Microplastics mitigate the effects of glyphosate on the shikimic acid pathway enzymes in cyanobacteria

Microplastics, an environmental contaminant, can directly harm aquatic organisms and alter the toxicity and availability of other pollutants. The herbicide glyphosate (N-(phosphonomethyl) glycine) exerts its toxicity by inhibiting 5-enol-pyruvyl-shikimate-3-phosphate synthase (EPSPS), a key enzyme belonging to shikimic acid pathway that leads to the biosynthesis of aromatic amino acids; tolerance, instead, is dependent on a glyphosate -resistant EPSPS. We tested the effects of 0,2mM glyphosate alone and in combination with 170 mg/mL polyethylene microplastics (MPs) on the expression of EPSPS and chorismate synthase (ChS) on a culture of the cyanobacterium <i>Limnospira maxima.</i> Glyphosate caused the highest mortality after one week, with the resistant population surviving thereafter.However, when the culture was exposed to the combined treatment the mortality decreased. Proteomic profiles of treated cultures demonstrated that both enzymes were accumulated during the 21 days glyphosate treatment, suggesting that the surviving population of <i>L. maxima</i> might express glyphosate-resistant target enzymes. Treatment with combined solution caused a decrease of EPSPS and ChS levels compared to those of glyphosate alone. Our results strongly suggest that microplastics mitigate the toxicity of glyphosate towards target enzymes of the shikimic acid pathway, thereby increasing the resistance capacity of the <i>L. maxima</i> strain.