Insoluble Protein Applications: The Use of Bacterial Inclusion Bodies as Biocatalysts.

Biocatalysis and biotransformations have a broad application in industrial synthetic chemistry. In addition to the whole cell catalysis, purified recombinant enzymes are successfully used for biocatalysis of specific chemical reactions. In this contribution, we report characterization, immobilization, and application of several model target enzymes (D-amino acid oxidase, sialic acid aldolase, maltodextrin phosphorylase, polyphosphate kinase, UDP-glucose pyrophosphorylase) physiologically aggregated within inclusion bodies retaining their biological activity as immobilized biocatalysts.

Insoluble protein applications: the use of bacterial inclusion bodies as biocatalysts.

Biocatalysis and biotransformations have a broad application in industrial synthetic chemistry. In addition to the whole cell catalysis, purified recombinant enzymes are successfully used for biocatalysis of specific chemical reactions. In this contribution, we report characterization, immobilization, and application of several model target enzymes (D-amino acid oxidase, sialic acid aldolase, maltodextrin phosphorylase, polyphosphate kinase) physiologically aggregated within inclusion bodies (IBs) retaining their biological activity as immobilized biocatalysts.

Degradation of polyphosphates by polyphosphate kinases from Ruegeria pomeroyi.

Polyphosphate kinases 2 (PPK2) are key enzymes for polyphosphate utilisation in bacteria. The genome of Ruegeria pomeroyi, a marine α-proteobacterium, includes three Pseudomonas aeruginosa PPK2 homologs. We expressed these homologs in Escherichia coli as soluble proteins, purified the protein products and compared their metal, pH and nucleotide preferences. The optimal pH was 8.0 for SPO1727 and 9.0 for SPO1256. The SPO0224 gene product had two pH optima at eight and ten. The SPO0224 protein showed little dependence on metal presence, while SPO1256 required Mg(2+). SPO1727 required Mg(2+) but accepted other ions as well.

Polyphosphate--an ancient energy source and active metabolic regulator.

There are a several molecules on Earth that effectively store energy within their covalent bonds, and one of these energy-rich molecules is polyphosphate. In microbial cells, polyphosphate granules are synthesised for both energy and phosphate storage and are degraded to produce nucleotide triphosphate or phosphate. Energy released from these energetic carriers is used by the cell for production of all vital molecules such as amino acids, nucleobases, sugars and lipids. Polyphosphate chains directly regulate some processes in the cell and are used as phosphate donors in gene regulation. These two processes, energetic metabolism and regulation, are orchestrated by polyphosphate kinases. Polyphosphate kinases (PPKs) can currently be categorized into three groups (PPK1, PPK2 and PPK3) according their functionality; they can also be divided into three groups according their homology (EcPPK1, PaPPK2 and ScVTC). This review discusses historical information, similarities and differences, biochemical characteristics, roles in stress response regulation and possible applications in the biotechnology industry of these enzymes. At the end of the review, a hypothesis is discussed in view of synthetic biology applications that states polyphosphate and calcium-rich organelles have endosymbiotic origins from ancient protocells that metabolized polyphosphate.