Effect of interactions between amino acid residues 43 and 61 on thermal stability of bacterial formate dehydrogenases

NAD⁺-dependent formate dehydrogenases (EC 1.2.1.2, FDH) of methylotrophic bacteria Pseudomonas sp. 101 (PseFDH) and Mycobacterium vaccae N10 (MycFDH) exhibit high homology. They differ in two amino acid residues only among a total of 400, i.e., Ile35 and Glu61 in MycFDH substitute for Thr35 and Lys61 as in PseFDH. However, the rate constant for MycFDH thermal inactivation in the temperature range of 54-65°C is 4-6-times higher than the corresponding rate constant for the enzyme from Pseudomonas sp. 101. To clarify the role of these residues in FDH stability the dependence of the apparent rate constant for enzyme inactivation on phosphate concentration was studied. Kinetic and thermodynamic parameters for thermal inactivation were obtained for both recombinant wild-type and mutant forms, i.e., MycFDH Glu61Gln, Glu61Pro, Glu61Lys and PseFDH Lys61Arg. It has been shown that the lower stability of MycFDH compared to that of PseFDH is caused mainly by electrostatic repulsion between Asp43 and Glu61 residues. Replacement of Lys61 with an Arg residue in the PseFDH molecule does not result in an increase in stability.     

Role of the tetrahemic subunit in Desulfovibrio vulgaris hildenborough formate dehydrogenase

In the anaerobic sulfate-reducing bacterium Desulfovibrio vulgaris Hildenborough (DvH), the genome sequencing revealed the presence of three operons encoding formate dehydrogenases. fdh1 encodes an alphabetagamma trimeric enzyme containing 11 heme binding sites; fdh2 corresponds to an alphabetagamma trimeric enzyme with a tetrahemic subunit; fdh3 encodes an alphabeta dimeric enzyme. In the present work, spectroscopic measurements demonstrated that the reduction of cytochrome c(553) was obtained in the presence of the trimeric FDH2 and not with the dimeric FDH3, suggesting that the tetrahemic subunit (FDH2C) is essential for the interaction with this physiological electron transfer partner. To further study the role of the tetrahemic subunit, the fdh2C gene was cloned and expressed in Desulfovibrio desulfuricans G201. The recombinant FDH2C was purified and characterized by optical and NMR spectroscopies. The heme redox potentials measured by electrochemistry were found to be identical in the whole enzyme and in the recombinant subunit, indicating a correct folding of the recombinant protein. The mapping of the interacting site by 2D heteronuclear NMR demonstrated a similar interaction of cytochrome c(553) with the native enzyme and the recombinant subunit. The presence of hemes c in the gamma subunit of formate dehydrogenases is specific of these anaerobic sulfate-reducing bacteria and replaces heme b subunit generally found in the enzymes involved in anaerobic metabolisms.     

FDH: an aldehyde dehydrogenase fusion enzyme in folate metabolism

FDH (10-formyltetrahydrofolate dehydrogenase, Aldh1L1, EC 1.5.1.6) converts 10-formyltetrahydrofolate (10-formyl-THF) to tetrahydrofolate and CO(2) in a NADP(+)-dependent reaction. It is a tetramer of four identical 902 amino acid residue subunits. The protein subunit is a product of a natural fusion of three unrelated genes and consists of three distinct domains. The N-terminal domain of FDH (residues 1-310) carries the folate binding site and shares sequence homology and structural topology with other enzymes utilizing 10-formyl-THF as a substrate. In vitro it functions as 10-formyl-THF hydrolase, and evidence indicate that this activity is a part of the overall FDH mechanism. The C-terminal domain of FDH (residues 400-902) originated from an aldehyde dehydrogenase-related gene and is capable of oxidation of short-chain aldehydes to corresponding acids. Similar to classes 1 and 2 aldehyde dehydrogenases, this domain exists as a tetramer and defines the oligomeric structure of the full-length enzyme. The two catalytic domains are connected by an intermediate linker (residues 311-399), which is a structural and functional homolog of carrier proteins possessing a 4'-phosphopantetheine prosthetic group. In the FDH mechanism, the intermediate linker domain transfers a formyl, covalently attached to the sulfhydryl group of the phosphopantetheine arm, from the N-terminal domain to the C-terminal domain. The overall FDH mechanism is a coupling of two sequential reactions, a hydrolase and a formyl dehydrogenase, bridged by a substrate transfer step. In this mechanism, one domain provides the folate binding site and a hydrolase catalytic center to remove the formyl group from the folate substrate, another provides a transfer vehicle between catalytic centers and the third one contributes the dehydrogenase machinery further oxidizing formyl to CO(2).     

