Sustainable production of biologically active molecules of marine based origin.

The marine environment offers both economic and scientific potential which are relatively untapped from a biotechnological point of view. These environments whilst harsh are ironically fragile and dependent on a harmonious life form balance. Exploitation of natural resources by exhaustive wild harvesting has obvious negative environmental consequences. From a European industry perspective marine organisms are a largely underutilised resource. This is not due to lack of interest but due to a lack of choice the industry faces for cost competitive, sustainable and environmentally conscientious product alternatives. Knowledge of the biotechnological potential of marine organisms together with the development of sustainable systems for their cultivation, processing and utilisation are essential. In 2010, the European Commission recognised this need and funded a collaborative RTD/SME project under the Framework 7-Knowledge Based Bio-Economy (KBBE) Theme 2 Programme 'Sustainable culture of marine microorganisms, algae and/or invertebrates for high value added products'. The scope of that project entitled 'Sustainable Production of Biologically Active Molecules of Marine Based Origin' (BAMMBO) is outlined. Although the Union is a global leader in many technologies, it faces increasing competition from traditional rivals and emerging economies alike and must therefore improve its innovation performance. For this reason innovation is placed at the heart of a European Horizon 2020 Strategy wherein the challenge is to connect economic performance to eco performance. This article provides a synopsis of the research activities of the BAMMBO project as they fit within the wider scope of sustainable environmentally conscientious marine resource exploitation for high-value biomolecules.

Improved PCR-based gene synthesis method and its application to the Citrobacter freundii phytase gene codon modification.

Gene synthesis technologies provide a powerful tool for increasing protein expression through codon optimization and gene modification. Here we describe an improved PCR-based gene synthesis technology, which is accurate, simple and cheap. The improved PCR-based gene synthesis (IPS) method consists of two steps. The first one is the synthesis of 300-400bp fragments by PCR reaction with Pfu DNA polymerase from 60-mer and 30-mer oligonucleotides with a 15bp overlap. The second one is assembling of fragments from the first step into the full-length gene by PCR reaction. Using this approach, we have successfully synthesized a modified phytase gene with 1256bp in length with optimal codons for expression in Pichia pastoris. P. pastoris strain that expressed the modified phytase gene (phyA-mod) showed a 50% increase in phytase activity level. In addition, we propose an inexpensive method for error correction, based on overlap-extension PCR (OE-PCR).

Gene cloning, expression and characterization of novel phytase from Obesumbacterium proteus.

The gene phyA encoding phytase was isolated from Obesumbacterium proteus genomic library and sequenced. The cleavage site of the PhyA signal peptide was predicted and experimentally proved. The PhyA protein shows maximum identity of 53% and 47% to phosphoanhydride phosphorylase from Yersinia pestis and phytase AppA from Escherichia coli, respectively. Based on protein sequence similarity of PhyA and its homologs, the phytases form a novel subclass of the histidine acid phosphatase family. To characterize properties of the PhyA protein, we expressed the phyA gene in E. coli. The specific activity of the purified recombinant PhyA was 310 U mg(-1) of protein. Recombinant PhyA showed activity at pH values from 1.5 through 6.5 with the optimum at 4.9. The temperature optimum was 40-45 degrees C at pH 4.9. The Km value for sodium phytate was 0.34 mM with a Vmax of 435 U mg(-1).