Identification of the dimerization domain of dehalogenase IVa of Burkholderia cepacia MBA4

Dehalogenases: From Improved Performance to Potential Microbial Dehalogenation Applications

The variety of halogenated substances and their derivatives widely used as pesticides, herbicides and other industrial products is of great concern due to the hazardous nature of these compounds owing to their toxicity, and persistent environmental pollution. Therefore, from the viewpoint of environmental technology, the need for environmentally relevant enzymes involved in biodegradation of these pollutants has received a great boost. One result of this great deal of attention has been the identification of environmentally relevant bacteria that produce hydrolytic dehalogenases—key enzymes which are considered cost-effective and eco-friendly in the removal and detoxification of these pollutants. These group of enzymes catalyzing the cleavage of the carbon-halogen bond of organohalogen compounds have potential applications in the chemical industry and bioremediation. The dehalogenases make use of fundamentally different strategies with a common mechanism to cleave carbon-halogen bonds whereby, an active-site carboxylate group attacks the substrate C atom bound to the halogen atom to form an ester intermediate and a halide ion with subsequent hydrolysis of the intermediate. Structurally, these dehalogenases have been characterized and shown to use substitution mechanisms that proceed via a covalent aspartyl intermediate. More so, the widest dehalogenation spectrum of electron acceptors tested with bacterial strains which could dehalogenate recalcitrant organohalides has further proven the versatility of bacterial dehalogenators to be considered when determining the fate of halogenated organics at contaminated sites. In this review, the general features of most widely studied bacterial dehalogenases, their structural properties, basis of the degradation of organohalides and their derivatives and how they have been improved for various applications is discussed.

The 228bp upstream non-coding region of haloacids transporter gene dehp2 has regulated promoter activity

Biodegradation is an effective way to remove environmental pollutants haloacids, and haloacids uptake is an important step besides cytoplasmic dehalogenation. Previous study has identified a robust haloacids transport system in Burkholderia caribensis MBA4 with two homologous genes deh4p and dehp2 as major players. Both genes are inducible by monochloroacetate (MCA), and dehp2 is conserved among the Burkholderia genus with a two component system upstream. Here we show that dehp2 is not in the same operon with the upstream two component system, and fusion with lacZ confirmed the presence of MCA-inducible promoter activity in the 228bp upstream non-coding region of dehp2. Serial deletion confirmed 112bp upstream is enough for basic promoter activity, but sequence further upstream is useful for enhanced promoter activity. Electrophoretic mobility shift assay of the 228bp region showed a retardation complex with stronger hybridization in the induced condition, suggesting a positive regulation pattern. Regulator(s) binding region was found to lie between -228 to -113bp of dehp2. Quantitative real-time PCR showed that the expressions of dehp2 orthologs in three other Burkholderia species were also MCA-inducible, similar as dehp2. The 5' non-coding regions of these dehp2 orthologs have high sequence similarity with dehp2 promoter, and 100bp upstream of dehp2 orthologs is especially conserved. Our study identified a promoter of haloacids transporter gene that is conserved in the Burkholderia genus, which will benefit future exploitation of them for effective biodegradation of haloacids.

In Silico Phylogenetic Analysis and Molecular Modelling Study of 2-Haloalkanoic Acid Dehalogenase Enzymes from Bacterial and Fungal Origin

2-Haloalkanoic acid dehalogenase enzymes have broad range of applications, starting from bioremediation to chemical synthesis of useful compounds that are widely distributed in fungi and bacteria. In the present study, a total of 81 full-length protein sequences of 2-haloalkanoic acid dehalogenase from bacteria and fungi were retrieved from NCBI database. Sequence analysis such as multiple sequence alignment (MSA), conserved motif identification, computation of amino acid composition, and phylogenetic tree construction were performed on these primary sequences. From MSA analysis, it was observed that the sequences share conserved lysine (K) and aspartate (D) residues in them. Also, phylogenetic tree indicated a subcluster comprised of both fungal and bacterial species. Due to nonavailability of experimental 3D structure for fungal 2-haloalkanoic acid dehalogenase in the PDB, molecular modelling study was performed for both fungal and bacterial sources of enzymes present in the subcluster. Further structural analysis revealed a common evolutionary topology shared between both fungal and bacterial enzymes. Studies on the buried amino acids showed highly conserved Leu and Ser in the core, despite variation in their amino acid percentage. Additionally, a surface exposed tryptophan was conserved in all of these selected models.