Phylogeny and evolution of aldehyde dehydrogenase-homologous folate enzymes

Folate coenzymes function as one-carbon group carriers in intracellular metabolic pathways. Folate-dependent reactions are compartmentalized within the cell and are catalyzed by two distinct groups of enzymes, cytosolic and mitochondrial. Some folate enzymes are present in both compartments and are likely the products of gene duplications. A well-characterized cytosolic folate enzyme, FDH (10-formyltetrahydro-folate dehydrogenase, ALDH1L1), contains a domain with significant sequence similarity to aldehyde dehydrogenases. This domain enables FDH to catalyze the NADP(+)-dependent conversion of short-chain aldehydes to corresponding acids in vitro. The aldehyde dehydrogenase-like reaction is the final step in the overall FDH mechanism, by which a tetrahydrofolate-bound formyl group is oxidized to CO(2) in an NADP(+)-dependent fashion. We have recently cloned and characterized another folate enzyme containing an ALDH domain, a mitochondrial FDH. Here the biological roles of the two enzymes, a comparison of the respective genes, and some potential evolutionary implications are discussed. The phylogenic analysis suggests that the vertebrate ALDH1L2 gene arose from a duplication event of the ALDH1L1 gene prior to the emergence of osseous fish >500 millions years ago.     

A cold-active and thermostable alcohol dehydrogenase of a psychrotorelant from Antarctic seawater, <Emphasis Type="Italic">Flavobacterium frigidimaris</Emphasis> KUC-1

An NAD⁺-dependent alcohol dehydrogenase of a psychrotorelant from Antarctic seawater, Flavobacterium frigidimaris KUC-1 was purified to homogeneity with an overall yield of about 20% and characterized enzymologically. The enzyme has an apparent molecular weight of 160k and consists of four identical subunits with a molecular weight of 40k. The pI value of the enzyme and its optimum pH for the oxidation reaction were determined to be 6.7 and 7.0, respectively. The enzyme contains 2 gram-atoms Zn per subunit. The enzyme exclusively requires NAD⁺ as a coenzyme and shows the pro-R stereospecificity for hydrogen transfer at the C4 position of the nicotinamide moiety of NAD⁺. F. frigidimaris KUC-1 alcohol dehydrogenase shows as high thermal stability as the enzymes from thermophilic microorganisms. The enzyme is active at 0 to over 85°C and the most active at 70°C. The half-life time and k _cat value at 60°C were calculated to be 50 min and 27,400 min⁻¹, respectively. The enzyme also shows high catalytic efficiency at low temperatures (0–20°C) (k _cat/K _m at 10°C; 12,600 mM⁻¹ min⁻¹) similar to other cold-active enzymes from psychrophiles. The alcohol dehydrogenase gene is composed of 1,035 bp and codes 344 amino acid residues with an estimated molecular weight of 36,823. The sequence identities were found with the amino acid sequences of alcohol dehydrogenases from Moraxella sp. TAE123 (67%), Pseudomonas aeruginosa (65%) and Geobacillus stearothermophilus LLD-R (56%). This is the first example of a cold-active and thermostable alcohol dehydrogenase.     

Heterologous production of extreme alkaline thermostable NAD+-dependent formate dehydrogenase with wide-range pH activity from Myceliophthora thermophila

NAD⁺-dependent formate dehydrogenase(s) (EC 1.2.1.2, FDH) catalyzes the interconversion of formate anion to carbon dioxide coupled with the conversion of NAD⁺ or NADH. FDHs attract significant attention in biotechnology due to their potential applications in NAD(H)-dependent industrial biocatalysis as well as in the production of renewable fuels and chemicals from carbon dioxide. In the present work, a new FDH from thermophilic fungus Myceliophthora thermophile (MtFDH) was characterized. The gene of the enzyme was synthesised, cloned, expressed in E. coli, as 6His-tagged protein, and purified to homogeneity by metal chelate affinity chromatography. Kinetic analysis suggested that MtFDH exhibits higher catalytic efficiency on NaHCO₃ compared to formate. Notable, recombinant MtFDH displays a pH optimum for the conversion of formate anion to carbon dioxide at extreme alkaline pH (pH 10.5). Thermal stability analysis showed that the enzyme displays good thermostability with T_m 48 °C. Homology modelling and phylogenetic analysis suggested that the enzyme belongs to the D-specific 2-hydroxy acid dehydrogenases family. The active-site residues are well conserved compared to other homologous FDHs. The results of the present work provide new knowledge on the structure, function and diversity of FDHs and indicate that MtFDH possess a huge potential for CO₂ reduction or NADH generation and under extreme alkaline conditions.     

