The Effect of the Environmental Temperature on the Adaptation to Host in the Zoonotic Pathogen Vibrio vulnificus
Date
2020Abstract
Vibrio vulnificus is a zoonotic pathogen that lives in temperate, tropical and subtropical
aquatic ecosystems whose geographical distribution is expanding due to global
warming. The species is genetically variable and only the strains that belong to the
zoonotic clonal-complex can cause vibriosis in both humans and fish (being its main
host the eel). Interestingly, the severity of the vibriosis in the eel and the human depends
largely on the water temperature (highly virulent at 28◦C, avirulent at 20◦C or below)
and on the iron content in the blood, respectively. The objective of this work was to
unravel the role of temperature in the adaptation to the host through a transcriptomic
and phenotypic approach. To this end, we obtained the transcriptome of a zoonotic
strain grown in a minimum medium (CM9) at 20, 25, 28, and 37◦C, and confirmed the
transcriptomic results by RT-qPCR and phenotypic tests. In addition, we compared
the temperature stimulon with those previously obtained for iron and serum (from
eel and human, respectively). Our results suggest that warm temperatures activate
adaptive traits that would prepare the bacteria for host colonization (metabolism, motility,
chemotaxis, and the protease activity) and fish septicemia (iron-uptake from transferrin
and production of O-antigen of high molecular weight) in a generalized manner, while
environmental iron controls the expression of a host-adapted virulent phenotype (toxins
and the production of a protective envelope). Finally, our results confirm that beyond the
effect of temperature on the V. vulnificus distribution in the environment, it also has an
effect on the infectious capability of this pathogen that must be taken into account to
predict the real risk of V. vulnificus infection caused by global warming.