Investigating the structure of human RNase H1 by site-directed mutagenesis

In this study we examine for the first time the roles of the various domains of human RNase H1 by site-directed mutagenesis. The carboxyl terminus of human RNase H1 is highly conserved with Escherichia coli RNase H1 and contains the amino acid residues of the putative catalytic site and basic substrate-binding domain of the E. coli RNase enzyme. The amino terminus of human RNase H1 contains a structure consistent with a double-strand RNA (dsRNA) binding motif that is separated from the conserved E. coli RNase H1 region by a 62-amino acid sequence. These studies showed that although the conserved amino acid residues of the putative catalytic site and basic substrate-binding domain are required for RNase H activity, deletion of either the catalytic site or the basic substrate-binding domain did not ablate binding to the heteroduplex substrate. Deletion of the region between the dsRNA-binding domain and the conserved E. coli RNase H1 domain resulted in a significant loss in the RNase H activity. Furthermore, the binding affinity of this deletion mutant for the heteroduplex substrate was approximately 2-fold tighter than the wild-type enzyme suggesting that this central 62-amino acid region does not contribute to the binding affinity of the enzyme for the substrate. The dsRNA-binding domain was not required for RNase H activity, as the dsRNA-deletion mutants exhibited catalytic rates approximately 2-fold faster than the rate observed for wild-type enzyme. Comparison of the dissociation constant of human RNase H1 and the dsRNA-deletion mutant for the heteroduplex substrate indicates that the deletion of this region resulted in a 5-fold loss in binding affinity. Finally, comparison of the cleavage patterns exhibited by the mutant proteins with the cleavage pattern for the wild-type enzyme indicates that the dsRNA-binding domain is responsible for the observed strong positional preference for cleavage exhibited by human RNase H1.     

Sequence determination of the Sendai virus HN gene and its comparison to the influenza virus glycoproteins

The nucleotide sequence of the Sendai virus (SV) HN (hemagglutinin-neuraminidase) gene was determined. The deduced primary structure of the protein showed only one hydrophobic domain likely to represent the transmembrane region, but at its N terminus. Since the SV F protein is anchored in the membrane at its C terminus, the two SV glycoproteins are thus membrane-anchored in opposite orientations, similar to the two influenza virus (FLU) glycoproteins. Amino acid sequence comparisons of the SV HN and the FLU HA and NA proteins revealed homologies between 100 amino acids of the hemagglutinin region of the FLU HA protein and the C terminus of the SV HN, and between 200 amino acids of the neuraminidase region of the FLU NA and the central region of SV HN. Alignment of the neuraminidase, hemagglutinin, and fusion regions shared by these glycoproteins suggest the structure of a possible ancestral gene.     

Two Arginine Residues of Streptococcus gordonii Sialic Acid-Binding Adhesin Hsa Are Essential for Interaction to Host Cell Receptors

Hsa is a large, serine-rich protein of Streptococcus gordonii DL1 that mediates binding to α2-3-linked sialic acid termini of glycoproteins, including platelet glycoprotein Ibα, and erythrocyte membrane protein glycophorin A, and band 3. The binding of Hsa to platelet glycoprotein Ibα contributes to the pathogenesis of infective endocarditis. This interaction appears to be mediated by a second non-repetitive region (NR2) of Hsa. However, the molecular details of the interaction between the Hsa NR2 region and these glycoproteins are not well understood. In the present study, we identified the amino acid residues of the Hsa NR2 region that are involved in sialic acid recognition. To identify the sialic acid-binding site of Hsa NR2 region, we prepared various mutants of Hsa NR2 fused with glutathione transferase. Fusion proteins harboring Arg340 to Asn (R340N) or Arg365 to Asn (R365N) substitutions in the NR2 domain exhibited significantly reduced binding to human erythrocytes and platelets. A sugar-binding assay showed that these mutant proteins abolished binding to α2-3-linked sialic acid. Furthermore, we established S. gordonii DL1 derivatives that encoded the corresponding Hsa mutant protein. In whole-cell assays, these mutant strains showed significant reductions in hemagglutination, in platelet aggregation, and in adhesion to human leukocytes. These results indicate that the Arg340 and Arg365 residues of Hsa play an important role in the binding of Hsa to α2-3-linked sialic acid-containing glycoproteins.     