<Emphasis Type="Italic">Thermotoga maritima</Emphasis> TM0298 is a highly thermostable mannitol dehydrogenase

Thermotoga maritima TM0298 is annotated as an alcohol dehydrogenase, yet it shows high identity and similarity to mesophilic mannitol dehydrogenases. To investigate this enzyme further, its gene was cloned and expressed in Escherichia coli. The purified recombinant enzyme was most active on fructose and mannitol, making it the first known hyperthermophilic mannitol dehydrogenase. T. maritima mannitol dehydrogenase (TmMtDH) is optimally active between 90 and 100 °C and retains 63% of its activity at 120 °C but shows no detectable activity at room temperature. Its kinetic inactivation follows a first-order mechanism, with half-lives of 57 min at 80 °C and 6 min at 95 °C. Although TmMtDH has a higher V _max with NADPH than with NADH, its catalytic efficiency is 2.2 times higher with NADH than with NADPH and 33 times higher with NAD⁺ than with NADP⁺. This cofactor specificity can be explained by the high density of negatively charged residues (Glu193, Asp195, and Glu196) downstream of the NAD(P) interaction site, the glycine motif. We demonstrate that TmMtDH contains a single catalytic zinc per subunit. Finally, we provide the first proof of concept that mannitol can be produced directly from glucose in a two-step enzymatic process, using a Thermotoga neapolitana xylose isomerase mutant and TmMtDH at 60 °C.     

A single mutation in the NAD-specific formate dehydrogenase from Candida methylica allows the enzyme to use NADP

An homology model of Candida methylica formate dehydrogenase (cmFDH) was constructed based on the Pseudomonas sp. 101 formate dehydrogenase (psFDH) structure. An aspartic acid residue in the model was predicted to interact with the adenine ribose of the NAD cofactor, in common with many NAD-dependent oxoreductases. Replacement of this aspartic acid residue by serine in cmFDH removed the absolute requirement for NAD over NADP shown by the wild type enzyme. Taken with similar results shown by d- and l-lactate dehydrogenases, this suggests that an aspartic acid in this position is a major determinant of coenzyme specificity in NAD/NADP-dependent dehydrogenases.     

Crystal structure of NAD-dependent formate dehydrogenase.

The ternary complex of NAD-dependent formate dehydrogenase (FDH) from the methylotrophic bacterium Pseudomonas sp. 101 (enzyme-NAD-azide) has been crystallised in the space group P2(1)2(1)2(1) with cell dimensions a = 11.60 nm, b = 11.33 nm, c = 6.34 nm. There is 1 dimeric molecule/asymmetric unit. An electron density map was calculated using phases from multiple isomorphous replacement at 0.30 nm resolution. Four heavy atom derivatives were used. The map was improved by solvent flattening and molecular averaging. The atomic model, including 2 x 393 amino acid residues, was refined by the CORELS and PROLSQ packages using data between 1.0 nm and 0.30 nm excluding structure factors less than 1 sigma. The current R factor is 27.1% and the root mean square deviation from ideal bond lengths is 4.2 pm. The FDH subunit is folded into a globular two-domain (coenzyme and catalytic) structure and the active centre and NAD binding site are situated at the domain interface. The beta sheet in the FDH coenzyme binding domain contains an additional beta strand compared to other dehydrogenases. The difference in quaternary structure between FDH and the other dehydrogenases means that FDH constitutes a new subfamily of NAD-dependent dehydrogenases: namely the P-oriented dimer. The FDH nucleotide binding region of the structure is aligned with the three dimensional structures of four other dehydrogenases and the conserved residues are discussed. The amino acid residues which contribute to the active centre and which make contact with NAD have been identified.     

