Exploring the onset of B12-based mutualisms using a recently evolved Chlamydomonas auxotroph and B12-producing bacteria

Abstract

SummaryCobalamin (vitamin B12), is a cofactor for crucial metabolic reactions in multiple eukaryotic taxa, including major primary producers such as algae, and yet only prokaryotes can produce it. Many bacteria can colonise the algal phycosphere, forming stable communities that gain preferential access to exudates and in return provide compounds, such as B12. Extended coexistence can then drive gene loss, leading to greater algal-bacterial interdependence. In this study, we investigate how a recently evolved B12-dependent strain of Chlamydomonas reinhardtii, metE7, forms a mutualism with certain bacteria, including the rhizobium Mesorhizobium loti and even a strain of the gut bacterium E. coli engineered to produce cobalamin. Although metE7 was supported by B12 producers, its growth in co-culture was slower than the B12-independent wild-type, suggesting that high bacterial B12 provision may be necessary to favour B12 auxotrophs and their evolution. Moreover, we found that an E. coli strain that releases more B12 makes a better mutualistic partner, and although this trait may be more costly in isolation, greater B12 release provided an advantage in co-cultures. We hypothesise that, given the right conditions, bacteria that release more B12 may be selected for, particularly if they form close interactions with B12-dependent algae.Originality-Significance statementMicroalgae are fundamental to the global carbon cycle, and yet despite being photosynthetic they often rely on other organisms for micronutrients. One of these micronutrients is vitamin B12 (cobalamin), which they receive from bacteria. Many environmental studies support the widespread role of B12 in algal-bacterial mutualisms, so here we wished to investigate how these mutualisms may arise evolutionarily by using an experimentally evolved B12-dependent alga and various B12-producers. A B12-producing rhizobium, Mesorhizobium loti, could stably support the B12-dependent Chlamydomonas reinhardtii metE7 strain, and vice versa, but nutrient supplementation increased growth of both species further. metE7 could also be supported by E. coli strains engineered to produce B12, and engineering a strain to release a higher proportion of B12 led to better algal growth, which increased bacterial growth in turn. We suggest that as B12-based mutualisms develop, increased B12 release may be selected for and therefore lead to more productive symbioses.