Identification of critical contact residues in the NC41 epitope of a subtype N9 influenza virus neuraminidase

We have examined amino acids on influenza virus neuraminidase (NA) subtype N9 (A/tern/Australia/G70c/75) which are in contact with monoclonal antibody NC41 to analyze individual interactions important for antibody recognition. The crystal structure of NA complexed with NC41 Fab¹ shows antibody contacts at 19 amino acid residues on the NA surface which are localized on five polypeptide loops surrounding the enzyme active site. Fifteen mutant NA genes were constructed to encode a protein which contained a single amino acid substitution and these were tested for effects of the replacement on NC41 binding. Our data revealed that NAs with changes at 368, 400, and 434 completely lost NC41 recognition. NAs with side chains replaced at residues 346 and 373 exhibited binding reduced to less than 50% of wild-type binding. Changes in seven other contacting residues, including substituted side chains which differed considerably from wild-type NA in size and charge, had no significant effect on NC41 binding. These results indicate that only a few of the many residues which make up an epitope are crucial for interaction and provide the critical contacts required for antibody recognition. This implies that antibody escape mutants are selected only if they contain changes at these crucial sites, or changes which introduce bulky side chains that sterically prevent antibody attachment. © 1993 Wiley-Liss, Inc.     

Structure of the Ulster Strain Newcastle Disease Virus Hemagglutinin-Neuraminidase Reveals Auto-Inhibitory Interactions Associated with Low Virulence

Paramyxovirus hemagglutinin-neuraminidase (HN) plays roles in viral entry and maturation, including binding to sialic acid receptors, activation of the F protein to drive membrane fusion, and enabling virion release during virus budding. HN can thereby directly influence virulence and in a subset of avirulent Newcastle disease virus (NDV) strains, such as NDV Ulster, HN must be proteolytically activated to remove a C-terminal extension not found in other NDV HN proteins. Ulster HN is 616 amino acids long and the 45 amino acid C-terminal extension present in its precursor (HN₀) form has to be cleaved to render HN biologically active. Here we show that Ulster HN contains an inter-subunit disulfide bond within the C-terminal extension at residue 596, which regulates HN activities and neuraminidase (NA) domain dimerization. We determined the crystal structure of the dimerized NA domain containing the C-terminal extension, which extends along the outside of the sialidase β-propeller domain and inserts C-terminal residues into the NA domain active site. The C-terminal extension also engages a secondary sialic acid binding site present in NDV HN proteins, which is located at the NA domain dimer interface, that most likely blocks its attachment function. These results clarify how the Ulster HN C-terminal residues lead to an auto-inhibited state of HN, the requirement for proteolytic activation of HN₀ and associated reduced virulence.     

Domain 5 of the cation-independent mannose 6-phosphate receptor preferentially binds phosphodiesters (mannose 6-phosphate N-acetylglucosamine ester)

