Microbial phylogenetic relatedness links to distinct successional patterns of bacterial and fungal communities

Development of soil microbial communities along ecological succession is crucial for ecosystem recovery and maintenance. However, mechanisms mediating microbial community dynamics and co-occurrence patterns along ecological succession remain unclear. Here, we explored community dynamics and taxa co-occurrence patterns in bacterial and fungal communities across a well-established chronosequence of post-mining lands spanning 54 years of recovery. Meanwhile, by synthesizing previous studies and ecological theories, we devised two conceptual models that integrate microbial phylogeny with patterns in community dynamics and in taxa co-occurrence. We further tested these models by using empirical data. At early successional stages, bacterial community structures became increasingly phylogenetically clustered with soil age, which was co-determined by the environmental selection from soil vegetation cover and by heterogeneous responses of less phylogenetically similar bacteria to the increasing resource availability along succession. At later successional stages, bacterial community phylogenetic structures displayed progressively lower variability. The fungal community phylogenetic structures varied relatively less and were independent of soil age, soil properties and vegetation cover, which was attributed to the dominance of stochastic processes in community turnover along succession. Network analysis revealed a decrease in bacterial co-occurrence complexity along succession, which aligned with a decrease in average pairwise phylogenetic distances between co-occurring bacteria. These patterns together implied a decrease in potential bacterial cooperation that was probably mediated by increasing resource availability along succession. The increased complexity of fungal co-occurrence along succession was independent of phylogenetic distances between co-occurring fungi. This study provides new sights into ecological mechanisms underlying bacterial and fungal community succession. ### Competing Interest Statement The authors have declared no competing interest.