Abstract
Myxobacteria, belonging to the phylum Myxococcota, are ubiquitous in soil, marine, and other environments. A recent metagenomic sequencing analysis showed that Myxococcota are predominant in activated sludge systems; however, their metabolic traits remain unclear. In the present study, we examined the potential biological functions of 46 metagenomic bins of Myxococcota reconstructed from activated sludge samples from four municipal sewage treatment plants. The results obtained showed that most Myxococcota bins had an almost complete set of genes associated with glycolysis and the TCA cycle. The Palsa-1104 and Polyangiales bins contained the glycoside hydrolase GH5 and peptidase M23, which are presumably involved in lysis of the cell wall and cellular cytoplasm, suggesting that some Myxococcota from activated sludge prey on other microorganisms. The cell contact-dependent predatory functions of Myxococcus xanthus are conserved in the family Myxococcaceae, but not in other families. Two bins belonging to Palsa-1104 had phototrophic gene clusters, indicating the potential for heterotrophic and autotrophic metabolism by these microbes. In assessments of the social behavior of Myxococcota in activated sludge, the FruA gene and C-signal gene, which are involved in the regulation of fruiting body formation, were lacking in Myxococcota bins, suggesting their inability to form fruiting bodies. In addition, multiple bins of Myxococcota had novel secondary metabolite biosynthesis gene clusters that may be used for the predation of other bacteria in activated sludge. Our metagenome-based analyses provide novel insights into the microbial interactions associated with Myxococcota in activated sludge ecosystems.
