Absence of carbonic anhydrase in chloroplasts affects C3 plant development but not photosynthesis.

ABSTRACT

The enzyme carbonic anhydrase (CA), which catalyzes the interconversion of bicarbonate with carbon dioxide (CO2) and water, has been hypothesized to play a role in C3 photosynthesis. We identified two tobacco stromal CAs, ß-CA1 and ß-CA5, and produced CRISPR/Cas9 mutants affecting their encoding genes. While single knockout lines Δß-ca1 and Δß-ca5 had no striking phenotypic differences compared to wild type (WT) plants, Δß-ca1ca5 leaves developed abnormally and exhibited large necrotic lesions even when supplied with sucrose. Leaf development of Δß-ca1ca5 plants normalized at 9,000 ppm CO2 Leaves of Δß-ca1ca5 mutants and WT that had matured in high CO2 had identical CO2 fixation rates and photosystem II efficiency. Fatty acids, which are formed through reactions with bicarbonate substrates, exhibited abnormal profiles in the chloroplast CA-less mutant. Emerging Δß-ca1ca5 leaves produce reactive oxygen species in chloroplasts, perhaps due to lower nonphotochemical quenching efficiency compared to WT. Δß-ca1ca5 seedling germination and development is negatively affected at ambient CO2 Transgenes expressing full-length ß-CA1 and ß-CA5 proteins complemented the Δß-ca1ca5 mutation but inactivated (ΔZn-ßCA1) and cytoplasm-localized (Δ62-ßCA1) forms of ß-CA1 did not reverse the growth phenotype. Nevertheless, expression of the inactivated ΔZn-ßCA1 protein was able to restore the hypersensitive response to tobacco mosaic virus, while Δß-ca1 and Δß-ca1ca5 plants failed to show a hypersensitive response. We conclude that stromal CA plays a role in plant development, likely through providing bicarbonate for biosynthetic reactions, but stromal CA is not needed for maximal rates of photosynthesis in the C3 plant tobacco.