Formation of an Organic-Inorganic Biopolymer: Polyhydroxybutyrate-Polyphosphate.

A considerable variety of different biopolymers is formed by the entirety of organisms present on earth. Most of these compounds are organic polymers such as polysaccharides, polyamino acids, polynucleotides, polyisoprenes or polyhydroxyalkanoates (PHAs), but some biopolymers can consist of solely inorganic monomers such as phosphate in polyphosphates (polyPs). In this contribution, we describe the formation of an organic-inorganic block copolymer consisting of poly(3-hydroxybutyrate) (PHB) and polyP. This was achieved by the expression of a fusion of the polyP kinase gene (ppk2c) with the PHB synthase gene (phaC) of Ralstonia eutropha in a polyP-free and PHB-free mutant background of R. eutropha. The fusion protein catalyzed both the formation of polyP by its polyP kinase domain and the formation of PHB by its PHB synthase domain. It was also possible to synthesize the polyP-PHB polymer in vitro with purified Ppk2c-PhaC, if the monomers, adenosine triphosphate (ATP) and 3-hydroxybutyryl-CoA (3HB-CoA), were provided. Most likely, the formed block copolymer (polyP-protein-PHB) turns into a blend of polyP and PHB after release from the enzyme.

Sequence analysis of a gene product synthesized by Xanthomonas sp. during growth on natural rubber latex.

Xanthomonas sp. secretes an extracellular protein (Mr approximately 70+/-5 kDa) during growth on purified natural rubber [poly(1,4-cis-isoprene)] but not during growth on water-soluble carbon sources such as glucose or gluconate. A 1.3 kbp DNA fragment coding for an internal part of the structural gene of the 70 kDa protein was amplified by nested polymerase chain reaction (PCR) using amino acid sequence information obtained after Edman degradation of selected trypsin-generated peptides of the purified 70 kDa protein. The PCR product was used as a DNA probe to clone the complete structural gene from genomic DNA of Xanthomonas sp. The sequenced DNA contained a 2037 bp open reading frame which coded for a polypeptide of 678 amino acids (Mr 74.6 kDa) and which included the features of the N-terminal signal peptidase cleavage site (Mr approximately 72.9 kDa for the mature protein). Analysis of the amino acid sequence revealed the presence of two heme binding motifs (CXXCH) and a approximately 20 amino acids long sequence that is conserved in the Paracoccus denitrificans and Pseudomonas aeruginosa diheme cytochrome c peroxidases (CCPs). This region includes a histidine residue (H519 in Xanthomonas sp. and H265 and H271 in the Pseudomonas strains, respectively) that is essential for activity in CCPs and that is also conserved in other bacterial oxidases. Blast analysis confirmed the relatedness of the 70 kDa protein to heme-containing oxidases and suggested that it is a member of a new family of relatively large (approximately 500 to approximately 1000 amino acids) extracellular proteins with so far unknown function being only far related in amino acid sequence to P. denitrificans and P. aeruginosa CCPs.

The activator of the Rhodospirillum rubrum PHB depolymerase is a polypeptide that is extremely resistant to high temperature (121 degrees C) and other physical or chemical stresses.

Hydrolysis of native (amorphous) polyhydroxybutyrate (nPHB) granules isolated from different sources by soluble PHB depolymerase of Rhodospirillum rubrum in vitro requires the presence of a heat-stable compound (activator). The activator was purified and was resistant against various physical and chemical stresses such as heat (up to 130 degrees C), pH 1-12, dryness, oxidation by H2O2, reducing and denaturing compounds (2-mercaptoethanol, 5 M guanidinium-HCl) and many solvents including phenol/chloroform. The activator coding gene was identified by N-terminal sequencing of the purified protein, and the deduced protein showed significant homology to magnetosome-associated protein (Mms16) of magnetotactic bacteria. Analysis of the activation process in vitro showed that the activator acts on nPHB granules but not on the depolymerase. The effect of the activator could be mimicked by pretreatment of nPHB granules with trypsin or other proteases but protease activity of the purified activator was not detected. Evidence is shown that different mechanisms were responsible for activation of nPHB by trypsin and activator, respectively. PHB granule-associated protein (PhaP) of Ralstonia eutropha nPHB granules were cleaved by trypsin but no cleavage occurred after activator treatment. Hydrolysis of artificial protein-free PHB granules coated with negatively charged detergents (sodium dodecyl sulfate (SDS), cholate but not cetyltrimethyl-ammonium bromide (CTAB)) did not require activation and confirmed that surface layer proteins of nPHB granules are the targets of the activator rather than lipids. All experimental data are in agreement with the assumption that trypsin and the activator enable the PHB depolymerase to find and to bind to the polymer surface: trypsin by removing a portion of proteins from the polymer surface, the activator by modifying the surface structure in a not yet understood manner presumably by interaction with phasins of the proteinous surface layer of nPHB.

