Changes in pH and dissolved inorganic carbon in water affect the growth, saxitoxins production and toxicity of the cyanobacterium Raphidiopsis raciborskii ITEP-A1.

• Responses of R. raciborskii to different pH/CO 2 scenarios were tested;. • Bicarbonate availability governed growth and saxitoxin production in the cyanobacterium;. • R. raciborskii ITEP-A1 is a bicarbonate-user (potentially expresses the BicA transporter);. • Dissolved inorganic carbon and pH influenced saxitoxins production and toxicity in R. raciborskii ITEP-A1. Raphidiopsis raciborskii is a widely distributed, potentially toxic cyanobacterium described as a tropical-subtropical species. However, its occurrence in temperate regions has been expanding. Understanding the environmental factors underlying the expansion and colonization success of Raphidiopsis has been the object of numerous studies. However, less is known regarding its responses to pH and inorganic carbon in water. Thus, the aim of the present study was to investigate the effects of changes in pH and dissolved inorganic carbon on growth and saxitoxins production in the strain R. raciborskii ITEP-A1. We incubated batch cultures with different unbuffered and buffered pH (neutral-acid and alkaline) and inorganic carbon availability (CO 2 -rich air bubbling and the addition of NaHCO 3) to assess the effect of these factors on the growth, toxin production as well as saxitoxins composition of the cyanobacterium. The carbon concentrating mechanism (CCM) system of ITEP-A1 was also characterized by an in silico analysis of its previously sequenced genome. The growth and saxitoxins production of R. raciborskii were affected. The addition of sodium bicarbonate and air bubbling enhanced the growth of the cyanobacterium in alkaline pH. In contrast, saxitoxins production and relative toxicity were decreased. Moreover, significant changes in the cellular composition of saxitoxins were strongly related to pH changes. ITEP-A1 potentially expresses the low-flux bicarbonate transporter BicA, an efficient CCM which uptakes most of its carbon from HCO 3 −. Hence, increasing the diffusion of CO 2 in alkaline eutrophic lakes is likely to increase R. raciborskii dominance , but produce less toxic blooms. Image, graphical abstract [ABSTRACT FROM AUTHOR]