Jakob Birke

Rubber Oxygenase and Latex Clearing Protein Cleave Rubber to Different Products and Use Different Cleavage Mechanisms

ABSTRACT Two types of enzyme for oxidative cleavage of poly(cis-1,4-isoprene) are known. One is rubber oxygenase (RoxA) that is secreted by Xanthomonas sp. strain 35Y and a few other Gram-negative rubber-degrading bacteria during growth on polyisoprene. RoxA was studied in the past, and the recently solved structure showed a structural relationship to bacterial cytochrome c peroxidases (J. Seidel et al., Proc. Natl. Acad. Sci. U. S. A. 110:13833–13838, 2013, http://dx.doi.org/10.1073/pnas.1305560110). The other enzyme is latex-clearing protein (Lcp) that is secreted by rubber-degrading actinomycetes, but Lcp has not yet been purified. Here, we expressed Lcp of Streptomyces sp. strain K30 in a ΔroxA background of Xanthomonas sp. strain 35Y and purified native (untagged) Lcp. The specific activities of Lcp and RoxA were 0.70 and 0.48 U/mg, respectively. Lcp differed from RoxA in the absence of heme groups and other characteristics. Notably, Lcp degraded polyisoprene via endo-type cleavage to tetra-C20 and higher oligo-isoprenoids with aldehyde and keto end groups, whereas RoxA used an exo-type cleavage mechanism to give the main end product 12-oxo-4,8-dimethyltrideca-4,8-diene-1-al (ODTD). RoxA was able to cleave isolated Lcp-derived oligo-isoprenoid molecules to ODTD. Inhibitor studies, spectroscopic investigations and metal analysis gave no indication for the presence of iron, other metals, or cofactors in Lcp. Our results suggest that Lcp could be a member of the growing group of cofactor-independent oxygenases and differs in the cleavage mechanism from heme-dependent RoxA. In conclusion, RoxA and Lcp represent two different answers to the same biochemical problem, the cleavage of polyisoprene, a polymer that has carbon-carbon double bonds as the only functional groups for enzymatic attack.

Phe317 Is Essential for Rubber Oxygenase RoxA Activity

ABSTRACT RoxA is an extracellular c-type diheme cytochrome secreted by Xanthomonas sp. strain 35Y during growth on rubber. RoxA cleaves poly(cis-1,4-isoprene) to 12-oxo-4,8-dimethyltrideca-4,8-diene-1-al (ODTD). Analysis of the RoxA structure revealed that Phe317 is located in close proximity (≈5 Å) to the N-terminal heme that presumably represents the active site. To find evidence of whether Phe317 is important for catalysis, we changed it to tyrosine, tryptophan, leucine, histidine, or alanine. All five RoxA muteins were expressed after integration of the respective gene into the chromosome of a Xanthomonas sp. ΔroxA strain. Residual clearing zone formation on opaque latex agar was found for Xanthomonas sp. strains expressing the Phe317Leu, Phe317Ala, or Phe317His variant (wild type > Leu > Ala > His). Strains in which Phe317 was changed to tyrosine or tryptophan were inactive. Phe317Ala and Phe312Leu RoxA muteins were purified, and polyisoprene cleavage activities were reduced to ≈3% and 10%, respectively. UV-visible spectroscopy of RoxA muteins confirmed that both heme groups were present in an oxidized form, but spectral responses to the addition of low-molecular-weight (inhibitory) ligand molecules such as imidazole and pyridine were different from those of wild-type RoxA. Our results show that residue 317 is involved in interaction with substrates. This is the first report on structure-function analysis of a polyisoprene-cleaving enzyme and on the identification of an amino acid that is essential for polyisoprene cleavage activity.

