Alnus trabeculosa, a rhizobia-nodulating tree, was introduced into the Chongxi tidal wetland in the Yangtze River estuary of China to increase the biodiversity of plants and restore tidal wetland functions. However, the effect of the introduced plant on soil bacterial communities and restoration outcomes remains unknown. In this study, the rhizosphere bacterial community structure and diversity were compared between Phragmites australis monospecific community and A. trabeculosa-P. australis mixed communities,aiming to assess whether A. trabeculosa influenced the rhizosphere bacterial communities of P. australis and to investigate whether different taxonomic groups within a soil community may respond similarly to the presence of an introduced exotic plant. Among the14 phylogenetic phyla detected, Proteobacteria and Acidobacteria were the dominant bacterial taxa in the rhizosphere. Phylogenetic analysis of the predominant Proteobacteria showed that the clones from the rhizosphere soils of A. trabeculosa and P. australis in A. trabeculosa-P. australis mixed communities were more diverse than those in the rhizosphere soil of P. australis in P. australis monospecific community. The rhizosphere community in the wetland potentially included active microbial community related to carbon, nitrogen, and sulfur cycling in the Yangtze River estuary. The rhizosphere soil of P. australis in A. trabeculosa-P. australis mixed communities exhibited the highest Shannon diversity index(H′) and Simpson diversity index(1/D)(H = 4.52, 1/D =253). Correspondence analyses revealed that the bacterial community structures were altered after A. trabeculosa was introduced. However, the effect of the introduced plant on soil bacterial bile and soil remediation outcomes remains unknown. In this study, the rhizosphere bacterial community structure and diversity were compared between Phragmites australis monospecific community and A. trabeculosa-P. australis mixed communities, aiming to assess whether A. trabeculosa influenced the rhizosphere bacterial communities of P. australis and to查查 whether different taxonomic groups within a soil community may respond similarly to the presence of an introduced exotic plant. Among the 14 phylogenetic phyla detected, Proteobacteria and Acidobacteria were the dominant bacterial taxa in the rhizosphere. Phylogenetic analysis of the predominant Proteobacteria showed that the clones from the rhizosphere soils o f A. trabeculosa and P. australis in A. trabeculosa -P. australis mixed communities were more diverse than those in the rhizosphere soil of P. australis in P. australis monospecific community. The rhizosphere community in the wetland potentially included active microbial community related to carbon, nitrogen, and sulfur cycling in the Yangtze River estuary. The rhizosphere soil of P. australis in A. trabeculosa-P. australis mixed populations presents the highest Shannon diversity index (H ’) and Simpson diversity index (1 / D) (H = 4.52, 1 / D = 253). Correspondence analyzes shows that the bacterial community structures were altered after A. trabeculosa was introduced.