The harmful bloom-forming cyanobacterium Cylindrospermopsis raciborskii grows in freshwaters over a wide range of light conditions. This species has increased its global distribution recently. The influence of ultraviolet radiation (UVR) on the fitness and toxin production of C. raciborskii has not previously been explored. We performed short-term experiments with three C. raciborskii strains (MVCC19, LB2897, and CYP011 K), and we compared their responses with other bloom-forming species (Microcystis sp.1 and Plankthotrix agardhii) to determine the impact of UV-B radiation on pigments, biomass, and morphological traits. In addition, we analyzed the effect of UV-B on the saxitoxin content and sxtU gene expression in the strain MVCC19. C. raciborskii strains were stressed differentially by UV-B exposure as evidenced by changes in growth, morphology, and heterocytes number. A significant increase in saxitoxin concentration and sxtU gene expression under UV-B suggests that toxin production in C. raciborskii can be a response to UV-B stress. In comparison, Microcystis sp.1 was more tolerant, while P. agardhii was severely impacted by UV-B, indicating also different sensitivities among cyanobacteria to UVR. Our results underscore the influence of UVR on C. raciborskii and the differences between strains which showed phenotypic plasticity, which potentially could affect its distribution in freshwaters.
Raphidiopsis raciborskii is a toxic, invasive bacteria with a defined biogeographic pattern attributed to the generation of ecotypes subjected to local environmental filters and to phenotypic plasticity. The interactions taking place between the cyanobacterium and the other bacteria inhabiting the external polysaccharide-rich matrix surrounding the cells, or phycosphere, may be ecotype-specific and would have different influence on the carbon and nutrient cycling in the ecosystem. Here, we describe the bacterial community or microbiome (assessed by 16S rRNA metagenomics) associated to two R. raciborskii strains that have been described as different ecotypes: the saxitoxin-producer MVCC19 and the non-toxic LB2897. Our results showed that both ecotypes share 50% of their microbiomes and differ in their dominant taxa. The taxon having the highest abundance in the microbiome of MVCC19 was Neorhizobium (22.5% relative abundance), while the dominant taxon in LB2897 was the Planctomycetes SM1A02 (26.2% relative abundance). These groups exhibit different metabolic capabilities regarding nitrogen acquisition (symbiotic nitrogen-fixing in Neorhizobium vs. anammox in SM1A02), suggesting the existence of ecotype-specific microbiomes that play a relevant role in cyanobacterial niche-adaptation. In addition, as saxitoxin and analogues are nitrogen-rich (7 atoms per molecule), we hypothesise that saxitoxin-producing R. raciborskii benefits from external sources of nitrogen provided by the microbiome bacteria. Based on these findings, we propose that the mechanisms involved in the assembly of the cyanobacterial microbiome community are ecotype-dependent.
Las floraciones de cianobacterias potencialmente tóxicas son uno de los problemas más difundidos en los sistemas acuáticos a nivel global. Sin embargo, es necesario desarrollar programas de monitoreo sensibles y directamente aplicables a la predicción de las floraciones y su gestión. Con este objetivo se combinaron conceptos ecológicos y genéticos para generar herramientas para el monitoreo de cianobacterias. Se utilizaron dos aproximaciones: agrupación de organismos en grupos funcionales basados en morfología y análisis moleculares (PCR cuantitativo en tiempo real) que indican presencia de genes que codifican para la expresión de cianotoxinas (mcy). Para evaluar las herramientas se realizaron seis campañas de muestreo bimensuales (2013-2014) en seis estaciones con dos sitios en cada una, a lo largo del Río Uruguay y del Estuario Río de la Plata, desde Salto Grande hasta Punta del Este. Se observó un gradiente marcado en las variables meteorológicas, físico-químicas, y mayores abundancias de organismos planctónicos en Salto Grande y Punta del Este. Se encontró la presencia en todo el gradiente de poblaciones tóxicas, con mayor abundancia en Salto, particularmente del complejo Microcystis aeruginosa (CMA). Las variables ambientales más importantes en determinar el gradiente ambiental y las variaciones en las variables biológicas fueron la salinidad, la temperatura, el viento y la turbidez. Los resultados de los nuevos indicadores (presencia en red del CMA y genes mcy) estuvieron correlacionados con los tradicionales (ej. clorofila-a) en los casos de floraciones más severas, y fueron sustantivamente más sensibles que los tradicionales en situaciones de bajas abundancias. La conjunción de los resultados se aplicó a la construcción de un protocolo de monitoreo y un sistema de alerta. Palabras clave: Floraciones, grupos funcionales, genotipos tóxicos, gradiente ambiental, protocolo de monitoreo, sistema de alerta.
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