The response of the different soybean metallothionein isoforms to cadmium intoxication

Cadmium is a highly toxic heavy metal for both plants and animals. The presence of Cd in agricultural soils is of major concern regarding its entry into the food chain, since Cd compounds are readily taken up by plants, and accumulated in edible parts due to their high solubility. In this study, we first demonstrate the high capacity for Cd concentration of soybean grains. Consequently, we considered the study and characterization of the molecular determinants of Cd accumulation -such as metallothioneins (MT)- to be of major practical importance. We report here the first characterization of the soybean MT system, with the identification of nine genes (one of which is a truncated pseudogene), belonging to the four plant MT types. The most highly expressed of each type was chosen for further function analysis. All of them are expressed at high levels in soybean tissues: GmMT1, GmMT2 and GmMT3 in roots, shoots and seeds, and GmMT4 only in seeds. The corresponding recombinant soybean MTs, synthesized in Escherichia coli cells cultured in metal supplemented media, exhibit greater cadmium than zinc binding capacity. These results suggest a definite role of GmMTs in Cd(II) accumulation as one of the main responses of soybean to an overload of this metal.

Well ordered crystals of a short-chain alcohol dehydrogenase from Drosophila lebanonensis: re-evaluation of the crystallographic data and rotation-function analysis

Alcohol dehydrogenase prepared from Drosophila lebanonensis yields well ordered plate-like crystals which diffract to better than 2.3 A resolution. The crystals belong to space group P2(1) of the monoclinic system; the unit-cell dimensions are a = 65.25, b = 55.77, c = 70.02 A, alpha = 90, beta = 107.08, gamma = 90 degrees. The asymmetric unit of the crystal cell is most probably occupied by a dimer, corresponding to a packing density of 2.15 A(3) Da-L. The orientation of the non-crystallographic twofold symmetry axes is determined by analysis of a self-rotation function calculated with native intensity data.

MTO: the second member of a Drosophila dual copper-thionein system

Drosophila MTO metal binding features were analyzed for comparison with MTN, the paralogous Drosophila metallothionein, and to classify MTO as either zinc- or copper-thionein. This was achieved by a combination of in vivo, in vitro and in silico methodologies. All the results unambiguously classified MTO as a second Drosophila copper-thionein, putting Drosophila forward as the only metazoan in which any zinc-thionein has still to be reported. Interestingly, experimental data only showed minor differences in the coordinative behavior of both MTs, but provided a characteristic spectroscopic fingerprint, revealing the possible binding of chloride anions in certain metal-MTO aggregates.

Zinc(II) is required for the in vivo and in vitro folding of mouse copper metallothionein in two domains

We postulate that zinc(II) is a keystone in the structure of physiological mouse copper metallothionein 1 (Cu-MT 1). Only when Zn(II) is coordinated does the structure of the in vivo- and in vitro-conformed Cu-MT species consist of two additive domains. Therefore, the functionally active forms of the mammalian Cu-MT may rely upon a two-domain structure. The in vitro behaviour of the whole protein is deduced from the Cu titration of the apo and Zn-containing forms and compared with that of the independent fragments using CD, UV-vis, ESI-MS and ICP-AES. We propose the formation of the following Cu, Zn-MT species during Zn/Cu replacement in Zn7-MT: (Zn4)alpha(Cu4Zn1)beta-MT, (Cu3Zn2)alpha(Cu4Zn1)beta-MT and (Cu4Zn1)alpha(Cu6)beta-MT. The cooperative formation of (Cu3Zn2)alpha(Cu4Zn1)beta-MT from (Zn4)alpha(Cu4Zn1)beta-MT indicates that the preference of Cu(I) for binding to the beta domain is only partial and not absolute, as otherwise accepted. Homometallic Cu-MT species have been obtained either from the apoform of MT or from Zn7-MT after total replacement of zinc. In these species, copper distribution cannot be inferred from the sum of the independent alpha and beta fragments. The in vivo synthesis of the entire MT in Cu-supplemented media has afforded Cu7Zn3-MT [(Cu3Zn2)alpha(Cu4Zn1)beta-MT], while that of alpha MT has rendered a mixture of Cu4Zn1-alpha MT (40%), Cu5Zn1-alpha MT (20%) and Cu7-alpha MT (40%). In the case of beta MT, a mixture of Cu6-beta MT (25%) and Cu7-beta MT (75%) was recovered [1]. These species correspond to some of those conformed in vitro and confirm that Zn(II) is essential for the in vivo folding of Cu-MT in a Cu-rich environment. A final significant issue is that common procedures used to obtain mammalian Cu6-beta MT from native sources may not be adequate.

Secretion of mouse-metallothionein by engineered E. coli cells in metal-enriched culture media

Heterologous Escherichia coli expression systems were designed and assayed for the synthesis of functional mouse metallothionein (MT) as a secreted fusion protein. MT secretion was compared among different systems, and the optimum vector/host/medium combination was tested for metal removal. In this case, the Cu content of the medium decreased by up to 34% after growth of recombinant bacteria. The potential use of these genetically-engineered bacteria for water bioremediation is discussed as an alternative to cytoplasmic MT or membrane-bound MT heterologous expression systems.