Latex Clearing Protein (Lcp) of Streptomyces sp. Strain K30 Is a b-Type Cytochrome and Differs from Rubber Oxygenase A (RoxA) in Its Biophysical Properties

ABSTRACT Specific polyisoprene-cleaving activities of 1.5 U/mg and 4.6 U/mg were determined for purified Strep-tagged latex clearing protein (Lcp) of Streptomyces sp. strain K30 at 23°C and 37°C, respectively. Metal analysis revealed the presence of approximately one atom of iron per Lcp molecule. Copper, which had been identified in Lcp1VH2 of Gordonia polyisoprenivorans previously, was below the detection limit in LcpK30. Heme was identified as a cofactor in purified LcpK30 by (i) detection of characteristic α-, β-, and γ (Soret)-bands at 562 nm, 532 nm, and 430 nm in the visible spectrum after chemical reduction, (ii) detection of an acetone-extractable porphyrin molecule, (iii) determination of a heme b-type-specific absorption maximum (556 nm) after chemical conversion of the heme group to a bipyridyl-heme complex, and (iv) detection of a b-heme-specific m/z value of 616.2 via mass spectrometry. Spectroscopic analysis showed that purified Lcp as isolated contains an oxidized heme-Fe3+ that is free of bound dioxygen. This is in contrast to the rubber oxygenase RoxA, a c-type heme-containing polyisoprene-cleaving enzyme present in Gram-negative rubber degraders, in which the covalently bound heme firmly binds a dioxygen molecule. LcpK30 also differed from RoxA in the lengths of the rubber degradation cleavage products and in having a higher melting point of 61.5°C (RoxA, 54.3°C). In summary, RoxA and Lcp both are equipped with a heme cofactor and catalyze an oxidative C-C cleavage reaction but differ in the heme subgroup type and in several biochemical and biophysical properties. These findings suggest differences in the catalytic reaction mechanisms.

Functional Identification of Rubber Oxygenase (RoxA) in Soil and Marine Myxobacteria

ABSTRACT The rubber oxygenase (RoxA) of Xanthomonas sp. strain 35Y (RoxA Xsp ) is so far the only known extracellular c-type diheme cytochrome that is able to cleave poly(cis-1,4-isoprene). All other rubber-degrading bacteria described are Gram positive and employ a nonheme protein (latex-clearing protein [Lcp]) for the postulated primary attack of polyisoprene. Here, we identified RoxA orthologs in the genomes of Haliangium ochraceum, Myxococcus fulvus, Corallococcus coralloides, and Chondromyces apiculatus. The roxA orthologs of H. ochraceum (RoxA Hoc ), C. coralloides BO35 (RoxA Cco ), and M. fulvus (RoxA Mfu ) were functionally expressed in a ΔroxA Xanthomonas sp. 35Y background. All RoxA orthologs oxidatively cleaved polyisoprene, as revealed by restoration of clearing-zone formation and detection of 12-oxo-4,8-dimethyltrideca-4,8-diene-1-al (ODTD) as a cleavage product. RoxA Xsp , RoxA Mfu , and RoxA Cco were purified and biochemically characterized. The optimal temperature of RoxA Cco and RoxA Mfu was between 22 and 30°C. All RoxA orthologs as isolated showed an oxidized UV-visible spectrum. Chemical reduction of RoxA Cco and RoxA Mfu indicated the presence of two slightly different heme centers with absorption maxima between 549 and 553 nm, similar to RoxA Xsp . Sequence analysis and modeling of the three-dimensional structures of the RoxA orthologs revealed a high degree of similarity to the recently solved RoxA Xsp structure and included several conserved residues, notably, W302, F317, and a MauG motif at about H517. Lcp-like sequences were not detected in the genomes of the Xanthomonas sp. 35Y, H. ochraceum, M. fulvus, and C. coralloides. No RoxA orthologs were found in Gram-positive bacteria, and this first description of functional RoxA in Gram-negative bacteria other than Xanthomonas proves that RoxA is more common among rubber degraders than was previously assumed.

Cleavage of Rubber by the Latex Clearing Protein (Lcp) of Streptomyces sp. Strain K30: Molecular Insights.

