Mangi Autif Hussain, Yan Qi, Song Xiao, Song Junting, Lan Xia, Zhou Jin, Cai Zhong-Hua
Shenzhen Public Platform for Screening and Application of Marine Microbial Resources, Institute for Ocean Engineering, Shenzhen International Graduate School, Tsinghua University, Shenzhen, China.
School of Life Sciences, Tsinghua University, Beijing, China.
Front Microbiol. 2021 Nov 10;12:716201. doi: 10.3389/fmicb.2021.716201. eCollection 2021.
Oysters are ecological engineers, and previous studies have examined their role as competent facilitators of ecological restoration. However, the decisive role of oysters in the aquatic environment is still debatable because oyster biodeposition (OBD) may also increase the nutrients enriched in sediments. In order to better interpret this problem, we sampled sediment cores from representative oyster culture areas and uncultured areas in Shenzhen Bay. The results have shown that the TOC (total organic carbon) and TN (total nitrogen) decreased significantly ( < 0.05) at the surface sediment layer (0-20-cm deep) and the sediment layer (20-40-cm deep) of the oyster site compared with the reference site. The decreased TOC and TN were also observed at 60- to 100-cm sediment depth in the oyster site. This indicated that the OBD significantly impacted the concentration of TOC and TN in the sediment. To confirm the alleviative role of OBD, we conducted stable isotope (δC and δN) analyses, which further demonstrated the presence of heavier and less lighter forms of organic carbon and nitrogen sediment. The surface sediment layer (0-20 cm) at the oyster site showed 8% more δC‰ compared with the control site ( < 0.05), reflecting the reduction in the TOC. In order to reveal the potential microbial mechanisms involved in OBD, we performed a functional analysis using the Geochip5 advanced microarray technology. Regarding carbon metabolism, we observed that genes (encoding pullulanase, glucoamylase, exoglucanase, cellobiase, and xylanase) involved in the degradation of relatively labile C-based molecules (e.g., starch, cellulose, and hemicellulose) were highly represented in an experimental area ( < 0.05). In addition, microbes in the experimental area exhibited a greater capacity for degrading recalcitrant C (e.g., lignin), which involves glyoxal oxidase (), manganese peroxidase (), and phenol oxidase. Among the genes controlling nitrogen metabolism, the genes involved in denitrification, assimilation, ammonification, and nitrification were differentially expressed compared with the control area. These results indicated that microbial metabolic roles might have enhanced the C/N-flux speed and reduced the overall nutrient status. We concluded that OBD alleviates sediment nutrient overload under oyster farming from a microbial ecological perspective in a rapidly urbanized coastal area.
牡蛎是生态工程师,先前的研究已经考察了它们作为生态恢复有力促进者的作用。然而,牡蛎在水生环境中的决定性作用仍存在争议,因为牡蛎生物沉积(OBD)也可能增加沉积物中富集的营养物质。为了更好地解释这个问题,我们从深圳湾代表性的牡蛎养殖区和未养殖区采集了沉积物岩芯。结果表明,与参考站点相比,牡蛎站点表层沉积物层(0 - 20厘米深)和沉积层(20 - 40厘米深)的总有机碳(TOC)和总氮(TN)显著降低(<0.05)。在牡蛎站点60至100厘米的沉积物深度也观察到TOC和TN的降低。这表明OBD对沉积物中TOC和TN的浓度有显著影响。为了证实OBD的缓解作用,我们进行了稳定同位素(δC和δN)分析,进一步证明了沉积物中存在较重和较轻形式的有机碳和氮。牡蛎站点的表层沉积物层(0 - 20厘米)与对照站点相比,δC‰高出8%(<0.05),反映了TOC的减少。为了揭示OBD涉及的潜在微生物机制,我们使用Geochip5先进微阵列技术进行了功能分析。关于碳代谢,我们观察到参与降解相对不稳定的基于碳的分子(如淀粉、纤维素和半纤维素)的基因(编码支链淀粉酶、葡糖淀粉酶、外切葡聚糖酶、纤维二糖酶和木聚糖酶)在试验区高度富集(<0.05)。此外,试验区的微生物表现出更强的降解难降解碳(如木质素)的能力,这涉及乙二醛氧化酶、锰过氧化物酶和酚氧化酶。在控制氮代谢的基因中,与对照区相比,参与反硝化、同化、氨化和硝化的基因存在差异表达。这些结果表明,微生物的代谢作用可能提高了碳/氮通量速度并降低了总体营养状况。我们得出结论,从微生物生态学角度来看,在快速城市化的沿海地区,OBD减轻了牡蛎养殖下沉积物的营养过载。