A new insight into metallothionein (MT) classification and evolution. The in vivo and in vitro metal binding features of Homarus americanus recombinant MT

We report the synthesis and characterization of a Homarus americanus MT-cDNA (MTH) through retrotranscription of MTH-mRNA from metal-injected lobsters. Heterologous Escherichia coli expression in zinc- and copper-supplemented medium was achieved for MTH, the two domains betabetaMTH and betaalphaMTH and three site-directed mutants, betabetaC9H, betaalphaC37H, and betaalphaE31C/T34C. The in vivo conformed metal complexes and the in vitro substituted cadmium aggregates were characterized. Major stoichiometries of M(II)6-MTH for the entire MTH and M(II)3-betabetaMTH and M(II)3-betaalphaMTH for the independent domains fully validated our expression system. A low affinity binding site for a seventh Zn(II) in the in vivo synthesized MTH was located in the betaalpha domain. Additionally, minor M(II)4 species were found for each domain. Both single Cys to His mutations exhibited a similar reduction of their in vivo zinc binding ability but differed in their cadmium binding behavior when compared with the wild-type forms. Conversely, the double mutant showed an enhanced zinc and cadmium binding capacity. In vivo synthesis of MTH and of its independent domains in the presence of copper only afforded heterometallic copper-zinc species. These findings allow consideration of MTH as a zinc thionein and question the view of all crustacea MT structures as copper thioneins. Furthermore, a new approach for the evolutionary and functional classification of MT is proposed, based on the stoichiometry of metal-MT species and molecular phylogenetic analysis.

Genesis of Drosophila ADH: the shaping of the enzymatic activity from a SDR ancestor

Drosophila alcohol dehydrogenase (ADH) is an NAD(H)-dependent oxidoreductase that catalyzes the oxidation of alcohols and aldehydes. Structurally and biochemically distinct from all the reported ADHs (typically, the mammalian medium-chain dehydrogenase/reductase-ethanol-metabolizing enzyme), it stands as the only small-alcohol transforming system that has originated from a short-chain dehydrogenase/reductase (SDR) ancestor. The crystal structures of the apo, binary (E.NAD(+)) and three ternary (E.NAD(+).acetone, E.NAD(+).3-pentanone and E.NAD(+).cyclohexanone) forms of Drosophila lebanonensis ADH have allowed us to infer the structural and kinetic features accounting for the generation of the ADH activity within the SDR lineage.

Engineering a mouse metallothionein on the cell surface of Ralstonia eutropha CH34 for immobilization of heavy metals in soil

Here we describe targeting of the mouse metallothionein I (MT) protein to the cell surface of the heavy metal-tolerant Ralstonia eutropha (formerly Alcaligenes eutrophus) CH34 strain, which is adapted to thrive in soils highly polluted with metal ions. DNA sequences encoding MT were fused to the autotransporter beta-domain of the IgA protease of Neisseria gonorrhoeae, which targeted the hybrid protein toward the bacterial outer membrane. The translocation, surface display, and functionality of the chimeric MTbeta protein was initially demonstrated in Escherichia coli before the transfer of its encoding gene (mtb) to R. eutropha. The resulting bacterial strain, named R. eutropha MTB, was found to have an enhanced ability for immobilizing Cd2+ ions from the external media. Furthermore, the inoculation of Cd2+-polluted soil with R. eutropha MTB decreased significantly the toxic effects of the heavy metal on the growth of tobacco plants (Nicotiana bentamiana).

Structure-function relationships in Drosophila melanogaster alcohol dehydrogenase allozymes ADH(S), ADH(F) and ADH(UF), and distantly related forms

Drosophila melanogaster alcohol dehydrogenase (ADH), a paradigm for gene-enzyme molecular evolution and natural selection studies, presents three main alleloforms (ADHS, ADHF and ADHUF) differing by one or two substitutions that render different biochemical properties to the allelozymes. A three-dimensional molecular model of the three allozymes was built by homology modeling using as a template the available crystal structure of the orthologous D. lebanonensis ADH, which shares a sequence identity of 82.2%. Comparison between D. lebanonensis and D. melanogaster structures showed that there is almost no amino-acid change near the substrate or coenzyme binding sites and that the hydrophobic active site cavity is strictly conserved. Nevertheless, substitutions are not distributed at random in nonconstricted positions, or located in external loops, but they appear clustered mainly in secondary structure elements. From comparisons between D. melanogaster allozymes and with D. simulans, a very closely related species, a model based on changes in the electrostatic potential distribution is presented to explain their differential behavior. The depth of knowledge on Drosophila ADH genetics and kinetics, together with the recently obtained structural information, could provide a better understanding of the mechanisms underlying molecular evolution and population genetics.

Engineering outer-membrane proteins in Pseudomonas putida for enhanced heavy-metal bioadsorption

Metallothioneins (MTs) are small, cysteine-rich proteins with a strong metal-binding capacity that are ubiquitous in the animal kingdom. Recombinant expression of MT fused to outer-membrane components of gram-negative bacteria may provide new methods to treat heavy-metal pollution in industrial sewage. In this work, we have engineered Pseudomonas putida, a per se highly robust microorganism able to grow in highly contaminated habitats in order to further increase its metal-chelating ability. We report the expression of a hybrid protein between mouse MT and the beta domain of the IgA protease of Neisseria in the outer membrane of Pseudomonas cells. The metal-binding capacity of such cells was increased three-fold. The autotranslocating capacity of the beta domain of the IgA protease of Neisseria, as well as the correct anchoring of the transported protein into the outer membrane, have been demonstrated for the first time in a member of the Pseudomonas genus.

