Abstract
Cyanobacterial HCO3 - transporters BCT1, SbtA and BicA are important components of cyanobacterial CO2-concentration mechanisms. They also show potential in applications aimed at improving photosynthetic rates and yield when expressed in the chloroplasts of C3 crop species. The present study investigated the feasibility of using Escherichia coli to assess function of a range of SbtA and BicA transporters in a heterologous expression system, ultimately for selection of transporters suitable for chloroplast expression. Here, we demonstrate that six β-forms of SbtA are active in E. coli, although other tested bicarbonate transporters were inactive. The sbtA clones were derived from Synechococcus sp. WH5701, Cyanobium sp. PCC7001, Cyanobium sp. PCC6307, Synechococcus elongatus PCC7942, Synechocystis sp. PCC6803, and Synechococcus sp. PCC7002. The six SbtA homologs varied in bicarbonate uptake kinetics and sodium requirements in E. coli. In particular, SbtA from PCC7001 showed the lowest uptake affinity and highest flux rate and was capable of increasing the internal inorganic carbon pool by more than 8 mM relative to controls lacking transporters. Importantly, we were able to show that the SbtB protein (encoded by a companion gene near sbtA) binds to SbtA and suppresses bicarbonate uptake function of SbtA in E. coli, suggesting a role in post-translational regulation of SbtA, possibly as an inhibitor in the dark. This study established E. coli as a heterologous expression and analysis system for HCO3 - transporters from cyanobacteria, and identified several SbtA transporters as useful for expression in the chloroplast inner envelope membranes of higher plants.
Highlights
Due to projections in global population growth, there have been calls for a near doubling of global food production by 2050 [1, 2]
Two key features of the cyanobacterial CO2concentrating mechanism (CCM) are the use of active transport systems for uptake of inorganic carbon (Ci, including CO2 and HCO3-) and the elevation of CO2 levels within unique protein microcompartments, called carboxysomes, which are packed with the Rubisco enzyme [9, 10]
Screening for putative HCO3- transporters that are functional in E. coli
Summary
Due to projections in global population growth, there have been calls for a near doubling of global food production by 2050 [1, 2] To meet this demand, scientists are exploring numerous genetic engineering strategies to increase crop yields by improving photosynthesis, by increasing photosynthetic rates and/or water-use efficiency in crops. Field studies have shown that elevated CO2 levels can increase photosynthetic rates and crop yields [4, 5]. This suggests that strategies aimed at raising CO2 levels in the chloroplast may be a useful approach. Two key features of the cyanobacterial CCM are the use of active transport systems for uptake of inorganic carbon (Ci, including CO2 and HCO3-) and the elevation of CO2 levels within unique protein microcompartments, called carboxysomes, which are packed with the Rubisco enzyme [9, 10]
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