L-2-Haloacid dehalogenase from Ancylobacter aquaticus UV5: Sequence determination and structure prediction

A novel 25 kDa L-2-haloacid dehalogenase (L-2-DhlB) from a recently isolated Ancylobacter aquaticus strain UV5 indigenous to contaminated site in South Africa is reported here with its gene sequence. The enzyme was purified to 22.1-fold increase in specific activity of 72.9 U/mg protein when the organism was grown in medium supplemented with 5 mM 1,2-dichloroethane (1,2-DCA). L-2-DhlB was optimally active at pH 9.0 and 37°C with poor stability at 50°C, retaining 50% of its activity after 30 min, but inactivated rapidly at 60°C. L-2-DhlB catalyzed monochloroacetate (MCA) with Km and Vmax values of 0.47 mM and 2.4 μM/min, respectively. L-2-DhlB exhibited the kcat value of 4.8/min. Expression of about 100% relative activity of L-2-DhlB on the substrate L-2-monochloropropionate (L-2-MCPA) as compared to 5% on D-2-monochloropropionate (D-2-MCPA) suggested that L-2-DhlB belongs to the family of L-2-haloacid dehalogenases. ES-mass spectroscopy and bioinformatics tools resulted in 693 bp ORF sequence corresponding to 230 amino acid protein. NCBI-BLAST of L-2-DhlB resulted in the detection of a putative conserved domain of hypothetical haloacid dehalogenase (HAD)-like superfamily and subfamily IA.

Complete genome sequence and characterization of the haloacid-degrading Burkholderia caribensis MBA4

Burkholderia caribensis MBA4 was isolated from soil for its capability to grow on haloacids. This bacterium has a genome size of 9,482,704 bp. Here we report the genome sequences and annotation, together with characteristics of the genome. The complete genome sequence consists of three replicons, comprising 9056 protein-coding genes and 80 RNA genes. Genes responsible for dehalogenation and uptake of haloacids were arranged as an operon. While dehalogenation of haloacetate would produce glycolate, three glycolate operons were identified. Two of these operons contain an upstream glcC regulator gene. It is likely that the expression of one of these operons is responsive to haloacetate. Genes responsible for the metabolism of dehalogenation product of halopropionate were also identified.

Draft Genome Sequence of the Haloacid-Degrading Burkholderia caribensis Strain MBA4

Burkholderia caribensis MBA4 was isolated from soil for its ability to utilize 2-haloacid. An inducible haloacid operon, encoding a dehalogenase and a permease, is mainly responsible for the biotransformation. Here, we report the draft genome sequence of this strain.

Enhanced degradation of haloacid by heterologous expression in related Burkholderia species

Haloacids are environmental pollutant and can be transformed to non-toxic alkanoic acids by microbial dehalogenase. Bacterium Burkholderia species MBA4 was enriched from soil for its ability to bioremediate haloacids such as mono-chloroacetate (MCA), mono-bromoacetate (MBA), 2-mono-chloropropionate, and 2-mono-bromopropionate. MBA4 produces an inducible dehalogenase Deh4a that catalyzes the dehalogenation process. The growth of MBA4 on haloacid also relies on the presence of a haloacid-uptake system. Similar dehalogenase genes can be found in the genome of many related species. However, wildtype Burkholderia caribensis MWAP64, Burkholderia phymatum STM815, and Burkholderia xenovorans LB400 were not able to grow on MCA. When a plasmid containing the regulatory and structural gene of Deh4a was transformed to these species, they were able to grow on haloacid. The specific enzyme activities in these recombinants ranges from 2- to 30-fold that of MBA4 in similar condition. Reverse transcription-quantitative real-time PCR showed that the relative transcript levels in these recombinant strains ranges from 9 to over 1,600 times that of MBA4 in similar condition. A recombinant has produced nearly five times of dehalogenase that MBA4 could ever achieve. While the expressions of Deh4a were more relaxed in these phylogenetically related species, an MCA-uptake activity was found to be inducible. These metabolically engineered strains are better degraders than the haloacid-enriched MBA4.