Drosophila MTN: a metazoan copper-thionein related to fungal forms

Two Drosophila metallothioneins (MT) have been reported: MTN, a 40 residue peptide including 10 Cys, and MTO, a 43 residue peptide including 12 Cys. However, neither functional nor evolutionary analyses for either of the Drosophila MT are available. Here, heterologous expression of Mtn in Escherichia coli is reported. The metal binding abilities of the Cu- and Zn-MTN complexes conformed in vivo, as well as the features of the Cd- and Cu-aggregates produced by metal replacement in vitro, have been determined by atomic emission spectrometry, circular dichroism and electrospray ionization mass spectrometry. Primary structure relationships with other MT have been examined. The results indicate a close resemblance of MTN to fungal copper-thioneins.

The catalytic reaction and inhibition mechanism of Drosophila alcohol dehydrogenase: observation of an enzyme-bound NAD-ketone adduct at 1.4 A resolution by X-ray crystallography

Drosophila alcohol dehydrogenase (DADH) is an NAD+-dependent enzyme that catalyzes the oxidation of alcohols to aldehydes/ketones. DADH is the member of the short-chain dehydrogenases/reductases family (SDR) for which the largest amount of biochemical data has been gathered during the last three decades. The crystal structures of one binary form (NAD+) and three ternary complexes with NAD+.acetone, NAD+.3-pentanone and NAD+.cyclohexanone were solved at 2.4, 2.2, 1. 4 and 1.6 A resolution, respectively. From the molecular interactions observed, the reaction mechanism could be inferred. The structure of DADH undergoes a conformational change in order to bind the coenzyme. Furthermore, upon binding of the ketone, a region that was disordered in the apo form (186-191) gets stabilized and closes the active site cavity by creating either a small helix (NAD+. acetone, NAD+.3-pentanone) or an ordered loop (NAD+.cyclohexanone). The active site pocket comprises a hydrophobic bifurcated cavity which explains why the enzyme is more efficient in oxidizing secondary aliphatic alcohols (preferably R form) than primary ones. Difference Fourier maps showed that the ketone inhibitor molecule has undergone a covalent reaction with the coenzyme in all three ternary complexes. Due to the presence of the positively charged ring of the coenzyme (NAD+) and the residue Lys155, the amino acid Tyr151 is in its deprotonated (tyrosinate) state at physiological pH. Tyr151 can subtract a proton from the enolic form of the ketone and catalyze a nucleophilic attack of the Calphaatom to the C4 position of the coenzyme creating an NAD-ketone adduct. The binding of these NAD-ketone adducts to DADH accounts for the inactivation of the enzyme. The catalytic reaction proceeds in a similar way, involving the same amino acids as in the formation of the NAD-ketone adduct. The p Kavalue of 9-9.5 obtained by kinetic measurements on apo DADH can be assigned to a protonated Tyr151 which is converted to an unprotonated tyrosinate (p Ka7.6) by the influence of the positively charged nicotinamide ring in the binary enzyme-NAD+form. pH independence during the release of NADH from the binary complex enzyme-NADH can be explained by either a lack of electrostatic interaction between the coenzyme and Tyr151 or an apparent p Kavalue for this residue higher than 10.0.

In vivo copper- and cadmium-binding ability of mammalian metallothionein beta domain

The beta domain of mouse metallothionein 1 (betaMT) was synthesized in Escherichia coli cells grown in the presence of copper or cadmium. Homogenous preparations of Cu-betaMT and Cd-betaMT were used to characterize the corresponding in vivo-conformed metal-clusters, and to compare them with the species obtained in vitro by metal replacement to a canonical Zn3-betaMT structure. The copper-containing betaMT clusters formed inside the cells were very stable. In contrast, the nascent beta peptide, although it showed cadmium binding ability, produced a highly unstable species, whose stoichiometry depended upon culture conditions. The absence of betaMT protein in E. coli protease-proficient hosts grown in cadmium-supplemented medium pointed to drastic proteolysis of a poorly folded beta peptide, somehow enhanced by the presence of cadmium. Possible functional and evolutionary implications of the bioactivity of mammalian betaMT in the presence of monovalent and divalent metal ions are discussed.

Replacement of terminal cysteine with histidine in the metallothionein alpha and beta domains maintains its binding capacity

To generate novel forms of metal-binding proteins, six mutant mouse metallothionein (MT) 1 fragments, in which a terminal cysteine residue was replaced by histidine, were expressed in Escherichia coli. The spectroscopic and analytical results showed that the alphaMT (C33H, C36H, C41H, C57H) and betaMT (C5H, C13H) mutant forms bound 4 and 3 Zn(II) atoms per molecule of protein to the nearest integer, even though in C41H and C5H, species of lower stoichiometry were also detected. In Cd(II) titrations, all the Zn(II) ions bound to the mutant proteins were displaced from the binding sites, giving rise to Cd-mutated MT forms with 4 and 3 Cd(II), respectively. However, although Cys-to-His substitutions maintained the binding capacity of the MT fragments, they caused structural changes with respect to the wild-type proteins. While C13H, C36H and C57H seem to contain Zn(II)-aggregates that are closely related to those of the wild-type proteins, only C41H and C57H gave rise to Cd(II)-aggregates similar to those of Cd4-alphaMT, where the His residue plays the role of the substituted Cys. Despite the structural implications of the Cys-to-His replacement, the dissociation constants showed no major decrease in the Cd-binding affinity in any of the mutants assayed compared with the wild-type.

