Persistent microbial symbioses can confer greater fitness to their host under unfavorable
conditions, but manipulating such beneficial interactions necessitates a mechanistic …

Interactions between roots and microbes affect plant's resistance to abiotic stress. However,
the structural and functional variation of root-associated microbiomes and their effects on …

Hyperaccumulator plants can take up large amounts of metals in their shoots without
showing significant signs of toxicity. This makes hyperaccumulators ideal candidates for …

Hyperaccumulator plants combined with beneficial bacteria is a promising strategy for
extracting trace metals from contaminated soils. We explored how the rhizosphere …

Rhizospheric bacteria play important roles in plant tolerance and activation of heavy metals.
Understanding the bacterial rhizobiome of hyperaccumulators may contribute to the …

Microbial communities are closely related to plant performance and numerous studies have
shown their involvement with the growth and development of host plants, resistance to …

For over three centuries, soil scientists and microbiologists have been studying the most
diverse habitat on the planet, characterizing the structure, function, and composition of the …

Sedum alfredii (Crassulaceae) is a promising model plant for Cd/Zn phytoextraction, with
potential for leveraging its rhizosphere microbiomes to help improve phytoremediation …

The assemblage of root‐associated microorganisms plays important roles in improving their
capability to adapt to environmental stress. Metal (loid) hyperaccumulators exhibit disparate …

Phytoextraction is influenced by the indigenous soil microbial communities during the
remediation of heavy metal contaminated soils. Soil microbial communities can affect plant …