The 300 kDa cation-independent mannose 6-phosphate receptor (CI-MPR) and the 46 kDa cation-dependent MPR (CD-MPR) are key components of the lysosomal enzyme targeting system that bind newly synthesized mannose 6-phosphate (Man-6-P)-containing acid hydrolases and divert them from the secretory pathway. Previous studies have mapped two high-affinity Man-6-P binding sites of the CI-MPR to domains 1-3 and 9 and one low-affinity site to domain 5 within its 15-domain extracytoplasmic region. A structure-based sequence alignment predicts that domain 5 contains the four conserved residues (Gln, Arg, Glu, Tyr) identified as essential for Man-6-P binding by the CD-MPR and domains 1-3 and 9 of the CI-MPR. Here we show by surface plasmon resonance (SPR) analyses of constructs containing single amino acid substitutions that these conserved residues (Gln-644, Arg-687, Glu-709, Tyr-714) are critical for carbohydrate recognition by domain 5. Furthermore, the N-glycosylation site at position 711 of domain 5, which is predicted to be located near the binding pocket, has no influence on the carbohydrate binding affinity. Endogenous ligands for the MPRs that contain solely phosphomonoesters (Man-6-P) or phosphodiesters (mannose 6-phosphate N-acetylglucosamine ester, Man-P-GlcNAc) were generated by treating the lysosomal enzyme acid alpha-glucosidase (GAA) with recombinant GlcNAc-phosphotransferase and uncovering enzyme (N-acetylglucosamine-1-phosphodiester alpha-N-acetylglucosaminidase). SPR analyses using these modified GAAs demonstrate that, unlike the CD-MPR or domain 9 of the CI-MPR, domain 5 exhibits a 14-18-fold higher affinity for Man-P-GlcNAc than Man-6-P, implicating this region of the receptor in targeting phosphodiester-containing lysosomal enzymes to the lysosome.     

Determination of Neuraminidase Kinetic Constants Using Whole Influenza Virus Preparations and Correction for Spectroscopic Interference by a Fluorogenic Substrate

The influenza neuraminidase (NA) enzyme cleaves terminal sialic acid residues from cellular receptors, a process required for the release of newly synthesized virions. A balance of NA activity with sialic acid binding affinity of hemagglutinin (HA) is important for optimal virus replication. NA sequence evolution through genetic shift and drift contributes to the continuous modulation of influenza virus fitness and pathogenicity. A simple and reliable method for the determination of kinetic parameters of NA activity could add significant value to global influenza surveillance and provide parameters for the projection of fitness and pathogenicity of emerging virus variants. The use of fluorogenic substrate 2′-(4-methylumbelliferyl)-α-D-N-acetylneuraminic acid (MUNANA) and cell- or egg-grown whole influenza virus preparations have been attractive components of NA enzyme activity investigations. We describe important criteria to be addressed when determining K_m and V_max kinetic parameters using this method: (1) determination of the dynamic range of MUNANA and 4-methylumbelliferone product (4-MU) fluorescence for the instrument used; (2) adjustment of reaction conditions to approximate initial rate conditions, i.e. ≤15% of substrate converted during the reaction, with signal-to-noise ratio ≥10; (3) correction for optical interference and inner filter effect caused by increasing concentrations of MUNANA substrate. The results indicate a significant interference of MUNANA with 4-MU fluorescence determination. The criteria proposed enable an improved rapid estimation of NA kinetic parameters and facilitate comparison of data between laboratories.     

Amino Acid Residues Contributing to the Substrate Specificity of the Influenza A Virus Neuraminidase

Influenza A viruses possess two glycoprotein spikes on the virion surface: hemagglutinin (HA), which binds to oligosaccharides containing terminal sialic acid, and neuraminidase (NA), which removes terminal sialic acid from oligosaccharides. Hence, the interplay between these receptor-binding and receptor-destroying functions assumes major importance in viral replication. In contrast to the well-characterized role of HA in host range restriction of influenza viruses, there is only limited information on the role of NA substrate specificity in viral replication among different animal species. We therefore investigated the substrate specificities of NA for linkages between N-acetyl sialic acid and galactose (NeuAcalpha2-3Gal and NeuAcalpha2-6Gal) and for different molecular species of sialic acids (N-acetyl and N-glycolyl sialic acids) in influenza A viruses isolated from human, avian, and pig hosts. Substrate specificity assays showed that all viruses had similar specificities for NeuAcalpha2-3Gal, while the activities for NeuAcalpha2-6Gal ranged from marginal, as represented by avian and early N2 human viruses, to high (although only one-third the activity for NeuAcalpha2-3Gal), as represented by swine and more recent N2 human viruses. Using site-specific mutagenesis, we identified in the earliest human virus with a detectable increase in NeuAcalpha2-6Gal specificity a change at position 275 (from isoleucine to valine) that enhanced the specificity for this substrate. Valine at position 275 was maintained in all later human viruses as well as swine viruses. A similar examination of N-glycolylneuraminic acid (NeuGc) specificity showed that avian viruses and most human viruses had low to moderate activity for this substrate, with the exception of most human viruses isolated between 1967 and 1969, whose NeuGc specificity was as high as that of swine viruses. The amino acid at position 431 was found to determine the level of NeuGc specificity of NA: lysine conferred high NeuGc specificity, while proline, glutamine, and glutamic acid were associated with lower NeuGc specificity. Both residues 275 and 431 lie close to the enzymatic active site but are not directly involved in the reaction mechanism. This finding suggests that the adaptation of NA to different substrates occurs by a mechanism of amino acid substitutions that subtly alter the conformation of NA in and around the active site to facilitate the binding of different species of sialic acid.     