Transports of acetate and haloacetate in Burkholderia species MBA4 are operated by distinct systems

BACKGROUND

Acetate is a commonly used substrate for biosynthesis while monochloroacetate is a structurally similar compound but toxic and inhibits cell metabolism by blocking the citric acid cycle. In Burkholderia species MBA4 haloacetate was utilized as a carbon and energy source for growth. The degradation of haloacid was mediated by the production of an inducible dehalogenase. Recent studies have identified the presence of a concomitantly induced haloacetate-uptake activity in MBA4. This uptake activity has also been found to transport acetate. Since acetate transporters are commonly found in bacteria it is likely that haloacetate was transported by such a system in MBA4.

RESULTS

The haloacetate-uptake activity of MBA4 was found to be induced by monochloroacetate (MCA) and monobromoacetate (MBA). While the acetate-uptake activity was also induced by MCA and MBA, other alkanoates: acetate, propionate and 2-monochloropropionate (2MCPA) were also inducers. Competing solute analysis showed that acetate and propionate interrupted the acetate- and MCA- induced acetate-uptake activities. While MCA, MBA, 2MCPA, and butyrate have no effect on acetate uptake they could significantly quenched the MCA-induced MCA-uptake activity. Transmembrane electrochemical potential was shown to be a driving force for both acetate- and MCA- transport systems.

CONCLUSIONS

Here we showed that acetate- and MCA- uptake in Burkholderia species MBA4 are two transport systems that have different induction patterns and substrate specificities. It is envisaged that the shapes and the three dimensional structures of the solutes determine their recognition or exclusion by the two transport systems.

Purification, crystallization and preliminary crystallographic analysis of DehI, a group I alpha-haloacid dehalogenase from Pseudomonas putida strain PP3

Pseudomonas putida strain PP3 produces two dehalogenases, DehI and DehII, which belong to the group I and II alpha-haloacid dehalogenases, respectively. Group I dehalogenases catalyse the removal of halides from D-haloalkanoic acids and in some cases also the L-enantiomers, both substituted at their chiral centres. Studies of members of this group have resulted in the proposal of general catalytic mechanisms, although no structural information is available in order to better characterize their function. This work presents the initial stages of the structural investigation of the group I alpha-haloacid dehalogenase DehI. The DehI gene was cloned into a pET15b vector with an N-terminal His tag and expressed in Escherichia coli Nova Blue strain. Purified protein was crystallized in 25% PEG 3350, 0.4 M lithium sulfate and 0.1 M bis-tris buffer pH 6.0. The crystals were primitive monoclinic (space group P2(1)), with unit-cell parameters a = 68.32, b = 111.86, c = 75.13 A, alpha = 90, beta = 93.7, gamma = 90 degrees , and a complete native data set was collected. Molecular replacement is not an option for structure determination, so further experimental phasing methods will be necessary.

The crystal structure of DehI reveals a new alpha-haloacid dehalogenase fold and active-site mechanism

Haloacid dehalogenases catalyse the removal of halides from organic haloacids and are of interest for bioremediation and for their potential use in the synthesis of industrial chemicals. We present the crystal structure of the homodimer DehI from Pseudomonas putida strain PP3, the first structure of a group I alpha-haloacid dehalogenase that can process both L- and D-substrates. The structure shows that the DehI monomer consists of two domains of approximately 130 amino acids that have approximately 16% sequence identity yet adopt virtually identical and unique folds that form a pseudo-dimer. Analysis of the active site reveals the likely binding mode of both L- and D-substrates with respect to key catalytic residues. Asp189 is predicted to activate a water molecule for nucleophilic attack of the substrate chiral centre resulting in an inversion of configuration of either l- or d-substrates in contrast to D-only enzymes. These details will assist with future bioengineering of dehalogenases.

