<p>Soil cadmium (Cd<sup>2+</sup>) pollution poses a significant environmental threat due to its persistence, toxicity, and potential for bioaccumulation in the food chains. Rhizosphere bacteria, forming a critical plant-microbe interface, play a key role in mediating metal acquisition and detoxification. Genetically modifying these naturally occurring microorganisms offers a promising approach to enhance Cd<sup>2+</sup> bioremediation efficiency. This review focuses on molecular techniques for engineering rhizosphere bacteria to improve Cd<sup>2+</sup> tolerance, increase metal sequestration, and enhance plant growth promotion capabilities. It explores the genetic potential of microorganisms for developing sustainable and efficient Cd<sup>2+</sup> detoxification technologies in soil. Key advances discussed in the current review for the application of genetically engineered rhizosphere bacteria (ERB) for Cd<sup>2+</sup> bioremediation include (i) increased Cd<sup>2+</sup> adsorption and accumulation with the focus on modifying bacterial metal transporters and on the expression of metal-binding proteins that increase Cd<sup>2+</sup> uptake, intracellular sequestration, and detoxification; and (ii) enhanced rhizosphere competence and synergistic PGP for combined bio- and phytoremediation. This approach focuses on genetic enhancement of chemotaxis to improve bacterial colonization persistence and effectiveness in the rhizosphere, as well as the development of co-engineered bacteria with PGP traits that generate synergistic effects.</p> Graphical Abstract (SCI mechanism diagram) <p></p>

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Engineering rhizosphere bacteria for improved cadmium bioremediation efficacy

  • Gulmeena Shah,
  • Habib Ullah,
  • Aaqib Shaheen,
  • Muhammad Jamil,
  • Rozina Shaheen,
  • Zukhruf Tauqeer,
  • Weiwen Kong

摘要

Soil cadmium (Cd2+) pollution poses a significant environmental threat due to its persistence, toxicity, and potential for bioaccumulation in the food chains. Rhizosphere bacteria, forming a critical plant-microbe interface, play a key role in mediating metal acquisition and detoxification. Genetically modifying these naturally occurring microorganisms offers a promising approach to enhance Cd2+ bioremediation efficiency. This review focuses on molecular techniques for engineering rhizosphere bacteria to improve Cd2+ tolerance, increase metal sequestration, and enhance plant growth promotion capabilities. It explores the genetic potential of microorganisms for developing sustainable and efficient Cd2+ detoxification technologies in soil. Key advances discussed in the current review for the application of genetically engineered rhizosphere bacteria (ERB) for Cd2+ bioremediation include (i) increased Cd2+ adsorption and accumulation with the focus on modifying bacterial metal transporters and on the expression of metal-binding proteins that increase Cd2+ uptake, intracellular sequestration, and detoxification; and (ii) enhanced rhizosphere competence and synergistic PGP for combined bio- and phytoremediation. This approach focuses on genetic enhancement of chemotaxis to improve bacterial colonization persistence and effectiveness in the rhizosphere, as well as the development of co-engineered bacteria with PGP traits that generate synergistic effects.

Graphical Abstract (SCI mechanism diagram)