Abstract
This study was motivated by surprising gaps in the current knowledge of microbial inorganic carbon (Ci) uptake and assimilation at acidic pH values (pH < 3). Particularly striking is the limited understanding of the differences between Ci uptake mechanisms in acidic versus circumneutral environments where the Ci predominantly occurs either as a dissolved gas (CO2) or as bicarbonate (HCO3-), respectively. In order to gain initial traction on the problem, the relative abundance of transcripts encoding proteins involved in Ci uptake and assimilation was studied in the autotrophic, polyextreme acidophile Acidithiobacillus ferrooxidans whose optimum pH for growth is 2.5 using ferrous iron as an energy source, although they are able to grow at pH 5 when using sulfur as an energy source. The relative abundance of transcripts of five operons (cbb1-5) and one gene cluster (can-sulP) was monitored by RT-qPCR and, in selected cases, at the protein level by Western blotting, when cells were grown under different regimens of CO2 concentration in elemental sulfur. Of particular note was the absence of a classical bicarbonate uptake system in A. ferrooxidans. However, bioinformatic approaches predict that sulP, previously annotated as a sulfate transporter, is a novel type of bicarbonate transporter. A conceptual model of CO2 fixation was constructed from combined bioinformatic and experimental approaches that suggests strategies for providing ecological flexibility under changing concentrations of CO2 and provides a portal to elucidating Ci uptake and regulation in acidic conditions. The results could advance the understanding of industrial bioleaching processes to recover metals such as copper at acidic pH. In addition, they may also shed light on how chemolithoautotrophic acidophiles influence the nutrient and energy balance in naturally occurring low pH environments.
Highlights
Acidithiobacillus ferrooxidans is a polyextremophile inhabiting very acidic and often metal laden environments that belongs to the Acidithiobacillia class within the Proteobacteria (Williams and Kelly, 2013)
In order to evaluate the effect of CO2 on the growth of A. ferrooxidans, cells were cultivated in 9K medium, pH 3.5 and containing 5 g/L elemental sulfur at 30◦C (Quatrini et al, 2007) with increasing concentrations of CO2 from 0.036% to 20%
Having established that CO2 concentration impacts cell growth rate, we wished to examine the effect of CO2 concentration on the expression of genes involved in the CBB and carbon concentration mechanism (CCM) pathways
Summary
Acidithiobacillus ferrooxidans is a polyextremophile inhabiting very acidic (pH < 3) and often metal laden environments that belongs to the Acidithiobacillia class within the Proteobacteria (Williams and Kelly, 2013). A. ferrooxidans is considered a model species for understanding genetic and metabolic functions reviewed in Cardenas et al, 2016) and survival mechanisms at extremely low pH (Chao et al, 2008) and reviewed in Slonczewski et al (2009). It has provided useful information for understanding how microorganisms can contribute to the nutrient and energy balance in bioleaching heaps (Valdes et al, 2008; Valdés et al, 2010)
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