A new insight into the Ag+ and Cu+ binding sites in the metallothionein beta domain

The copper(I) and silver(I) binding properties of the beta fragment of recombinant mouse metallothionein I have been studied by electronic absorption and circular dichroism spectroscopy. When possible, the stoichiometry of the species formed was confirmed by electrospray mass spectrometry. The behaviour observed differs from that reported for the native protein. Titration of either Zn3-beta MT at pH 7 or apo-beta MT at pH 3 with Cu+ leads to the formation of species having the same stoichiometry and structure: Cu6-beta MT, Cu7-beta MT and Cu10-beta MT. In the first stage of the titration of Zn3-beta MT with Cu+ at pH 7 one additional species of formula Cu4Zn1-beta MT was detected. In contrast, the titration of Zn3-beta MT at pH 7.5 and of apo-beta MT at pH 2.5 with Ag+ proceeds through different reaction pathways, affording ZnxAg3-beta MT, Ag6-beta MT and Ag9-beta MT or Ag3-beta MT, Ag6-beta MT and Ag9-beta MT, respectively. The CD envelope corresponding to species with the same stoichiometric ratio, Ag6-beta MT and Ag9-beta MT, indicates that they have a different structure at each pH value. On the basis of the differences observed, the postulated similarity between copper and silver binding to metallothionein may be questioned.

Bioaccumulation of heavy metals with protein fusions of metallothionein to bacterial OMPs

In view of potential biotechnological applications, eukaryotic metallothioneins (MTs) have been expressed in Escherichia coli as fusions to membrane or membrane-associated proteins such as LamB, the peptidoglycan-associated lipoprotein protein (PAL) or a hybrid Lpp/OmpA carrier sequence. The use of different anchors enables the MT moiety to be targeted into various cell compartments thus bringing the metal-binding ability of the resulting hybrids to specific sites of the cell structure. To this end, both full-size and partial sequences of the human or mouse MTs have been genetically fused to: i) the permissive site 153 of the LamB sequence, which loops out the MT to the external medium; ii) the N-terminus of a PAL variant devoid of its N-terminal cystein, which targets expression of the fusion into the periplasm; and iii) the C-terminus of Lpp-OmpA, for anchoring the MT to the outer membrane protein as an N-terminal fusion. Each type of fusion presented a distinct behavior in terms of expression, stability and ability to endow E. coli cells an enhanced accumulation of Cd2+, in good correlation with the number of metal-binding centers contributed by the MT moiety of the fusions. The expression in vivo of metalloproteins bound to bacterial envelope structures opens a way to design biomass with specific metal-binding properties.

The refined crystal structure of Drosophila lebanonensis alcohol dehydrogenase at 1.9 A resolution

Drosophila alcohol dehydrogenase (DADH; EC 1.1.1.1) is a NAD(H)-dependent oxidoreductase belonging to the short-chain dehydrogenases/reductases (SDR) family. This homodimeric enzyme catalyzes the dehydrogenation of alcohols to their respective ketones or aldehydes in the fruit-fly Drosophila, both for metabolic assimilation and detoxification purposes. The crystal structure of the apo form of DADH, one of the first biochemically characterized member of the SDR family, was solved at 1.9 A resolution by Patterson methods. The initial model was improved by crystallographic refinement accompanied by electron density averaging, R-factor=20.5%, R-free=23.8%.DADH subunits show an alpha/beta single domain structure with a characteristic NAD(H) binding motif (Rossmann fold). The peptide chain of a subunit is folded into a central eight-stranded beta-sheet flanked on each side by three alpha-helices. The dimers have local 2-fold symmetry. Dimer association is dominated by a four-helix bundle motif as well as two C-terminal loops from each subunit, which represent a unique structural feature in SDR enzymes with known structure. Three structural features are characteristic for the active site architecture. (1) A deep cavity which is covered by a flexible loop (33 residues) and the C-terminal tail (11 residues) from the neighboring subunit. The hydrophobic surface of the cavity is likely to increase the specificity of this enzyme towards secondary aliphatic alcohols. (2) The residues of the catalytic triad (Ser138, Tyr151, Lys155) are known to be involved in enzymatic catalysis in the first line. The Tyr151 OH group is involved in an ionic bond with the Lys155 side-chain. Preliminary electrostatic calculations have provided evidence that the active form of Tyr151 is a tyrosinate ion at physiological pH. (3) Three well-ordered water molecules in hydrogen bond distance to side-chains of the catalytic triad may be significant for the proton release steps in DADH catalysis.A ternary structure-based sequence alignment with ten members of the SDR family with known three-dimensional structure has suggested to define a model consisting of four groups of residues, which relates the observed low degree of sequence identity to quite similar folding patterns and nearly identical distributions of residues involved in catalysis.

Shaping of Drosophila alcohol dehydrogenase through evolution: relationship with enzyme functionality

Drosophilidae is a large, widely distributed family of Diptera including 61 genera, of which Drosophila is the most representative. Drosophila feeding is part of the saprophytic trophic chain, because of its dependence upon decomposing organic matter. Many species have adapted to fermenting fruit feeding or to artificial (man-made) fermentation habitats, such as cellars and breweries. Actually, the efficient exploitation of niches with alcohols is considered one of the reasons for the worldwide success of this genus. Drosophila alcohol dehydrogenase (ADH), a member of the short-chain dehydrogenase/reductase family (SDR), is responsible for the oxidation of alcohols, but its direct involvement in fitness, including alcohol tolerance and utilization, gives rise to much controversy. Thus, it remains unclear whether ADH differentiation through evolution is somehow associated with natural adaptation to new feeding niches, and thus maybe to Drosophila speciation, or if it is a simple reflection of neutral divergence correlated with time separation between species. To build a hypothesis which could shed light on this dilemma, we analyzed the amino acid variability found in the 57 protein ADH sequences reported up to now, identified the taxon-specific residues, and localized them in a three-dimensional ADH model. Our results define three regions whose shaping has been crucial for ADH differentiation and would be compatible with a contribution of ADH to Drosophila speciation.

