Mechanical resistance of higher EPS contents in larger granules restricts anammox bacterial growth
Dongdong Xu, Tao Liu, Jiahui Fan, Wenda Chen, Yiyu Li, Meng Zhang, Ping Zheng, Jianhua Guo
Abstract
Extracellular polymeric substances (EPS) are core granular components, playing critical roles in its structural stability. However, little is known about the effect of EPS on bacterial growth due to physical and mechanical resistances posed by EPS matrix. Herein, anaerobic ammonium oxidation (anammox) granules with different sizes and EPS contents were collected from a full-scale plant. Using 13 C isotope labelling and qPCR assays, we confirmed that larger granules with higher EPS content exhibited the higher maximum nitrogen removal activity but much lower bacterial growth yield, resulting in a significantly lower maximum specific growth rate (-26.8%), compared to smaller granules. Metagenomic sequencing revealed that anammox species were identical in different granules, and actual EPS production yields were similar in 15-day incubation, ruling out the possibility that more energy was diverted to produce additional EPS in larger granules. Interestingly, the EPS mechanical strength was significantly greater in large granules, which reduced cell membrane fluidity and severely deformed bacterial cells. These mechanical constraints imposed by the dense EPS matrix limited anammox bacterial proliferation and reduced their growth yield. Using low-intensity ultrasound to loosen EPS structure improved the growth yield of anammox bacteria in large granules, while also enhancing nitrogen removal activity. These together contributed to a substantial increase in bacterial growth rate (+153.3%). The findings highlight that physical and mechanical resistance imposed by EPS plays a previously overlooked role in bacterial growth, and provide the basis for promoting anammox bacterial proliferation within granules.