Discovery of a new metal and NAD+-dependent formate dehydrogenase from Clostridium ljungdahlii

Over the next decades, with the growing concern of rising atmospheric carbon dioxide (CO₂) levels, the importance of investigating new approaches for its reduction becomes crucial. Reclamation of CO₂ for conversion into biofuels represents an alternative and attractive production method that has been studied in recent years, now with enzymatic methods gaining more attention. Formate dehydrogenases (FDHs) are NAD(P)H-dependent oxidoreductases that catalyze the conversion of formate into CO₂ and have been extensively used for cofactor recycling in chemoenzymatic processes. A new FDH from Clostridium ljungdahlii (ClFDH) has been recently shown to possess activity in the reverse reaction: the mineralization of CO₂ into formate. In this study, we show the successful homologous expression of ClFDH in Escherichia coli. Biochemical and kinetic characterization of the enzyme revealed that this homologue also demonstrates activity toward CO₂ reduction. Structural analysis of the enzyme through homology modeling is also presented.     

植物甲酸脱氢酶基因的表达调控及其生理功能研究进展

甲酸脱氢酶（FDH）是植物中普遍存在的一种含量丰富的酶。甲酸脱氢酶也是一种NAD依赖的酶,它催化甲酸氧化成二氧化碳的可逆反应。植物FDH是植物一碳代谢的一部分,它在植物响应各种环境胁迫、低氧或缺氧过程中发挥着重要的作用,因此在农学生产上具有很大的应用潜力。最近植物来源的FDH基因克隆和表达调控及其生理学功能等各方面的研究都取得很多重要的进展。综述了近年来植物来源的FDH基因克隆和表达调控及其生理学功能方面的研究进展。     

Effect of surface electrostatic interactions on the stability and folding of formate dehydrogenase from Candida methylica

NAD⁺-dependent formate dehydrogenase (FDH-EC 1.2.1.2) is an important enzyme to regenerate valuable NADH required by NAD⁺-dependent oxidoreductases in enzyme catalysis. The limitation in the thermostability of FDH enzyme is a crucial problem for development of biotechnological and industrial processes, despite of its advantages. In this study, to investigate the contribution of surface electrostatic interaction to the thermostability of FDH from Candida methylica (cmFDH) N187E, H13E, Q105R, N300E, N147R N300E/N147R, N187E/Q105R, N187E/N147R,Y160R, Y302R, Y160E and Y302E mutants were designed using a homology model of cmFDH based on Candida boidinii (cb) by considering electrostatic interactions on the protein surface. The effects of site-specific engineering on the stability of this molecule was analyzed according to minimal model of folding and assembly reaction and deduced equilibrium properties of the native system with respect to its thermal and denaturant sensitivities. It was observed that mutations did not change the unfolding pattern of native cmFDH and increased numbers of electrostatic interactions can cause either stabilizing or destabilizing effect on the thermostability of this protein. The thermodynamic and kinetic results suggested that except relatively improved mutants, three out of the nine single mutations increased the melting temperature of cmFDH enzyme.     

ALDH1L2 Is the Mitochondrial Homolog of 10-Formyltetrahydrofolate Dehydrogenase

Cytosolic 10-formyltetrahydrofolate dehydrogenase (FDH, ALDH1L1) is an abundant enzyme of folate metabolism. It converts 10-formyltetrahydrofolate to tetrahydrofolate and CO₂ in an NADP⁺-dependent reaction. We have identified a gene at chromosome locus 12q24.11 of the human genome, the product of which has 74% sequence similarity with cytosolic FDH. This protein has an extra N-terminal sequence of 22 amino acid residues, predicted to be a mitochondrial translocation signal. Transfection of COS-7 or A549 cell lines with a construct in which green fluorescent protein was introduced between the leader sequence and the rest of the putative mitochondrial FDH (mtFDH) has demonstrated mitochondrial localization of the fusion protein, suggesting that the identified gene encodes a mitochondrial enzyme. Purified pig liver mtFDH displayed dehydrogenase/hydrolase activities similar to cytosolic FDH. Real-time PCR performed on an array of human tissues has shown that although cytosolic FDH mRNA is highest in liver, kidney, and pancreas, mtFDH mRNA is most highly expressed in pancreas, heart, and brain. In contrast to the cytosolic enzyme, which is not detectable in cancer cells, the presence of mtFDH was demonstrated in several human cancer cell lines by conventional and real-time PCR and by Western blot. Analysis of genomes of different species indicates that the mitochondrial enzyme is a later evolutionary product when compared with the cytosolic enzyme. We propose that this novel mitochondrial enzyme is a likely source of CO₂ production from 10-formyltetrahydrofolate in mitochondria and plays an essential role in the distribution of one-carbon groups between the cytosolic and mitochondrial compartments of the cell.     