ABSTRACT Gram-positive rubber degraders such as Streptomyces sp. strain K30 cleave rubber [poly(cis-1,4-isoprene)] to low-molecular-mass oligoisoprenoid products with terminal keto and aldehyde groups by the secretion of a latex clearing protein (Lcp) designated rubber oxygenase. LcpK30 is a heme b cytochrome and has a domain of unknown function (DUF2236) that is characteristic of orthologous Lcps. Proteins with a DUF2236 domain are characterized by three highly conserved residues (R164, T168, and H198 in LcpK30). Exchange of R164 or T168 by alanine and characterization of the purified LcpK30 muteins revealed that both were stable and contained a heme group (red color) but were inactive. This finding identifies both residues as key residues for the cleavage reaction. The purified H198A mutein was also inactive and stable but was colorless due to the absence of heme. We constructed and characterized alanine muteins of four additional histidine residues moderately conserved in 495 LcpK30 homologous sequences (H203A, H232A, H259A, H266A). All muteins revealed wild-type properties, excluding any importance for activity and/or heme coordination. Since LcpK30 has only eight histidines and the three remaining residues (H103, H184, and H296) were not conserved (<11%), H198 presumably is the only essential histidine, indicating its putative function as a heme ligand. The second axial position of the heme is likely occupied by a not yet identified molecule. Mutational analysis of three strictly conserved arginine residues (R195, R202, R328) showed that R195A and R202A muteins were colorless and instable, suggesting that these residues are important for the protein stability. IMPORTANCE Large amounts of rubber waste materials have been permanently released into the environment for more than a century, yet accumulation of rubber particles released, e.g., by abrasion of tires along highways has not been observed. This is indicative of the ubiquitous presence and activity of rubber-degrading microorganisms. Despite increasing research activities on rubber biodegradation during the last 2 decades, the knowledge of the enzymatic cleavage mechanism of rubber by latex clearing protein (Lcp) still is limited. In particular, the catalytic cleavage mechanism and the amino acids of Lcp proteins (Lcps) that are involved have not yet been identified for any Lcp. In this study, we investigated the importance of 10 amino acid residues of Lcp from Streptomyces sp. K30 (LcpK30) by mutagenesis, mutein purification, and biochemical characterization. We identified several essential residues, one of which most likely represents an axial heme ligand in Lcp of Streptomyces sp. K30.

RoxB Is a Novel Type of Rubber Oxygenase That Combines Properties of Rubber Oxygenase RoxA and Latex Clearing Protein (Lcp)

ABSTRACT Only two types of rubber oxygenases, rubber oxygenase (RoxA) and latex clearing protein (Lcp), have been described so far. RoxA proteins (RoxAs) are c-type cytochromes of ≈70 kDa produced by Gram-negative rubber-degrading bacteria, and they cleave polyisoprene into 12-oxo-4,8-dimethyltrideca-4,8-diene-1-al (ODTD), a C15 oligo-isoprenoid, as the major end product. Lcps are common among Gram-positive rubber degraders and do not share amino acid sequence similarities with RoxAs. Furthermore, Lcps have much smaller molecular masses (≈40 kDa), are b-type cytochromes, and cleave polyisoprene to a mixture of C20, C25, C30, and higher oligo-isoprenoids as end products. In this article, we purified a new type of rubber oxygenase, RoxBXsp (RoxB of Xanthomonas sp. strain 35Y). RoxBXsp is distantly related to RoxAs and resembles RoxAs with respect to molecular mass (70.3 kDa for mature protein) and cofactor content (2 c-type hemes). However, RoxBXsp differs from all currently known RoxAs in having a distinctive product spectrum of C20, C25, C30, and higher oligo-isoprenoids that has been observed only for Lcps so far. Purified RoxBXsp revealed the highest specific activity of 4.5 U/mg (at 23°C) of all currently known rubber oxygenases and exerts a synergistic effect on the efficiency of polyisoprene cleavage by RoxAXsp. RoxB homologs were identified in several other Gram-negative rubber-degrading species, pointing to a prominent function of RoxB for the biodegradation of rubber in Gram-negative bacteria. IMPORTANCE The enzymatic cleavage of rubber (polyisoprene) is of high environmental importance given that enormous amounts of rubber waste materials are permanently released (e.g., by abrasion of tires). Research from the last decade has discovered rubber oxygenase A, RoxA, and latex clearing protein (Lcp) as being responsible for the primary enzymatic attack on the hydrophobic and water-insoluble biopolymer poly(cis-1,4-isoprene) in Gram-negative and Gram-positive rubber-degrading bacteria, respectively. Here, we provide evidence that a third type of rubber oxygenase is present in Gram-negative rubber-degrading species. Due to its characteristics, we suggest the designation RoxB for the new type of rubber oxygenase. Bioinformatic analysis of genome sequences indicates the presence of roxB homologs in other Gram-negative rubber degraders.

