombinant alpha A-crystallin and the C-terminal domain are expressed in a water-soluble form. Recombinant alpha A-crystallin forms aggregates comparable with alpha-crystallin aggregates from calf lenses, whereas the C-terminal domain forms dimers or tetramers. The N-terminal domain is expressed in an initially water-insoluble form. After solubilization, denaturation and reaggregation the N-terminal domain exists in a high molecular weight multimeric form. These observations suggest that the interactions leading to aggregation of alpha A-crystallin subunits are mainly located in the N-terminal half of the chain.     

A hydrophobic segment within the C-terminal domain is essential for both client-binding and dimer formation of the HSP90-family molecular chaperone.

The alpha isoform of human 90-kDa heat shock protein (HSP90alpha) is composed of three domains: the N-terminal (residues 1-400); middle (residues 401-615) and C-terminal (residues 621-732). The middle domain is simultaneously associated with the N- and C-terminal domains, and the interaction with the latter mediates the dimeric configuration of HSP90. Besides one in the N-terminal domain, an additional client-binding site exists in the C-terminal domain of HSP90. The aim of the present study is to elucidate the regions within the C-terminal domain responsible for the bindings to the middle domain and to a client protein, and to define the relationship between the two functions. A bacterial two-hybrid system revealed that residues 650-697 of HSP90alpha were essential for the binding to the middle domain. An almost identical region (residues 657-720) was required for the suppression of heat-induced aggregation of citrate synthase, a model client protein. Replacement of either Leu665-Leu666 or Leu671-Leu672 to Ser-Ser within the hydrophobic segment (residues 662-678) of the C-terminal domain caused the loss of bindings to both the middle domain and the client protein. The interaction between the middle and C-terminal domains was also found in human 94-kDa glucose-regulated protein. Moreover, Escherichia coli HtpG, a bacterial HSP90 homologue, formed heterodimeric complexes with HSP90alpha and the 94-kDa glucose-regulated protein through their middle-C-terminal domains. Taken together, it is concluded that the identical region including the hydrophobic segment of the C-terminal domain is essential for both the client binding and dimer formation of the HSP90-family molecular chaperone and that the dimeric configuration appears to be similar in the HSP90-family proteins.     

Sequence-structure-function analysis of the bifunctional enzyme MnmC that catalyses the last two steps in the biosynthesis of hypermodified nucleoside mnm5s2U in tRNA

MnmC catalyses the last two steps in the biosynthesis of 5-methylaminomethyl-2-thiouridine (mnm(5)s(2)U) in tRNA. Previously, we reported that this bifunctional enzyme is encoded by the yfcK open reading frame in the Escherichia coli K12 genome. However, the mechanism of its activity, in particular the potential structural and functional dependence of the domains responsible for catalyzing the two modification reactions, remains unknown. With the aid of the protein fold-recognition method, we constructed a structural model of MnmC in complex with the ligands and target nucleosides and studied the role of individual amino acids and entire domains by site-directed and deletion mutagenesis, respectively. We found out that the N-terminal domain contains residues responsible for binding of the S-adenosylmethionine cofactor and catalyzing the methylation of nm(5)s(2)U to form mnm(5)s(2)U, while the C-terminal domain contains residues responsible for binding of the FAD cofactor. Further, point mutants with compromised activity of either domain can complement each other to restore a fully functional enzyme. Thus, in the conserved fusion protein MnmC, the individual domains retain independence as enzymes. Interestingly, the N-terminal domain is capable of independent folding, while the isolated C-terminal domain is incapable of folding on its own, a situation similar to the one reported recently for the rRNA modification enzyme RsmC.     

Domain structure of riboflavin synthase.

Riboflavin synthase of Escherichia coli is a homotrimer of 23.4 kDa subunits catalyzing the formation of the carbocyclic ring of the vitamin, riboflavin, by dismutation of 6,7-dimethyl-8-ribityllumazine. Intramolecular sequence similarity suggested that each subunit folds into two topologically similar domains. In order to test this hypothesis, sequence segments comprising amino-acid residues 1-97 or 101-213 were expressed in recombinant E. coli strains. The recombinant N-terminal domain forms a homodimer that can bind riboflavin, 6,7-dimethyl-8-ribityllumazine and trifluoromethyl-substituted 8-ribityllumazine derivatives as shown by absorbance, circular dichroism, and NMR spectroscopy. Most notably, the recombinant domain dimer displays the same diastereoselectivity for ligands as the full length protein. The minimum N-terminal peptide segment required for ligand binding comprises amino-acid residues 1-87. The recombinant C-terminal domain comprising amino-acid residues 101-213 is relatively unstable and was shown not to bind riboflavin but to differentiate between certain diastereomeric trifluoromethyl-8-ribityllumazine derivatives. The data show that a single domain comprises the intact binding site for one substrate molecule. The enzyme-catalyzed dismutation requires two substrate molecules to be bound in close proximity, and each active site of the enzyme appears to be located at the interface of an N-terminal and C-terminal domain.