Binding of excess cadmium(II) to Cd7-metallothionein from recombinant mouse Zn7-metallothionein 1. UV-VIS absorption and circular dichroism studies and theoretical location approach by surface accessibility analysis

A mouse metallotbionein (MT) 1 expression system has been constructed that renders recombinant MT as a high purity Zn-coordinated protein. Spectral changes in absorption and circular dichroism following the addition of up to 7 mol equivalents of Cd2+ to recombinant Zn7-MT showed that it behaves like the native protein. Exposure of Cd7-MT to Cd2+ resulted in further binding of these ions to the protein, although saturation was not achieved on the addition of up to 22 mol equivalents of Cd2+ to Zn7-MT. Spectral data are compatible with a model in which the first four additional Cd2+ ions are bound to Cd7-MT via sulfur atoms, and indicate that no further thiol groups are involved in the binding of the excess Cd(II) over 11. Cd2+ ions bound in excess to Cd7-MT appear to have lower binding constants as exposure of Cdn-MT (n > 7) species to Cbelex-100 retrieved Cd7-MT. Based on the X-ray data, the accessible surface areas of sulfur atoms in Cd5,Zn2-MT 2 were calculated. This led us to propose that the coordination of the first three additional Cd(II) ions to Cd7-MT proceeds by means of S-Met1-O-Met1, S-Cys7-S-Cys13 and S-Cys5-S-Cys26 pairs. Finally, comparison of the behavior of the entire MT with that of the recombinant alpha MT and beta MT subunits indicates that mutual influences may not be negligible.

Drosophila alcohol dehydrogenase: evaluation of Ser139 site-directed mutants

Drosophila alcohol dehydrogenase (DADH) belongs to the large and highly heterogeneous (15-30% residue identity) short-chain dehydrogenase/reductase family (SDR). It is the only reported member that oxidizes mainly ethanol and 2-propanol among other alcohols. To confirm the role of Ser139 we constructed two site-directed mutants, Ser139Ala and Ser139Cys, which show no enzymatic activity. Molecular replacement and data from crystallographically refined 3D structures confirm the position of Ser139, whose hydroxyl group faces the cleft of the presumed catalytic pocket, very close to Tyr152 and Lys156. Thus, consistent with the constitution of the catalytic triad of other SDR, our results suggest that Ser139 of DADH is directly involved in the catalytic reaction.

Recombinant synthesis of mouse Zn3-beta and Zn4-alpha metallothionein 1 domains and characterization of their cadmium(II) binding capacity

Genetic engineering, coupled with spectroscopic analyses, has enabled the metal binding properties of the alpha and beta subunits of mouse metallothionein 1 (MT) to be characterized. A heterologous expression system in E.coli has led to high yields of their pure zinc-complexed forms. The cadmium(II) binding properties of recombinant Zn4-alpha MT and Zn3-beta MT have been studied by electronic absorption and circular dichroism. The former binds Cd(II) identically to alpha fragments obtained from mammalian organs, showing that the recombinant polypeptide behaves like the native protein. Titration of Zn3-beta MT with CdCl2 results in the formation of Cd3-beta MT. The addition of excess Cd(II) leads to Cd4-beta MT which, with the extra loading of Cd(II), unravels to give rise isodichroically to Cd9-beta MT. The effect of cadmium-displaced Zn(II) ions and excess Cd(II) above the full metal occupancy of three has been studied using Chelex-100. The Cd3-beta MT species is stable in the presence of this strong metal-chelating agent.

Involvement of the C-terminal tail in the activity of Drosophila alcohol dehydrogenase. Evaluation of truncated proteins constructed by site-directed mutagenesis

Drosophila alcohol dehydrogenase belongs to the heterogeneous family of short-chain dehydrogenases/reductases, which does not include the well characterized mammalian alcohol dehydrogenases. Although it is clear that the main biological role of this enzyme is in alcohol oxidation, in the absence of the three-dimensional conformation only partial information on the protein regions involved in the active site, and the coenzyme and substrate interacting cavities is available. Two segments have already been identified, a coenzyme-binding segment at the N-terminus, and the reactive Tyr152 and Lys156 residues. Limited proteolytic assays had suggested the involvement of the 13 C-terminal amino acids in the function of the enzyme. By site-directed mutagenesis, we have constructed eight different truncated mutant enzymes and expressed them in Escherichia coli. The purified mutant enzymes have been recovered and characterized using monoclonal antibodies. Kinetic analysis and stability assays have been performed, and clearly demonstrate the contribution of the last 13 amino acids to the activity. We hypothesize that the C-terminal tail constitutes an essential region for maintaining the hydrophobicity of the catalytic pocket needed for binding of the substrate.