Structural and Functional Analysis of Latex Clearing Protein (Lcp) Provides Insight into the Enzymatic Cleavage of Rubber

Latex clearing proteins (Lcps) are rubber oxygenases that catalyse the extracellular cleavage of poly (cis-1,4-isoprene) by Gram-positive rubber degrading bacteria. Lcp of Streptomyces sp. K30 (LcpK30) is a b-type cytochrome and acts as an endo-type dioxygenase producing C20 and higher oligo-isoprenoids that differ in the number of isoprene units but have the same terminal functions, CHO-CH2– and –CH2-COCH3. Our analysis of the LcpK30 structure revealed a 3/3 globin fold with additional domains at the N- and C-termini and similarities to globin-coupled sensor proteins. The haem group of LcpK30 is ligated to the polypeptide by a proximal histidine (His198) and by a lysine residue (Lys167) as the distal axial ligand. The comparison of LcpK30 structures in a closed and in an open state as well as spectroscopic and biochemical analysis of wild type and LcpK30 muteins provided insights into the action of the enzyme during catalysis.

Production of functionalized oligo‐isoprenoids by enzymatic cleavage of rubber

In this study, we show the proof of concept for the production of defined oligo‐isoprenoids with terminal functional groups that can be used as starting materials for various purposes including the synthesis of isoprenoid‐based plastics. To this end, we used three types of rubber oxygenases for the enzymatic cleavage of rubber [poly(cis‐1,4‐isoprene)]. Two enzymes, rubber oxygenase RoxAXsp and rubber oxygenase RoxBXsp, originate from Xanthomonas sp. 35Y; the third rubber oxygenase, latex‐clearing protein (LcpK30), is derived from Gram‐positive rubber degraders such as Streptomyces sp. K30. Emulsions of polyisoprene (latex) were treated with RoxAXsp, RoxBXsp, LcpK30 or with combinations of the three proteins. The cleavage products were purified by solvent extraction and FPLC separation. All products had the same general structure with terminal functions (CHO‐CH2‐ and ‐CH2‐COCH3) but differed in the number of intact isoprene units in between. The composition and m/z values of oligo‐isoprenoid products were determined by HPLC‐MS analysis. Our results provide a method for the preparation of reactive oligo‐isoprenoids that can likely be used to convert polyisoprene latex or rubber waste materials into value‐added molecules, biofuels, polyurethanes or other polymers.

Correction: Metabolic and taxonomic insights into the Gram-negative natural rubber degrading bacterium Steroidobacter cummioxidans sp. nov., strain 35Y

[This corrects the article DOI: 10.1371/journal.pone.0197448.].

Rhizobacter gummiphilus NS21 has two rubber oxygenases (RoxA and RoxB) acting synergistically in rubber utilisation

Biodegradation of poly(cis-1,4-isoprene) (rubber) by Gram-negative bacteria has been investigated on the enzymatic level only in Steroidobacter cummioxidans 35Y (previously Xanthomonas sp. 35Y). This species produces two kinds of rubber oxygenases, RoxA35Y and RoxB35Y, one of which (RoxB35Y) cleaves polyisoprene to a mixture of C20- and higher oligoisoprenoids while the other (RoxA35Y) cleaves polyisoprene and RoxB35Y-derived oligoisoprenoids to the C15-oligoisoprenoid 12-oxo-4,8-dimethyltrideca-4,8-diene-1-al (ODTD). ODTD can be taken up by S. cummioxidans and used as a carbon source. Gram-positive rubber-degrading bacteria employ another type of rubber oxygenase, latex clearing protein (Lcp), for the initial oxidative attack of the polyisoprene molecule. In this contribution, we examined which type of rubber oxygenase is present in the only other well-documented Gram-negative rubber-degrading species, Rhizobacter gummiphilus NS21. No homologue for an Lcp protein but homologues for a putative RoxA and a RoxB protein (the latter identical to a previously postulated LatA-denominated rubber cleaving enzyme) were identified in the genome of strain NS21. The roxANS21 and roxBNS21 genes were separately expressed in a ∆roxA35Y/∆roxB35Y background of S. cummioxidans 35Y and restored the ability of the mutant to produce oligoisoprenoids. The RoxANS21 and RoxBNS21 proteins were each purified and biochemically characterised. The results—in combination with in silico analysis of databases—indicate that Gram-negative rubber-degrading bacteria generally utilise two synergistically acting rubber oxygenases (RoxA/RoxB) for efficient cleavage of polyisoprene to ODTD.