Streptococcal-host interactions. Structural and functional analysis of a Streptococcus sanguis receptor for a human salivary glycoprotein

Colonization of oral tissues by Streptococcus sanguis may be influenced by a mucin-like salivary glycoprotein (SAG) through a calcium-dependent interaction with a specific bacterial receptor. We report the nucleotide and deduced amino acid sequence of the S. sanguis receptor (SSP-5) and show that this protein may bind sialic acid residues of SAG. The SSP-5 protein contains three unique structural domains, two of which consist of repetitive amino acid sequences. The N-terminal domain is comprised of four tandem copies of an 82-residue repeat which exhibits homology to M protein of Streptococcus pyogenes. This region is highly charged and predicted to be alpha-helical. A second hydrophilic repetitive domain consists of three copies of a 39-amino acid sequence containing 30% proline flanked by nonrepetitive proline-rich sequence. The third domain consists of 48% proline and resides near the C terminus of the protein. Secondary structure analysis of the SSP-5 sequence also identified four potential helix-turn-helix motifs that resembled E-F hand calcium binding domains. The SSP-5 protein is highly homologous to a surface antigen expressed by the mutans streptococci and the domain structure of SSP-5 is conserved within this family of proteins. The interactions of SSP-5 and of intact S. sanguis with SAG were inhibited by neuraminidase digestion of the salivary glycoprotein and by simple sugars containing sialic acid, suggesting that sialic acid is the primary ligand involved in the binding reaction.     

The activator protein for glucosylceramide beta-glucosidase from guinea pig liver. Improved isolation method and complete amino acid sequence

beta-Glucosidase activator (SAP-2) is a family of heat-stable, acidic glycoproteins which stimulate enzymatic hydrolysis of glucosylceramide. In this study, we improved the purification method and found that SAP-2 is highly heterogeneous. A hot water extract of frozen guinea pig liver was fractionated by ammonium sulfate sedimentation, then chromatographed with DEAE-Sephacel, Sephadex G-75, and concanavalin A-Sepharose. A fraction binding to concanavalin A-Sepharose was purified further with a C4 high performance liquid chromatography reverse phase column. This yielded several peaks, the main one of which was studied. The specific activity of the purified SAP-2 was 35 units/micrograms (1 unit produces 50% stimulation of a basal glucosidase preparation). N-terminal amino acid sequencing showed that this preparation is a mixture of polypeptides differing in the presence or absence of one or two of the end amino acids. The complete amino acid sequence of the 81 residues in SAP-2 has been determined. Comparison of the sequence of guinea pig SAP-2 with the sequence of human sphingomyelinase activator revealed 58% homology and quite similar hydropathy profiles. Both proteins possess a highly hydrophilic region around Asn-22, which is glycosylated, and 6 cysteine residues, in oxidized form, located in the same positions. Comparison with the published nucleotide sequence for the precursor form of the human activator protein for sulfatide sulfatase (SAP-1) suggested that this activator also has a possibly glycosylated Asn and 6 Cys residues at similar positions, although the remainder of the molecule is somewhat different. Examination of another region of the precursor's nucleotide sequence, assuming a few changes in the identifications, revealed the presence of the sphingomyelinase activator. It appears that two or more activators are derived from a single precursor protein. Marked homologies were seen also with a lung surfactant protein and a sulfated glycoprotein from Sertoli cells.     