Maize glutathione-dependent formaldehyde dehydrogenase cDNA: a novel plant gene of detoxification

We have previously shown that intact plants and cultured plant cells can metabolize and detoxify formaldehyde through the action of a glutathione-dependent formaldehyde dehydrogenase (FDH), followed by C-1 metabolism of the initial metabolite (formic acid). The cloning and heterologous expression of a cDNA for the glutathione-dependent formaldehyde dehydrogenase from Zea mays L. is now described. The functional expression of the maize cDNA in Escherichia coli proved that the cloned enzyme catalyses the NAD⁺- and glutathione (GSH)-dependent oxidation of formaldehyde. The deduced amino acid sequence of 41 kDa was on average 65% identical with class III alcohol dehydrogenases from animals and less than 60% identical with conventional plant alcohol dehydrogenases (ADH) utilizing ethanol. Genomic analysis suggested the existence of a single gene for this cDNA. Phylogenetic analysis supports the convergent evolution of ethanol-consuming ADHs in animals and plants from formaldehyde-detoxifying ancestors. The high structural conservation of present-day glutathione-dependent FDH in microorganisms, plants and animals is consistent with a universal importance of these detoxifying enzymes.     

Crystal structures of the carboxyl terminal domain of rat 10-formyltetrahydrofolate dehydrogenase: implications for the catalytic mechanism of aldehyde dehydrogenases

10-Formyltetrahydrofolate dehydrogenase (FDH) catalyzes an NADP+-dependent dehydrogenase reaction resulting in conversion of 10-formyltetrahydrofolate to tetrahydrofolate and CO2. This reaction is a result of the concerted action of two catalytic domains of FDH, the amino-terminal hydrolase domain and the carboxyl-terminal aldehyde dehydrogenase domain. In addition to participation in the overall FDH mechanism, the C-terminal domain is capable of NADP+-dependent oxidation of short chain aldehydes to their corresponding acids. We have determined the crystal structure of the C-terminal domain of FDH and its complexes with oxidized and reduced forms of NADP. Compared to other members of the ALDH family, FDH demonstrates a new mode of binding of the 2'-phosphate group of NADP via a water-mediated contact with Gln600 that may contribute to the specificity of the enzyme for NADP over NAD. The structures also suggest how Glu673 can act as a general base in both acylation and deacylation steps of the reaction. In the apo structure, the general base Glu673 is positioned optimally for proton abstraction from the sulfur atom of Cys707. Upon binding of NADP+, the side chain of Glu673 is displaced from the active site by the nicotinamide ring and contacts a chain of highly ordered water molecules that may represent a pathway for translocation of the abstracted proton from Glu673 to the solvent. When reduced, the nicotinamide ring of NADP is displaced from the active site, restoring the contact between Cys707 and Glu673 and allowing the latter to activate the hydrolytic water molecule in deacylation.     

Molecular basis for the transfer of nicotinamide adenine dinucleotide among dehydrogenases

NADH is transferred directly from one dehydrogenase enzyme site to another without intervention of the aqueous solvent whenever the two dehydrogenases are of opposite chiral specificity as regards the C4 H of NADH which is transferred in the catalyzed reduction reaction. When both enzymes catalyze the transfer of hydrogen from the same face of the nicotinamide ring, direct enzyme-enzyme transfer of NADH is not possible [Srivastava, D. K., & Bernhard, S. A. (1984) Biochemistry 23, 4538-4545; Srivastava, D. K., & Bernhard, S. A. (1985) Biochemistry (preceding paper in this issue)]. Utilizing an advanced computer graphics facility, and the known three-dimensional coordinates for three dehydrogenases, we have investigated the feasibility of various aspects of the direct transfer of dinucleotide from the site of one enzyme to the site of the other. The facile passage of the coenzyme through the first enzyme site requires an open protein conformation, characteristic of the apoenzyme rather than the holoenzyme structure. Since two dehydrogenases of the same chirality bind coenzyme in the same conformation, the direct transfer of coenzyme from one site to the other is impossible due to the restriction in molecular rotation of the coenzyme in the path of transfer from one binding site to the other; therefore, coenzyme can only be transferred from one dehydrogenase site to another site via the intermediate dissociation of coenzyme into the aqueous milieu. In contrast, when an A dehydrogenase and a B dehydrogenase are juxtaposed, it is stereochemically feasible to transfer the nicotinamide ring from its specific binding site in one enzyme to the site in the other.(ABSTRACT TRUNCATED AT 250 WORDS)     