The "PHB depolymerase inhibitor" of Paucimonas lemoignei is a PHB depolymerase.

A approximately 35 kDa protein that has been described to be secreted by Paucimonas lemoignei during growth on succinate and to inhibit hydrolysis of denatured (crystalline) poly(3-hydroxybutyrate) (dPHB) by extracellular PHB depolymerases of P. lemoignei (PHB depolymerase inhibitor (PDI)) was purified and characterized. Purified PDI (M(r), 36 199 +/- 45 Da) inhibited hydrolysis of dPHB by two selected purified PHB depolymerases (PhaZ2 and PhaZ5) but did not inhibit the hydrolysis of water-soluble substrates such as p-nitrophenylbutyrate by PhaZ5 and PhaZ2. PDI revealed a high binding affinity to dPHB although it was not able to hydrolyze the crystalline polymer. However, purified PDI had a high hydrolytic activity if native (amorphous) PHB (nPHB) was used as a substrate. N-terminal sequencing of PDI revealed that it was identical to recently described extracellular PHB depolymerase PhaZ7 which is specific for nPHB and which cannot hydrolyze dPHB. To confirm that the inhibition of hydrolysis of dPHB by PhaZ7 is an indirect surface competition effect at high depolymerase concentration, the activity of PHB depolymerases PhaZ2 and PhaZ5 in the presence of different amounts of protein mixtures was determined. The components of NB or LB medium inhibited hydrolysis of the polymer in a concentration-dependent manner but had no effect on the hydrolysis of p-nitrophenylbutyrate by PHB depolymerases. In combination with PHB depolymerases PhaZ2 and PhaZ5 the protein PhaZ7 ("PDI") enables the bacteria to hydrolyze dPHB and nPHB simultaneously.

Thermotolerant poly(3-hydroxybutyrate)-degrading bacteria from hot compost and characterization of the PHB depolymerase of Schlegelella sp. KB1a.

Eighteen gram-negative thermotolerant poly(3-hydroxybutyrate) (PHB)-degrading bacterial isolates ( T(max) approximately 60 degrees C) were obtained from compost. Isolates produced clearing zones on opaque PHB agar, indicating the presence of extracellular PHB depolymerases. Comparison of physiological characteristics and determination of 16S rRNA gene sequences of four selected isolates revealed a close relatedness of three isolates (SA8, SA1, and KA1) to each other and to Schlegelella thermodepolymerans and Caenibacterium thermophilum. The fourth strain, isolate KB1a, showed reduced similarities to the above-mentioned isolates and species and might represent a new species of Schlegelella. Evidence is provided that S. thermodepolymerans and C. thermophilum are only one species. The PHB depolymerase gene, phaZ, of isolate KB1a was cloned and functionally expressed in Escherichia coli. Purified PHB depolymerase was most active around pH 10 and 76 degrees C. The DNA-deduced amino acid sequence of the mature protein (49.4 kDa) shared significant homologies to other extracellular PHB depolymerases with a domain substructure: catalytic domain type 2-linker domain fibronectin type 3-substrate-binding domain type 1. A catalytic triad consisting of S(20), D(104), and H(138) and a pentapeptide sequence (GLS(20)AG) characteristic for PHB depolymerases (PHB depolymerase box, GLSXG) and for other serine hydrolases (lipase box, GXSXG) were identified.

The "intracellular" poly(3-hydroxybutyrate) (PHB) depolymerase of Rhodospirillum rubrum is a periplasm-located protein with specificity for native PHB and with structural similarity to extracellular PHB depolymerases.

Rhodospirillum rubrum possesses a putative intracellular poly(3-hydroxybutyrate) (PHB) depolymerase system consisting of a soluble PHB depolymerase, a heat-stable activator, and a 3-hydroxybutyrate dimer hydrolase (J. M. Merrick and M. Doudoroff, J. Bacteriol. 88:60-71, 1964). In this study we reinvestigated the soluble R. rubrum PHB depolymerase (PhaZ1). It turned out that PhaZ1 is a novel type of PHB depolymerase with unique properties. Purified PhaZ1 was specific for amorphous short-chain-length polyhydroxyalkanoates (PHA) such as native PHB, artificial PHB, and oligomer esters of (R)-3-hydroxybutyrate with 3 or more 3-hydroxybutyrate units. Atactic PHB, (S)-3-hydroxybutyrate oligomers, medium-chain-length PHA, and lipase substrates (triolein, tributyrin) were not hydrolyzed. The PHB depolymerase structural gene (phaZ1) was cloned. Its deduced amino acid sequence (37,704 Da) had no significant similarity to those of intracellular PHB depolymerases of Wautersia eutropha or of other PHB-accumulating bacteria. PhaZ1 was found to have strong amino acid homology with type-II catalytic domains of extracellular PHB depolymerases, and Ser(42), Asp(138), and His(178) were identified as catalytic-triad amino acids, with Ser(42) as the putative active site. Surprisingly, the first 23 amino acids of the PHB depolymerase previously assumed to be intracellular revealed features of classical signal peptides, and Edman sequencing of purified PhaZ1 confirmed the functionality of the predicted cleavage site. Extracellular PHB depolymerase activity was absent, and analysis of cell fractions unequivocally showed that PhaZ1 is a periplasm-located enzyme. The previously assumed intracellular activator/depolymerase system is unlikely to have a physiological function in PHB mobilization in vivo. A second gene, encoding the putative true intracellular PHB depolymerase (PhaZ2), was identified in the genome sequence of R. rubrum.

