Construction of recombinant mercury resistant Acidithiobacillus caldus

Recombinant expression using the tetrathionate hydrolase promoter in Acidithiobacillus ferrooxidans

In the iron- and sulfur-oxidizing acidophilic chemolithoautotrophic bacterium, Acidithiobacillus ferrooxidans, tetrathionate hydrolase gene (Af-tth) is highly expressed during tetrathionate growth. The expression levels of Af-tth were specifically determined by quantitative reverse transcription-polymerase chain reaction and the expression ratios of S⁰/Fe²⁺ and S₄O₆^2-/Fe²⁺ were found to be 68 ± 21 and 181 ± 5, respectively. The transcriptional start site was identified by primer extension. Promoter regions of Af-tth were cloned into the expression shuttle vector pMPJC and GFP gene was under the direction of the regions. Green fluorescence was observed by UV irradiation in recombinant A. ferrooxidans harboring the plasmid colonies grown on tetrathionate. Furthermore, His-tagged Af-Tth was synthesized in the recombinant cells grown on tetrathionate. Recombinant, His-tagged Af-Tth in an active form, was rapidly purified through metal-affinity column chromatography, although recombinant Af-Tth was synthesized in the inclusion bodies of Escherichia coli and acid-refolding treatment was necessary to recover the activity. The specific activity of purified Af-Tth from recombinant A. ferrooxidans (2.2 ± 0.37 U mg^-1) was similar to that of acid-refolded Af-Tth from recombinant E. coli (2.5 ± 0.18 U mg^-1). This method can be applied not only to heterologous expression but also to homologous expression of target genes for modification or specific mutation in A. ferrooxidans cells.

Genetic engineering of the acidophilic chemolithoautotroph Acidithiobacillus ferrooxidans

There are several natural and anthropomorphic environments where iron- and/or sulfur-oxidizing bacteria thrive in extremely acidic conditions. These acidophilic chemolithautotrophs play important roles in biogeochemical iron and sulfur cycles, are critical catalysts for industrial metal bioleaching operations, and have underexplored potential in future biotechnological applications. However, their unique growth conditions complicate the development of genetic techniques. Over the past few decades genetic tools have been successfully developed for Acidithiobacillus ferrooxidans, which serves as a model organism that exhibits both iron- and sulfur-oxidizing capabilities. Conjugal transfer of plasmids has enabled gene overexpression, gene knockouts, and some preliminary metabolic engineering. We highlight the development of genetic systems and recent genetic engineering of A. ferrooxidans, and discuss future perspectives.

Extremophilic Microfactories: Applications in Metal and Radionuclide Bioremediation

Metals and radionuclides (M&Rs) are a worldwide concern claiming for resilient, efficient, and sustainable clean-up measures aligned with environmental protection goals and global change constraints. The unique defense mechanisms of extremophilic bacteria and archaea have been proving usefulness towards M&Rs bioremediation. Hence, extremophiles can be viewed as microfactories capable of providing specific and controlled services (i.e., genetic/metabolic mechanisms) and/or products (e.g., biomolecules) for that purpose. However, the natural physiological plasticity of such extremophilic microfactories can be further explored to nourish different hallmarks of M&R bioremediation, which are scantly approached in the literature and were never integrated. Therefore, this review not only briefly describes major valuable extremophilic pathways for M&R bioremediation, as it highlights the advances, challenges and gaps from the interplay of ‘omics’ and biological engineering to improve extremophilic microfactories performance for M&R clean-up. Microfactories’ potentialities are also envisaged to close the M&R bioremediation processes and shift the classical idea of never ‘getting rid’ of M&Rs into making them ‘the belle of the ball’ through bio-recycling and bio-recovering techniques.

Plasmid to generate Mycobacteria mutants

The generation of conditional mutants has been an effective approach to studying bacteria and validating drug targets, and mutants of Mycobacteria are no exception. However unlike other bacteria, there is still a paucity of available tools for Mycobacteria. We constructed a new plasmid containing tetracycline-repressive expression system (TetRr1.7) and Xer Site-Specific recombinase system to generate label-free controllable expression strains. The plasmid was subsequently used to construct a strain of M. tuberculosis expressing the only copy of d-alanine:d-alanine ligase under the control of the tetracycline-repressive promoter. The results showed that the mutant strain lost the ability of colony formation, became more sensitive to d-cycloserine and the cell wall of the mutant strain was disrupted when anhydrotetracycline was added to the medium. Taken together these observations, confirmed that the expression of d-alanine:d-alanine ligase was tightly controlled by the promoter. In conclusion, the new plasmid is a convenient tool for constructing stable conditional mutant strains in Mycobacteria and can be used for future target identification.

Engineering microbial consortia to enhance biomining and bioremediation

In natural environments microorganisms commonly exist as communities of multiple species that are capable of performing more varied and complicated tasks than clonal populations. Synthetic biologists have engineered clonal populations with characteristics such as differentiation, memory, and pattern formation, which are usually associated with more complex multicellular organisms. The prospect of designing microbial communities has alluring possibilities for environmental, biomedical, and energy applications, and is likely to reveal insight into how natural microbial consortia function. Cell signaling and communication pathways between different species are likely to be key processes for designing novel functions in synthetic and natural consortia. Recent efforts to engineer synthetic microbial interactions will be reviewed here, with particular emphasis given to research with significance for industrial applications in the field of biomining and bioremediation of acid mine drainage.