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)     

Molecular insight into substrate recognition by human cytosolic sialidase NEU2

Sialidases or neuramidases are glycoside hydrolases removing terminal sialic acid residues from sialo-glycoproteins and sialo-glycolipids. Viral neuraminidases (NAs) have been extensively characterized and represent an excellent target for antiviral therapy through the synthesis of a series of competitive inhibitors that block the release of newly formed viral particles from infected cells. The human cytosolic sialidase NEU2 is the only mammalian enzyme structurally characterized and represents a valuable model to study the specificity of novel NA inhibitory drugs. Moreover, the availability of NEU2 3D structure represents a pivotal step toward the characterization of the molecular basis of natural substrates recognition by the enzyme. In this perspective, we have carried out a study of molecular docking of NEU2 active site using natural substrates of increasing complexity. Moreover, selective mutations of the residues putatively involved into substrate(s) interaction/recognition have been performed, and the resulting mutant enzymes have been preliminary tested for their catalytic activity and substrate specificity. We found that Q270 is involved in the binding of the disaccharide α(2,3) sialyl-galactose, whereas K45 and Q112 bind the distal glucose of the trisaccharide α(2,3) sialyl-lactose, corresponding to the oligosaccharide moiety of GM3 ganglioside. In addition, E218, beside D46, is proved to be a key catalytic residue, being, together with Y334, the second member of the nucleophile pair required for the catalysis. Overall, our results point out the existence of a dynamic network of interactions that are possibly involved in the recognition of the glycans bearing sialic acid.     

Sialic acid recognition by Vibrio cholerae neuraminidase

Vibrio cholerae neuraminidase (VCNA) plays a significant role in the pathogenesis of cholera by removing sialic acid from higher order gangliosides to unmask GM1, the receptor for cholera toxin. We previously showed that the structure of VCNA is composed of a central beta-propeller catalytic domain flanked by two lectin-like domains; however the nature of the carbohydrates recognized by these lectin domains has remained unknown. We present here structures of the enzyme in complex with two substrates, alpha-2,3-sialyllactose and alpha-2,6-sialyllactose. Both substrate complexes reveal the alpha-anomer of N-acetylneuraminic acid (Neu5Ac) bound to the N-terminal lectin domain, thereby revealing the role of this domain. The large number of interactions suggest a relatively high binding affinity for sialic acid, which was confirmed by calorimetry, which gave a Kd approximately 30 microm. Saturation transfer difference NMR using a non-hydrolyzable substrate, Neu5,9Ac2-2-S-(alpha-2,6)-GlcNAcbeta1Me, was also used to map the ligand interactions at the VCNA lectin binding site. It is well known that VCNA can hydrolyze both alpha-2,3- and alpha-2,6-linked sialic acid substrates. In this study using alpha-2,3-sialyllactose co-crystallized with VCNA it was revealed that the inhibitor 2-deoxy-2,3-didehydro-N-acetylneuraminic acid (Neu5Ac2en) was bound at the catalytic site. This observation supports the notion that VCNA can produce its own inhibitor and has been further confirmed by 1H NMR analysis. The discovery of the sialic acid binding site in the N-lectin-like domain suggests that this might help target VCNA to sialic acid-rich environments, thereby enhancing the catalytic efficiency of the enzyme.     

