The ancestral environment of teosinte populations shapes their root microbiome
Christopher J. Barnes, Maria Sophie Bünner, M. Rosario Ramírez Flores, Ida Broman Nielsen, Jazmin Ramos Madrigal, Daria Zharikova, Chloee M. McLaughlin, M. Thomas Gilbert and Ruairidh J.H. Sawers
Te invitamos a leer el artículo "The ancestral environment of teosinte populations shapes their root microbiome", en el que colaboraró M. Rosario Ramírez Flores de Cinvestav Irapuato.
Autores:
Christopher J. Barnes, Maria Sophie Bünner, M. Rosario Ramírez Flores, Ida Broman Nielsen, Jazmin Ramos Madrigal, Daria Zharikova, Chloee M. McLaughlin, M. Thomas Gilbert and Ruairidh J.H. Sawers
Resumen:
Background
The composition of the root microbiome affects the host’s growth, with variation in the host genome associated with microbiome variation. However, it is not known whether this intra-specific variation of root microbiomes is a consequence of plants performing targeted manipulations of them to adapt to their local environment or varying passively with other traits. To explore the relationship between the genome, environment and microbiome, we sampled seeds from teosinte populations across its native range in Mexico. We then grew teosinte accessions alongside two modern maize lines in a common garden experiment. Metabarcoding was performed using universal bacterial and fungal primers to profile their root microbiomes.
Results
The root microbiome varied between the two modern maize lines and the teosinte accessions. We further found that variation of the teosinte genome, the ancestral environment (temperature/elevation) and root microbiome were all correlated. Multiple microbial groups significantly varied in relative abundance with temperature/elevation, with an increased abundance of bacteria associated with cold tolerance found in teosinte accessions taken from high elevations.
Conclusions
Our results suggest that variation in the root microbiome is pre-conditioned by the genome for the local environment (i.e. non-random). Ultimately, these claims would be strengthened by confirming that these differences in the root microbiome impact host phenotype, for example, by confirming that the root microbiomes of high-elevation teosinte populations enhance cold tolerance.