Tetrachloroethene reductive dehalogenase of Dehalospirillum multivorans: substrate specificity of the native enzyme and its corrinoid cofactor.

The substrate specificity of the tetrachloroethene reductive dehalogenase of Dehalospirillum multivoransand its corrinoid cofactor were studied. Besides reduced methyl viologen, titanium(III) citrate could serve as electron donor for reductive dehalogenation of tetrachloroethene (PCE) and trichloroethene to cis-1,2-dichloroethene. In addition to chlorinated ethenes, chlorinated propenes were reductively dechlorinated solely by the native enzyme. trans-1,3-Dichloropropene, 1,1,3-trichloropropene and 2,3-dichloropropene were reduced to a mixture of mono-chloropropenes, 1,1-dichloropropene, and 2-chloropropene, respectively. Other halogenated compounds that were rapidly reduced by the enzyme were also dehalogenated abiotically by the heat-inactivated enzyme and by commercially available cyanocobalamin. The rate of this abiotic reaction was dependent on the number and type of halogen substituents and on the type of catalyst. The corrinoid cofactor purified from the tetrachloroethene dehalogenase of D. multivorans exhibited an activity about 50-fold higher than that of cyanocobalamin (vitamin B(12)) with trichloroacetate as electron acceptor, indicating that the corrinoid cofactor of the PCE dehalogenase is not cyanocobalamin. Corrinoids catalyzed the rapid dehalogenation of trichloroacetic acid. The rate was proportional to the amount of, e.g. cyanocobalamin; therefore, the reductive dehalogenation assay can be used for the sensitive and rapid quantification of this cofactor.

Unraveling the function of the Rhodospirillum rubrum activator of polyhydroxybutyrate (PHB) degradation: the activator is a PHB-granule-bound protein (phasin).

Efficient hydrolysis of native poly(3-hydroxybutyrate) (nPHB) granules in vitro by soluble PHB depolymerase of Rhodospirillum rubrum requires pretreatment of nPHB with an activator compound present in R. rubrum cells (J. M. Merrick and M. Doudoroff, J. Bacteriol. 88:60-71, 1964). Edman sequencing of the purified activator (17.4 kDa; matrix-assisted laser desorption ionization-time of flight mass spectrometry) revealed identity to a hypothetical protein deduced from a partially sequenced R. rubrum genome. The complete activator gene, apdA (activator of polymer degradation), was cloned from genomic DNA, expressed as a six-His-tagged protein in recombinant Escherichia coli (M(r), 18.3 x 10(3)), and purified. The effect of ApdA on PHB metabolism was studied in vitro and in vivo. In vitro, the activity of the activator could be replaced by trypsin, but recombinant ApdA itself had no protease activity. Comparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the protein patterns of trypsin- and ApdA-treated nPHB granules isolated from different PHB-accumulating bacteria showed that trypsin activated nPHB by removing proteins of the surface layer of nPHB regardless of the origin of nPHB, but ApdA bound to and interacted with the surface layer of nPHB in a nonproteolytic manner, thereby transforming nPHB into an activated form that was accessible to the depolymerase. In vivo, expression of ApdA in E. coli harboring the PHB biosynthetic genes, phaCBA, resulted in significant increases in the number and surface/volume ratio of accumulated PHB granules, which was comparable to the effect of phasin proteins, such as PhaP in Ralstonia eutropha. The amino acid sequence of ApdA was 55% identical to the amino acid sequence of Mms16, a magnetosome-associated protein in magnetotactic Magnetospirillum species. Mms16 was previously reported to be a GTPase with an essential function in magnetosome formation (Y. Okamura, H. Takeyama, and T. Matsunaga, J. Biol. Chem. 276:48183-48188, 2001). However, no GTPase activity of ApdA could be demonstrated. We obtained evidence that Mms16 of Magnetospirillum gryphiswaldense can functionally replace ApdA in R. rubrum. Fusions of apdA and mms16 to gfp or yfp were functionally expressed, and both fusions colocalized with PHB granules after conjugative transfer to R. rubrum. In conclusion, ApdA in vivo is a PHB-bound, phasin-like protein in R. rubrum. The function of Mms16 in magnetotactic bacteria requires further clarification.