Short-chain dehydrogenases/reductases (SDR)

Short-chain dehydrogenases/reductases (SDR) constitute a large protein family. Presently, at least 57 characterized, highly different enzymes belong to this family and typically exhibit residue identities only at the 15-30% level, indicating early duplicatory origins and extensive divergence. In addition, another family of 22 enzymes with extended protein chains exhibits part-chain SDR relationships and represents enzymes of no less than three EC classes. Furthermore, subforms and species variants are known of both families. In the combined SDR superfamily, only one residue is strictly conserved and ascribed a crucial enzymatic function (Tyr 151 in the numbering system of human NAD(+)-linked prostaglandin dehydrogenase). Such a function for this Tyr residue in SDR enzymes in general is supported also by chemical modifications, site-directed mutagenesis, and an active site position in those tertiary structures that have been characterized. A lysine residue four residues downstream is also largely conserved. A model for catalysis is available on the basis of these two residues. Binding of the coenzyme, NAD(H) or NADP(H), is in the N-terminal part of the molecules, where a common GlyXXXGlyXGly pattern occurs. Two SDR enzymes established by X-ray crystallography show a one-domain subunit with seven to eight beta-strands. Conformational patterns are highly similar, except for variations in the C-terminal parts. Additional structures occur in the family with extended chains. Some of the SDR molecules are known under more than one name, and one of the enzymes has been shown to be susceptible to native, chemical modification, producing reduced Schiff base adducts with pyruvate and other metabolic keto derivatives. Most SDR enzymes are dimers and tetramers. In those analyzed, the area of major subunit contacts involves two long alpha-helices (alpha E, alpha F) in similar and apparently strong subunit interactions. Future possibilities include verification of the proposed reaction mechanism and tracing of additional relationships, perhaps also with other protein families. Short-chain dehydrogenases illustrate the value of comparisons and diversified research in generating unexpected discoveries.

Structure of the Drosophila melanogaster glutathione-dependent formaldehyde dehydrogenase/octanol dehydrogenase gene (class III alcohol dehydrogenase). Evolutionary pathway of the alcohol dehydrogenase genes

The glutathione-dependent formaldehyde dehydrogenase gene (gfd) of Drosophila melanogaster encodes an enzyme that is active toward S-hydroxymethylglutathione, an adduct of formaldehyde with glutathione, and also with long-chain primary alcohols, both properties typical of class III alcohol dehydrogenases, gfd hybridizes at the 86D division of the third chromosome, in agreement with the known location of the Drosophila octanol dehydrogenase gene (odh), gfd/odh was isolated from a lambda EMBL-4 genomic library and consists of three exons (with coding segments of 21, 90 and 1029 bp) and two introns (69 bp and 70 bp, respectively). The introns are small in size like the Drosophila interrupting sequences and are located at the 5' end of the coding region. Comparisons with the homologous genes of Saccharomyces, Candida and humans provide information on the evolution of the class III alcohol dehydrogenases. Moreover, results from analysis of exon/intron distributions in eleven dehydrogenases are compatible with the hypothesis of intron loss accounting for aspects of the present structure of these genes.

Fundamental molecular differences between alcohol dehydrogenase classes

Two types of alcohol dehydrogenase in separate protein families are the "medium-chain" zinc enzymes (including the classical liver and yeast forms) and the "short-chain" enzymes (including the insect form). Although the medium-chain family has been characterized in prokaryotes and many eukaryotes (fungi, plants, cephalopods, and vertebrates), insects have seemed to possess only the short-chain enzyme. We have now also characterized a medium-chain alcohol dehydrogenase in Drosophila. The enzyme is identical to insect octanol dehydrogenase. It is a typical class III alcohol dehydrogenase, similar to the corresponding human form (70% residue identity), with mostly the same residues involved in substrate and coenzyme interactions. Changes that do occur are conservative, but Phe-51 is of functional interest in relation to decreased coenzyme binding and increased overall activity. Extra residues versus the human enzyme near position 250 affect the coenzyme-binding domain. Enzymatic properties are similar--i.e., very low activity toward ethanol (Km beyond measurement) and high selectivity for formaldehyde/glutathione (S-hydroxymethylglutathione; kcat/Km = 160,000 min-1.mM-1). Between the present class III and the ethanol-active class I enzymes, however, patterns of variability differ greatly, highlighting fundamentally separate molecular properties of these two alcohol dehydrogenases, with class III resembling enzymes in general and class I showing high variation. The gene coding for the Drosophila class III enzyme produces an mRNA of about 1.36 kb that is present at all developmental stages of the fly, compatible with the constitutive nature of the vertebrate enzyme. Taken together, the results bridge a previously apparent gap in the distribution of medium-chain alcohol dehydrogenases and establish a strictly conserved class III enzyme, consistent with an important role for this enzyme in cellular metabolism.

Drosophila lebanonensis ADH: analysis of recombinant wild-type enzyme and site-directed mutants. The effect of restoring the consensus sequence in two positions

Unique amino acid substitutions occur in D. lebanonensis ADH. They are found within the putative NAD(+)-binding domain and affect residues that are otherwise highly conserved in all other species of the genus. To restore the consensus amino acids, we have constructed an expression system for this enzyme in E. coli, and engineered two mutants, Ala13Gly and Asn56Thr. The biochemical and kinetic features of these retromutants are consistent with increased catalytic efficiency and thermal stability. Thus, results show that wild-type D. lebanonensis ADH can be improved by site-directed mutagenesis.

Effect of site-directed mutagenesis on conserved positions of Drosophila alcohol dehydrogenase

Tyr152 and Lys156 may be functionally important residues in Drosophila ADH as they are conserved in the genus and in all short-chain dehydrogenases. In addition, unaltered Gly positions could have a crucial role in the building of the structural framework. We have modified Drosophila ADH and expressed the mutant forms in E. coli. Mutation of Tyr152 to Glu or Gln, Lys156 to Ile, Gly184 to Leu, and the double mutant Gly130 to Cys and Gly133 to Ile, all rendered, with different substrates and at different pHs, an inactive enzyme. Results suggest that Tyr152 and Lys156 are involved in catalysis and that Gly130, Gly133 and Gly184 contribute substantially to the structure of the active form.