Isolation and characterization of a novel haloacid permease from Burkholderia cepacia MBA4

Burkholderia cepacia MBA4 is a bacterium that can utilize 2-haloacids as carbon and energy sources for growth. It has been proposed that dehalogenase-associated permease mediates the uptake of haloacid. In this paper, we report the first cloning and characterization of such a haloacid permease. The structural gene, designated deh4p, was found 353 bases downstream of the dehalogenase gene deh4a. Quantitative analysis of the expression of deh4p showed that it was induced by monochloroacetate (MCA), to a level similar to the MCA-induced level of deh4a. The nucleotide sequence of deh4p was determined, and an open reading frame of 1,656 bp encoding a putative peptide of 552 amino acids was identified. Deh4p has a putative molecular weight of 59,414 and an isoelectric point of 9.88. Deh4p has the signatures of sugar transport proteins and integral membrane proteins of the major facilitator superfamily. Uptake of [(14)C]MCA into the cell was Deh4p dependent. Deh4p has apparent K(m)s of 5.5 and 8.9 muM and V(max)s of 9.1 and 23.1 nmol mg(-1) min(-1) for acetate and MCA, respectively. A mutant with a transposon-inactivated haloacid operon failed to grow on MCA even when deh4a was provided in trans.

Blue–white selection of regulatory genes that affect the expression of dehalogenase IVa of Burkholderia cepacia MBA4

We have developed a method for rapid screening of genes that affected the expression of dehalogenase IVa of Burkholderia cepacia MBA4. The promoter region of the dehalogenase gene was used to drive the expression of a beta-galactosidase gene. A plasmid containing this reporter was first electroporated into MBA4, and a Tn5 containing suicidal plasmid was introduced subsequently. The use of electroporation was necessary because Escherichia coli mediated transconjugation was ineffective in plasmid-carrying MBA4. The number of integrants generated was directly proportional to the amount of plasmid DNA used. Integrants with an elevated beta-galactosidase activity were isolated. Mutants with a disruption in a putative iron-transporter gene and in a putative response regulator receiver gene were identified. The basal dehalogenase transcript levels of these mutants were higher than the wild type. These mutants also grow faster than the wild type in chloroacetate-containing medium. This methodology of isolating regulatory mutants is theoretically feasible and convenient for any kinds of bacteria.

Crystal structures of the substrate free-enzyme, and reaction intermediate of the HAD superfamily member, haloacid dehalogenase DehIVa from Burkholderia cepacia MBA4

DehIVa is a haloacid dehalogenase (EC 3.8.1.2) from the soil and water borne bacterium Burkholderia cepacia MBA4, which belongs to the functionally variable haloacid dehalogenase (HAD) superfamily of enzymes. The haloacid dehalogenases catalyse the removal of halides from haloacids resulting in a hydroxlated product. These enzymes are of interest for their potential to degrade recalcitrant halogenated environmental pollutants and their use in the synthesis of industrial chemicals. The haloacid dehalogenases utilise a nucleophilic attack on the substrate by an aspartic acid residue to form an enzyme-substrate ester bond and concomitantly cleaving of the carbon-halide bond and release of a hydroxylated product following ester hydrolysis. We present the crystal structures of both the substrate-free DehIVa refined to 1.93 A resolution and DehIVa covalently bound to l-2-monochloropropanoate trapped as a reaction intermediate, refined to 2.7 A resolution. Electron density consistent with a previously unidentified yet anticipated water molecule in the active site poised to donate its hydroxyl group to the product and its proton to the catalytic Asp11 is evident. It has been unclear how substrate enters the active site of this and related enzymes. The results of normal mode analysis (NMA) are presented and suggest a means whereby the predicted global dynamics of the enzyme allow for entry of the substrate into the active site. In the context of these results, the possible role of Arg42 and Asn178 in a "lock down" mechanism affecting active site access is discussed. In silico substrate docking of enantiomeric substrates has been examined in order to evaluate the enzymes enantioselectivity.

