Functional surface display of laccase in a phenol-inducible bacterial circuit for bioremediation purposes

Background: Phenolic compounds, which are produced routinely by industrial and urban activities, possess dangers to live organisms and environment. Laccases are oxidoreductase enzymes with the ability of remediating a wide variety of phenolic compounds to more benign molecules. The purpose of the present research is surface display of a laccase enzyme with adhesin involved in diffuse adhesion [AIDA-I] autotransporter system on the surface of Escherichia coli cells for bioremediation of phenolic compounds

Methods: The expression of laccase was regulated by a phenol-responsive promoter [a 54 promoter]. The constitutively-expressed CapR transcription activator was able to induce laccase expression in the presence of phenolic compounds

Results: Western blot analysis showed the expression and correct transfer of the enzyme to the outer membrane of E. coli cells in the presence of phenol. Activity assay confirmed the correct folding of the enzyme after translocation through the autotransporter system. HPLC analysis of residual phenol in culture medium showed a significant reduction of phenol concentration in the presence of cells displaying laccase on the surface

Conclusion: Our findings confirm that autodisplay enables functional surface display of laccase for direct substrate-enzyme availability by overcoming membrane hindrance

Comparison of three Escherichia coli Strains in recombinant production of reteplase

Background: Escherichia coli [E. coli] is the most extensively used host for the production of recombinant proteins. However, most of the eukaryotic proteins are typicallyobtained as insoluble, misfolded inclusion bodies that need solubilization and refolding. Reteplase as a highly disulfide-bonded recombinant protein is an example of difficult to express protein in E. coli

Methods: In this study, a codon optimized reteplase gene was synthetically prepared and cloned under the control of an IPTG inducible T7 promoter. The vector was simultaneously transformed and expressed in three different E. coli strains. The ability of strains for expression of this recombinant pharmaceutical was compared. Also, an attempt was made to increase the soluble production of reteplase in SHuffle T7 E. coli with alterations of expression condition like temperature, inducer concentration and oxygen supply

Results: High amounts of reteplase were expressed as inclusion bodies in all three strains. BL21 [DE3] showed the highest level of expression in inclusion bodies followed by Rosetta-gami [DE3] and Shuffle T7. Changes of expression conditions were insufficient for soluble expression of reteplase in SHuffle T7 as a genetically engineered host for production of disulfide bonded proteins

Conclusion: The oxidizing cytoplasm of Rosetta-gami and Shuffle T7 in addition to alterations of cultivation parameters could not result in soluble production of reteplase, although the inclusion bodies produced in these two strains might increase the rate of refolding procedure likely due to formation of folding intermediates

Regeneration of glyphosate-tolerant Nicotiana tabacum after plastid transformation with a mutated variant of bacterial aroA gene

Presence of antibiotic resistance markers has always been considered as one of the main safety concerns in transgenic plants and their derived products. Elimination of antibiotic selectable markers from transgenics is a major hurdle for finding efficient and safe candidates. Herbicide tolerance genes might be attractive alternatives. In this study, a variant form of the 5-enoylpyruvyl shikimate-3-phosphate synthase [EPSPS] gene that harbors glycine at position 96 to alanine and alanine 183 to threonine substitutions and confers higher resistance to the broad-spectrum herbicide, glyphosate, was substituted against the spectinomycin resistant gene as a sole selectable marker for plastid transformation of Nicotiana tabacum. Plastid transformation was carried out using the biolistic delivery procedure while delivery parameters such as rupture disk pressure, bombardment distance, etc had been optimized first. A previous study showed that the glyphosate herbicide imposes lethal effects on the structure and integrity of the plastid membrane, even at low concentrations. In order to overcome this problem, a modified procedure for selection of transplastomic cells was used. A long preculture incubation period followed by a gradual increased in glyphosate concentration led to sufficient expression of the transgene. Tolerant calli were thus regenerated through direct selection of transformed plastids in the presence of the glyphosate