Evidence of serine-protease activity closely associated with Drosophila alcohol dehydrogenase

With the use of monoclonal antibodies against alcohol dehydrogenase (ADH) we detected ADH proteolysis in different Drosophila melanogaster tissues during development [Visa, N., Fiblas, J., Santa-Crus, M. C. & Gonzàlez-Duarte R. (1992) J. Histochem. Cytochem. 40, 39-49]. We now report the analysis of this proteolytic activity in crude homogenates and in purified ADH preparations of several Drosophila species. Our results indicate that in non-denaturing IEF gels the proteolytic activity comigrates with native ADH electromorphs of all the species analyzed. In addition, we show that it copurifies with ADH and is responsible for the instability of apparently homogeneous ADH preparations in the presence of SDS. When purified ADH preparations were analyzed, the endogenous proteolytic activity yielded the same banding pattern as that obtained with crude homogenates. Even after rechromatography on Sephacryl S-200, the usual last step in our standard purification protocol, the proteolytic activity remained associated with the ADH fractions. Among the various agents which could explain the ADH-linked proteolytic effect, a pre-existing nicked state of the enzyme or chemical proteolysis have been ruled out. The kinetics observed on pure ADH preparations, the effect of specific protease inhibitors and substrate specificity have led us to ascribe this activity to the subtilase serine-protease family. Given that proteolysis is evident even in rechromatographed Sephacryl S-200 fractions, if incubated in SDS for enough time, we propose two alternative hypotheses to explain this phenomenon. First, the proteolytic activity may come from a protease which is inseparable from the ADH active forms and second, the ADH itself may behave as a subtilase when it adopts a particular conformation. Moreover, the previously reported differential banding pattern during development suggests a role for this activity in vivo, in which fatty acids could produce the inducer effect attributed to SDS in vitro.

Short-chain dehydrogenases. Proteolysis and chemical modification of prokaryotic 3 alpha/20 beta-hydroxysteroid, insect alcohol and human 15-hydroxyprostaglandin dehydrogenases

Prokaryotic 3 alpha/20 beta-hydroxysteroid dehydrogenase exhibits one segment sensitive to proteolysis with Glu-C protease and trypsin (cleaving after Glu192 and Arg196, respectively). Cleavage is associated with dehydrogenase inactivation; the presence of NADH offers almost complete protection and substrate (cortisone) gives some protection. Distantly related insect alcohol dehydrogenase is more resistant to proteolysis, but cleavage in a corresponding segment is detectable with Asp-N protease (cleaving before Asp198), while a second site (at Glu243) is sensitive to cleavage with both Glu-C and Asp-N proteases. Combined, the results suggest the presence of limited regions especially sensitive to proteolysis and the possibility of some association between the enzyme active site and the sensitive site(s). Modification of the hydroxysteroid dehydrogenase with tetranitromethane is paralleled by enzyme inactivation. With a 10-fold excess of reagent, labeling corresponds to 1.2 nmol Tyr/nmol protein chain and is recovered largely in Tyr152, with lesser amounts in Tyr251. Tetranitromethane also rapidly inhibits the other two dehydrogenases, but they contain Cys residues, preventing direct correlation with Tyr modification. Together, the proteolysis and chemical modifications highlight three segments of short-chain dehydrogenase subunits, one mid-chain, containing Tyr152 of the steroid dehydrogenase (similar numbers in the other enzymes), strictly conserved and apparently close to the enzyme active site, the other around position 195, sensitive to proteolysis and affected by coenzyme binding, while the third is close to the C-terminus.

Preliminary X-ray crystallographic studies on alcohol dehydrogenase from Drosophila

The alcohol dehydrogenase (ADHase) enzyme catalyses the oxidation of alcohols to aldehydes or ketones using NAD+ as a cofactor. Functional ADHase from Drosophila lebanonensis is a dimer, with a monomeric molecular weight of 27,000 and with 254 residues in each polypeptide chain. Crystals of the protein have been grown with and without NAD+. Two crystal forms have been observed. Most crystals are plate-like, 0.05 mm in their shortest dimension and up to 0.4 mm in their longest dimension. These crystals are generally too small to diffract efficiently using conventional X-ray sources, so preliminary studies were carried out using the Synchrotron Radiation Source at the SERC Daresbury Laboratory. Twinning was a severe problem with this crystal form. The second form is grown in the absence of NAD+ but with DL-dithiothreitol present. These crystals grow more evenly and diffract to better than 2 A resolution. They are monoclinic, with cell dimensions, a = 81.24(6) A, b = 55.75(4) A, c = 109.60(7) A and beta = 94.26(9) degrees, space group P2(1). There are two dimers in the asymmetric unit, but at low resolution a rotated cell with one dimer per asymmetric unit can be obtained.

Protein engineering of Drosophila alcohol dehydrogenase. The hydroxyl group of Tyr152 is involved in the active site of the enzyme

Drosophila alcohol dehydrogenase is the most studied member of the family of short-chain alcohol dehydrogenases, although its tridimensional structure still remains unknown. We have engineered a Drosophila alcohol dehydrogenase in which tyrosine-152, an invariant residue in all members of the family, has been substituted by phenylalanine. The mutated gene has been expressed in yeast and pure mutant enzyme has been prepared by a one-step FPLC chromatographic procedure. Drosophila alcohol dehydrogenase-phenylalanine-152 shows no enzymatic activity. This result suggests not only that tyrosine-152 could constitute an essential building block of the active site but also that its hydroxyl group is directly involved in the redox reaction catalyzed by the enzyme.