Evolutionary genomics of the HAD superfamily: understanding the structural adaptations and catalytic diversity in a superfamily of phosphoesterases and allied enzymes

The HAD (haloacid dehalogenase) superfamily includes phosphoesterases, ATPases, phosphonatases, dehalogenases, and sugar phosphomutases acting on a remarkably diverse set of substrates. The availability of numerous crystal structures of representatives belonging to diverse branches of the HAD superfamily provides us with a unique opportunity to reconstruct their evolutionary history and uncover the principal determinants that led to their diversification of structure and function. To this end we present a comprehensive analysis of the HAD superfamily that identifies their unique structural features and provides a detailed classification of the entire superfamily. We show that at the highest level the HAD superfamily is unified with several other superfamilies, namely the DHH, receiver (CheY-like), von Willebrand A, TOPRIM, classical histone deacetylases and PIN/FLAP nuclease domains, all of which contain a specific form of the Rossmannoid fold. These Rossmannoid folds are distinguished from others by the presence of equivalently placed acidic catalytic residues, including one at the end of the first core beta-strand of the central sheet. The HAD domain is distinguished from these related Rossmannoid folds by two key structural signatures, a "squiggle" (a single helical turn) and a "flap" (a beta hairpin motif) located immediately downstream of the first beta-strand of their core Rossmanoid fold. The squiggle and the flap motifs are predicted to provide the necessary mobility to these enzymes for them to alternate between the "open" and "closed" conformations. In addition, most members of the HAD superfamily contains inserts, termed caps, occurring at either of two positions in the core Rossmannoid fold. We show that the cap modules have been independently inserted into these two stereotypic positions on multiple occasions in evolution and display extensive evolutionary diversification independent of the core catalytic domain. The first group of caps, the C1 caps, is directly inserted into the flap motif and regulates access of reactants to the active site. The second group, the C2 caps, forms a roof over the active site, and access to their internal cavities might be in part regulated by the movement of the flap. The diversification of the cap module was a major factor in the exploration of a vast substrate space in the course of the evolution of this superfamily. We show that the HAD superfamily contains 33 major families distributed across the three superkingdoms of life. Analysis of the phyletic patterns suggests that at least five distinct HAD proteins are traceable to the last universal common ancestor (LUCA) of all extant organisms. While these prototypes diverged prior to the emergence of the LUCA, the major diversification in terms of both substrate specificity and reaction types occurred after the radiation of the three superkingdoms of life, primarily in bacteria. Most major diversification events appear to correlate with the acquisition of new metabolic capabilities, especially related to the elaboration of carbohydrate metabolism in the bacteria. The newly identified relationships and functional predictions provided here are likely to aid the future exploration of the numerous poorly understood members of this large superfamily of enzymes.

Purification, crystallization and preliminary crystallographic analysis of DehIVa, a dehalogenase from Burkholderia cepacia MBA4

DehIVa is one of two dehalogenases produced by the soil- and water-borne bacterium Burkholderia cepacia MBA4. It acts to break down short-chain halogenated aliphatic acids through a nucleophilic attack and subsequent hydrolysis of an enzyme-substrate intermediate to remove the halide ions from L-enantiomers substituted at the C2 position (e.g L-2-monochloropropionic acid). Dehalogenases are an important group of enzymes that are responsible for breaking down a diverse range of halogenated environmental pollutants. The dhlIVa gene coding for DehIVa was expressed in Escherichia coli and the protein was purified and crystallized using the hanging-drop method. Crystals grown in PEG 4000 and ammonium sulfate diffracted to 3.1 A. The crystals had a primitive hexagonal unit cell, with unit-cell parameters a = b = 104.2, c = 135.8 A, alpha = beta = 90, gamma = 120 degrees. Determining this structure will provide valuable insights into the characterization of the catalytic mechanisms of this group of enzymes.

