Prevalence of the Calvin-Benson-Bassham cycle in chemolithoautotrophic psychrophiles and the potential for cold-adapted Rubisco

Abstract

AbstractThe act of fixing inorganic carbon into the biosphere is largely facilitated by one enzyme, Rubisco. Beyond well-studied plants and cyanobacteria, many bacteria use Rubisco for chemolithoautotrophy in extreme environments on Earth. Here, we characterized the diversity of chemolithoautotrophic Rubiscos in subzero environments. First, we surveyed subzero environments and found that the Calvin-Benson-Bassham cycle was the most prevalent chemolithoautotrophic pathway. Second, we uncovered potential for chemolithoautotrophy in metagenomes from two distinct subzero, hypersaline Arctic environments: 40-kyr relic marine brines encased within permafrost (cryopeg brines) and first-year sea ice. Again, the Calvin-Benson-Bassham cycle was the dominant chemolithoautotrophic pathway in both environments, though with different Rubisco forms. From cryopeg brine, we reconstructed four metagenome-assembled genomes with the potential for chemolithoautotrophy, of which the sulfur-oxidizing genusThiomicrorhabduswas most abundant. A broader survey ofThiomicrorhabdusgenomes from diverse environments identified a core complement of three Rubisco forms (II, IAc, IAq) with distinct patterns of gain and loss. We developed a model framework and compared these different Rubisco forms across [CO2], [O2], and temperature. We found that form II outcompetes form I at low O2, but cold temperatures minimize this advantage. However, further inspection of form II from cold environments uncovered signals of thermal adaptation of key amino acids which resulted in a more exposed active site. These modifications suggest that these form II Rubisco proteins may have unique kinetics or thermal stability. This work can help address the limits of autotrophic functionality in extreme environments on Earth and other planetary bodies.ImportanceAutotrophy, or the fixation of inorganic carbon to biomass, is a key factor in life’s ability to thrive on Earth. Research on autotrophy has focused on plants and algae, but many bacteria are also autotrophic and can survive and thrive under more extreme conditions. These bacteria are a window to past autotrophy on Earth, as well as potential autotrophy in extreme environments elsewhere in the Universe. Our study focused on dark, cold, saline environments, which are likely to be found on Enceladus and Europa, as well as in the Martian subsurface. We found compelling evidence of cold adaptation in a key autotrophic enzyme, Rubisco, which could expand the known boundaries of autotrophy in rapidly disappearing icy environments on Earth. We also present a novel model framework that can be used to probe the limits of autotrophy not only on Earth but also on key astrobiological targets like Enceladus and Europa.