Identification of reactive tyrosine residues in cysteine-reactive dehydrogenases. Differences between liver sorbitol, liver alcohol and Drosophila alcohol dehydrogenases

Modification of tyrosine residues with tetranitromethane and reversible sulphite protection of cysteine residues were tested on three dehydrogenases of two families. In liver alcohol dehydrogenase no Tyr residue is appreciably labelled, while in the homologous sorbitol dehydrogenase Tyr-109 is specifically labelled; the difference corresponds to a segment correlating with subunit interactions and the different quaternary structures of the proteins. In Drosophila alcohol dehydrogenase, Tyr modification is multiple, and the results show the presence of two different states of Cys residues, reactive in the presence and absence of cupric ions, respectively. Super-activation with cyanide was also noticed after S-sulphocysteine protection. The results demonstrate the possibility of identification of specific Tyr residues in proteins with reversibly protected Cys residues.

Structural properties of long- and short-chain alcohol dehydrogenases. Contribution of NAD+ to stability

Structural studies were undertaken on long-chain and short-chain alcohol dehydrogenases (from horse liver and Drosophila respectively). Far-u.v. c.d. measurements were used to estimate the secondary structure contents of the enzymes. For the horse liver enzyme, the results agree well with the X-ray data; for the Drosophila enzyme (for which a crystal structure is not yet available), the results are in good agreement with those obtained by applying a range of structure-prediction procedures to the amino acid sequence of this enzyme. The conformational stabilities of the two enzymes were investigated by studying the unfolding brought about by guanidinium chloride (GdnHCl) by using activity and c.d. measurements. The unfolding of the Drosophila enzyme was analysed in terms of a two-state model; the presence of the substrate NAD+ leads to considerable protection against unfolding. By contrast, the unfolding of the horse liver enzyme shows a plateau effect at intermediate concentrations of GdnHCl, indicating that a two-state model is not appropriate in this case. NAD+ affords little, if any, protection against unfolding for the horse liver enzyme.

The Adh in Drosophila: chromosomal location and restriction analysis in species with different phylogenetic relationships

Restriction analysis of the genomic region containing the Adh gene and in situ hybridization assays were performed in six Drosophila species belonging to three different subgenera: D. ambigua, D. subobscura, D. madeirensis and D. guanche (sg. Sophophora); D. immigrans (sg. Drosophila); and D. lebanonensis (sg. Pholadoris). In agreement with previous observations, comparison of restriction maps of the Adh region shows that D. subobscura and D. madeirensis are very closely related. Partial homology is also observed with the rest of the obscura group species. Nevertheless, no resemblance at the restriction map level is detected when more distantly related species are compared. In D. ambigua, D. immigrans and D. lebanonensis in situ hybridization assays reveal a single chromosomal location for Adh, which in D. lebanonensis appears to be sex linked. In contrast, in D. subobscura, D. madeirensis and D. guanche multiple sites of hybridization with homologous and heterologous probes are observed. For example, in D. subobscura and D. madeirensis the functional Adh gene is located on the U chromosome and additional homologous retrosequences are found on the E chromosome.

Synthesis of Drosophila melanogaster alcohol dehydrogenase in yeast

Expression systems for the heterologous expression of Drosophila melanogaster alcohol dehydrogenase (ADH) in Saccharomyces cerevisiae have been designed, analyzed and compared. Four different yeast/Escherichia coli shuttle vectors were constructed and used to transform four different yeast strains. Expression was detectable in ADH- yeast strains, from either a constitutive promoter, yeast ADH1 promoter (ADCp), or a regulated promoter, yeast GALp. The highest amount of D. melanogaster ADH was obtained from a multicopy plasmid with the D. melanogaster Adh gene expressed constitutively under the control of yeast ADCp promoter. The D. melanogaster enzyme was produced in cell extracts, as assessed by Coomassie blue staining and Western blotting after polyacrylamide-gel electrophoresis and it was fully active and able to complement the yeast ADH deficiency. Results show that D. melanogaster ADH subunits synthesized in yeast are able to assemble into functional dimeric forms. The synthesized D. melanogaster ADH represents up to 3.5% of the total extracted yeast protein.

Purification and molecular characterization of alcohol dehydrogenase from Drosophila hydei: conservation in the biochemical features of the enzyme in several species of Drosophila

Alcohol dehydrogenase (ADH) has been purified from Drosophila hydei. Biochemical investigations show that the native enzyme is a dimer consisting of two identical subunits with molecular weight 27,000. The pH optimum values of pure enzyme preparations are 7.9 and 9.4. The pI values are 8.83 and 8.41. Substrate specificities have been characterized. Km(app) values are lowest for propan-2-ol and butan-2-ol and Vmax(app) values are highest for these two substrates. The amino acid composition has been determined. Peptide mapping experiments performed after trypsin digestion of the enzyme allow the identification of 24 peptides. Peptides comprising 64% of the amino acid residues have also been purified by high-performance liquid chromatography (HPLC), and their N-terminal residues and amino acid composition determined. Results are compared with the amino acid sequence of ADH from D. melanogaster Adhs [Thatcher, D. R. (1980). Biochem. J. 187:875]. When data on the biochemical and structural characterization of ADH from D. hydei are compared with data from other species of Drosophila, clear homologies are observed.