Sec-dependent and Sec-independent translocation of haloacid dehalogenase Chd1 of Burkholderia cepacia MBA4 in Escherichia coli

2-Haloacid dehalogenases are hydrolytic enzymes that cleave the halogen-carbon bond(s) in haloalkanoic acids. We have previously isolated a cryptic haloacid dehalogenase gene from Burkholderia cepacia MBA4 and expressed it in Escherichia coli. This recombinant protein is unusual in having a long leader sequence, a property of periplasmic enzymes. In this paper, we report the functional role of this leader sequence. Western blot analyses showed that Chd1 is translocated to the periplasm. The results on the expression of Chd1 in the presence of sodium azide suggested the cleavage of the leader to be Sec-dependent. Chimeras of Chd1 and green fluorescent protein demonstrated that the leader sequence is fully functional in translocating the fusion protein to the periplasm. The expression of the chimeras in Sec mutants supported the Sec-dependent translocation. Surprisingly, recombinant Chd1 and a chimera with no leader sequence were also found in the periplasm.

Mutagenic analysis of the conserved residues in dehalogenase IVa of Burkholderia cepacia MBA4

Amino and carboxyl terminal deletion derivatives of dehalogenase IVa (DehIVa) of Burkholderia cepacia MBA4 were constructed and analyzed for enzyme activity and for protein integrity. The results suggested that the majority of the protein is indispensable. Point mutations on 29 conserved charged and/or polar residues were generated and characterized. Derivatives D11E, D11N, D11S and D181N were totally inactive while mutant N178D was defective in catalysis. Mutations of other conserved residues displayed varying effects. Mutation that enhances DehIVa activity has been shown to be inhibitory in other dehalogenase and essential conserved residues in DehIVa have been shown to be dispensable in others. This suggests there is no general rule for the importance of these conserved residues.

Two sequence elements of glycosyltransferases involved in urdamycin biosynthesis are responsible for substrate specificity and enzymatic activity

BACKGROUND

Two deoxysugar glycosyltransferases (GTs), UrdGT1b and UrdGT1c, involved in urdamycin biosynthesis share 91% identical amino acids. However, the two GTs show different specificities for both nucleotide sugar and acceptor substrate. Generally, it is proposed that GTs are two-domain proteins with a nucleotide binding domain and an acceptor substrate site with the catalytic center in an interface cleft between these domains. Our work aimed at finding out the region responsible for determination of substrate specificities of these two urdamycin GTs.

RESULTS

A series of 10 chimeric GT genes were constructed consisting of differently sized and positioned portions of urdGT1b and urdGT1c. Gene expression experiments in host strains Streptomyces fradiae Ax and XTC show that nine of 10 chimeric GTs are still functional, with either UrdGT1b- or UrdGT1c-like activity. A 31 amino acid region (aa 52-82) located close to the N-terminus of these enzymes, which differs in 18 residues, was identified to control both sugar donor and acceptor substrate specificity. Only one chimeric gene product of the 10 was not functional. Targeted stepwise alterations of glycine 226 (G226R, G226S, G226SR) were made to reintroduce residues conserved among streptomycete GTs. Alterations G226S and G226R restored a weak activity, whereas G226SR showed an activity comparable with other functional chimeras.

CONCLUSIONS

A nucleotide sugar binding motif is present in the C-terminal moiety of UrdGT1b and UrdGT1c from S. fradiae. We could demonstrate that it is an N-terminal section that determines specificity for the nucleotide sugar and also the acceptor substrate. This finding directs the way towards engineering this class of streptomycete enzymes for antibiotic derivatization applications. Amino acids 226 and 227, located outside the putative substrate binding site, might be part of a larger protein structure, perhaps a solvent channel to the catalytic center. Therefore, they could play a role in substrate accessibility to it.