Escherichia coli formate dehydrogenase mutants with altered selenopolymer profiles

Four classes of Escherichia coli mutants deficient in either or both of their anaerobic selenium-containing formate dehydrogenases (FDH) were isolated. A class I mutant devoid of FDH_H activity specifically linked to benzyl viologen (BV) produced a small amount of the FDH_H 80,000 dalton selenopeptide. Three class II mutants were deficient in FDH_N activity specifically linked to phenazine methosulfate (PMS) and exhibited a selenopeptide doublet rather than the FDH_N 110,000 dalton selenosubunit. Three class III mutants were selenium incorporation deficient and did not exhibit either FDH activity or ⁷⁵Selabeled selenopolymers. A class IV mutant was devoid of PMS-linked FDH_N activity; neither its FDH_N 110,000 dalton selenosubunit nor its BV-linked FDH_H activity was fully regulated by nitrate.Abbreviations FDH formate dehydrogenase - BV benzyl viologen - MV methyl viologen - PMS phenazine methosulfate - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

<Emphasis Type="Italic"> Cis</Emphasis>-acting elements sufficient for induction of<Emphasis Type="Italic"> FDH1</Emphasis> expression by formate in the methylotrophic yeast<Emphasis Type="Italic"> Candida boidinii</Emphasis>

The FDH1 gene of Candida boidinii encodes an NAD⁺-dependent formate dehydrogenase, which catalyzes the last reaction in the methanol dissimilation pathway. FDH1 expression is strongly induced by methanol, as are the promoters of the genes AOD1 (alcohol oxidase) and DAS1 (dihydroxyacetone synthase). FDH1 expression can be induced by formate when cells are grown on a medium containing glucose as a carbon source, whereas expression of AOD1 and DAS1 is completely repressed in the presence of glucose. Using deletion analyses, we identified two cis-acting regulatory elements, termed UAS-FM and UAS-M, respectively, in the 5 non-coding region of the FDH1 gene. Both elements were necessary for full induction of the FDH1 promoter by methanol, while only the UAS-FM element was required for full induction by formate. Irrespective of whether induction was achieved with methanol or formate, the UAS-FM element enhanced the level of induction of the FDH1 promoter in a manner dependent on the number of copies, but independent of their orientation, and also converted the ACT1 promoter from a constitutive into an inducible element. Our results not only provide a powerful promoter for heterologous gene expression, but also yield insights into the mechanism of regulation of FDH1 expression at the molecular level.Communicated by C. P. Hollenberg     

Site-directed mutagenesis of the essential arginine of the formate dehydrogenase active centre

Sequence alignment shows that residue Arg 284 (according to the numbering of the residues in formate dehydrogenase, FDH, from the methylotrophic bacterium Pseudomonas sp. 101) is conserved in NAD-dependent FDHs and D-specific 2-hydroxyacid dehydrogenases. Mutation of Arg 284 to glutamine and alanine results in a change of the catalytic, thermodynamic and spectral properties of FDH. In comparison to wild-type, the affinity of the mutants for the substrate (K(formate)m) or the transition state analogue (K(azide)i) decreases and correlates with the ability of the side chain of residue 284 to form H-bonds. In contrast, the affinity for the coenzyme (K(NAD)d or K(NAD)m) is either not affected or increases and correlates inversely with the partial positive charge of the side chain. The temperature dependence of circular dichroism (CD) spectra of the wild-type FDH and its Ala mutant has been studied over the 5-90 degrees C temperature range. Both proteins reveal regions of enhanced conformational mobility at the predenaturing temperatures (40-55 degrees C) associated with a change of enzyme kinetic parameters and a co-operative transition around 55-70 degrees C which is followed by the loss of enzyme activity. CD spectra of the wild-type and mutant proteins were deconvoluted and contributions from various types of secondary structure estimated. It is shown that the co-operative transition at 55-70 degrees C in the FDH protein globule is triggered by a loss of alpha-helical secondary structure. The results confirm the conclusion, from the crystal structures, that Arg 284 is directly involved in substrate binding. In addition this residue seems to exert a major structural role by supporting the catalytic conformation of the enzyme active centre.