Rare earth elements detoxification mechanism in the hyperaccumulator Dicranopteris linearis: [silicon-pectin] matrix fixation.

Dicranopteris linearis is the best-known hyperaccumulator species of rare earth elements (REEs) and silicon (Si), capable of dealing with toxic level of REEs. Hence, this study aimed to clarify how D. linearis leaves cope with excessive REE stress, and whether Si plays a role in REE detoxification. The results show that lanthanum (La – as a representative of the REEs) stress led to decreased biomass and an increase of metabolism related to leaf cell wall synthesis and modification. However, the La stress-induced responses, especially the increase of pectin-related gene expression level, pectin polysaccharides concentration, and methylesterase activity, could be mitigated by Si supply. Approximately 70% of the Si in D. linearis leaves interacted with the cell walls to form organosilicon Si-O-C linkages. The Si-modified cell walls contained more hydroxyl groups, leading to a more efficient REE retention compared to the Si-free ones. Moreover, this [Si-cell wall] matrix increased the pectin-La accumulation capacity by 64%, with no effect on hemicellulose-La and cellulose-La accumulation capacity. These results suggest that [Si-pectin] matrix fixation is key in REE detoxification in D. linearis , laying the foundation for the development of phytotechnological applications (e.g. , REE phytomining) using this species in REE-contaminated sites. [Display omitted] • How hyperaccumulator plants detoxify excessive REE stress remain unclear. • Si supply can alleviate the REE toxicity in a hyperaccumulator fern. • Si mitigates the increase of pectin synthesis and modification induced by REE stress. • Most Si in the leaves form Si-O-C linkage with the cell wall component pectin. • [Si-pectin] matrix enhances the REE accumulation and retention capacity. [ABSTRACT FROM AUTHOR]