Plant resistance genes could affect rhizosphere microbiota, which in turn enhanced plant
resistance to stresses. Our previous study found that overexpression of the GsMYB10 gene …

Aluminum (Al)-resistant plant cultivars can recruit beneficial microbes to alleviate the
stresses. However, the mechanism of how rhizobacterial communities strengthen Al …

Background and aims Aluminum is a major deleterious factor for soybean productivity in
acidic soils. Soil enzyme activities and bacteria play important roles in improving the stress …

Strongly acidic soils are characterized by high aluminum (Al) toxicity and low phosphorus
(P) availability, which suppress legume plant growth and nodule development. Arbuscular …

Different soybean genotypes can differ in their tolerance toward aluminum stress depending
on their rhizosphere-inhabiting microorganisms. However, there is limited understanding of …

Aluminum (Al) toxicity is a major factor limiting crop productivity on acid soils. Soybean
(Glycine max) is an important oil crop and there is great variation in Al tolerance in soybean …

Aluminium (Al) toxicity impedes crop growth in acidic soils and is considered the second
largest abiotic stress after drought for crops worldwide. Despite remarkable progress in …

Rhizosphere microbes are important for plant tolerance to various soil stresses. Rice is the
most aluminum (Al)-tolerant small grain cereal crop species, but the link between rice Al …

Soil microbes are considered the second genome of plants. Understanding the distribution
and network of aluminum (Al)-tolerant microorganisms is helpful to alleviate Al toxicity to …

Introduction Rhizosphere microorganisms can effectively promote the stress resistance of
plants, and some beneficial rhizosphere microorganisms can significantly promote the …