Escherichia coli methionyl-tRNA formyltransferase: role of amino acids conserved in the linker region and in the C-terminal domain on the specific recognition of the initiator tRNA

The formylation of initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF) is important for the initiation of protein synthesis in eubacteria. We are studying the molecular mechanisms of recognition of the initiator tRNA by Escherichia coli MTF. MTF from eubacteria contains an approximately 100-amino acid C-terminal extension that is not found in the E. coli glycinamide ribonucleotide formyltransferase, which, like MTF, use N(10)-formyltetrahydrofolate as a formyl group donor. This C-terminal extension, which forms a distinct structural domain, is attached to the N-terminal domain through a linker region. Here, we describe the effect of (i) substitution mutations on some nineteen basic, aromatic and other conserved amino acids in the linker region and in the C-terminal domain of MTF and (ii) deletion mutations from the C-terminus on enzyme activity. We show that the positive charge on two of the lysine residues in the linker region leading to the C-terminal domain are important for enzyme activity. Mutation of some of the basic amino acids in the C-terminal domain to alanine has mostly small effects on the kinetic parameters, whereas mutation to glutamic acid has large effects. However, the deletion of 18, 20, or 80 amino acids from the C-terminus has very large effects on enzyme activity. Overall, our results support the notion that the basic amino acid residues in the C-terminal domain provide a positively charged channel that is used for the nonspecific binding of tRNA, whereas some of the amino acids in the linker region play an important role in activity of MTF.     

Characterization and manipulation of the acyl chain selectivity of fatty acid amide hydrolase

Fatty acid amide hydrolase (FAAH) is a mammalian integral membrane enzyme that catabolizes several neuromodulatory fatty acid amides, including the endogenous cannabinoid anandamide and the sleep-inducing lipid oleamide. FAAH belongs to a large group of hydrolytic enzymes termed the amidase signature (AS) family that is defined by a conserved, linear AS sequence of approximately 130 amino acids. Members of the AS family display strikingly different substrate selectivities, yet the primary structural regions responsible for defining substrate recognition in these enzymes remain unknown. In this study, a series of unbranched p-nitroanilide (pNA) substrates ranging from 6 to 20 carbons in length was used to probe the acyl chain binding specificity of FAAH, revealing that this enzyme exhibits a strong preference for acyl chains 9 carbons in length or longer. A fluorophosphonate inhibitor of FAAH containing a photoactivatable benzophenone group was synthesized and used to locate a region of the enzyme implicated in substrate binding. Protease digestion and mass spectrometry analysis of FAAH-inhibitor conjugates identified the major site of cross-linking as residues 487-493. Site-directed mutagenesis revealed that a single residue in this region, I491, strongly influenced substrate specificity of FAAH. For example, an I491A mutant displayed a greatly reduced binding affinity for medium-chain pNA substrates (7-12 carbons) but maintained nearly wild-type binding and catalytic constants for longer chain substrates (14-20 carbons). Mutation of I491 to aromatic or more polar residues generated enzymes with relative hydrolytic efficiencies for medium- versus long-chain pNAs that varied up to 90-fold. Collectively, these studies indicate that I491 participates in hydrophobic binding interactions with medium-chain FAAH substrates. Additionally, the significant changes in substrate selectivity achieved by single amino acid changes suggest that FAAH possesses a rather malleable substrate binding domain and may serve, along with other AS enzymes, as a template for the engineering of amidases with novel and/or tailored specificities.     

Characterization of SAP-1, a protein recruited by serum response factor to the c-fos serum response element.

We used a yeast genetic screen to isolate cDNAs that encode a protein, SRF accessory protein-1 (SAP-1), that is recruited to the c-fos serum response element (SRE) as part of a ternary complex that includes serum response factor (SRF). SAP-1 requires DNA-bound SRF for ternary complex formation and makes extensive DNA contacts to the 5' side of SRF, but does not bind DNA autonomously. Ternary complex formation by SAP-1 requires only the DNA-binding domain of SRF, which can be replaced by that of the related yeast protein MCM1. We isolated cDNAs encoding two forms of SAP-1 protein, SAP-1a and SAP-1b, which differ at their C termini. Both SAP-1 proteins contain three regions of striking homology with the elk-1 protein, including an N-terminal ets domain. Ternary complex formation by SAP-1 requires both the ets domain and a second conserved region 50 amino acids to its C-terminal side. SAP-1 has similar DNA binding properties to the previously characterized HeLa cell protein p62/TCF.     

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.