Department of Microbiology, University of Tennessee, Knoxville, Knoxville, Tennessee, USA
Department of Earth and Planetary Sciences, University of Tennessee, Knoxville, Knoxville, Tennessee, USA.
Appl Environ Microbiol. 2019 Sep 17;85(19). doi: 10.1128/AEM.00102-19. Print 2019 Oct 1.
Anoxic subsurface sediments contain communities of heterotrophic microorganisms that metabolize organic carbon at extraordinarily low rates. In order to assess the mechanisms by which subsurface microorganisms access detrital sedimentary organic matter, we measured kinetics of a range of extracellular peptidases in anoxic sediments of the White Oak River Estuary, NC. Nine distinct peptidase substrates were enzymatically hydrolyzed at all depths. Potential peptidase activities () decreased with increasing sediment depth, although expressed on a per-cell basis was approximately the same at all depths. Half-saturation constants ( ) decreased with depth, indicating peptidases that functioned more efficiently at low substrate concentrations. Potential activities of extracellular peptidases acting on molecules that are enriched in degraded organic matter (d-phenylalanine and l-ornithine) increased relative to enzymes that act on l-phenylalanine, further suggesting microbial community adaptation to access degraded organic matter. Nineteen classes of predicted, exported peptidases were identified in genomic data from the same site, of which genes for class C25 (gingipain-like) peptidases represented more than 40% at each depth. Methionine aminopeptidases, zinc carboxypeptidases, and class S24-like peptidases, which are involved in single-stranded-DNA repair, were also abundant. These results suggest a subsurface heterotrophic microbial community that primarily accesses low-quality detrital organic matter via a diverse suite of well-adapted extracellular enzymes. Burial of organic carbon in marine and estuarine sediments represents a long-term sink for atmospheric carbon dioxide. Globally, ∼40% of organic carbon burial occurs in anoxic estuaries and deltaic systems. However, the ultimate controls on the amount of organic matter that is buried in sediments, versus oxidized into CO, are poorly constrained. In this study, we used a combination of enzyme assays and metagenomic analysis to identify how subsurface microbial communities catalyze the first step of proteinaceous organic carbon degradation. Our results show that microbial communities in deeper sediments are adapted to access molecules characteristic of degraded organic matter, suggesting that those heterotrophs are adapted to life in the subsurface.
缺氧的底栖沉积物中含有异养微生物群落,它们以极低的速率代谢有机碳。为了评估底栖微生物获取碎屑沉积有机物质的机制,我们测量了北卡罗来纳州白橡河口缺氧沉积物中一系列胞外肽酶的动力学。在所有深度都可以酶解 9 种不同的肽酶底物。潜在的肽酶活性()随沉积物深度的增加而降低,尽管按细胞计算,所有深度的表达基本相同。半饱和常数()随深度降低,表明在低底物浓度下功能更有效的肽酶。作用于富含降解有机物质的分子(d-苯丙氨酸和 l-鸟氨酸)的胞外肽酶的潜在活性相对于作用于 l-苯丙氨酸的酶增加,进一步表明微生物群落适应于获取降解有机物质。从同一地点的基因组数据中鉴定出 19 类预测的分泌性肽酶,其中 C25 类(gingipain 样)肽酶基因在每个深度都超过 40%。甲硫氨酸氨肽酶、锌羧肽酶和参与单链 DNA 修复的 S24 样肽酶也很丰富。这些结果表明,一个主要通过多样化的适应性胞外酶来获取低质量碎屑有机物质的底栖异养微生物群落。海洋和河口沉积物中的有机碳埋藏是大气二氧化碳的长期汇。在全球范围内,约 40%的有机碳埋藏发生在缺氧河口和三角洲系统中。然而,埋藏在沉积物中的有机物质与氧化成 CO 的数量的最终控制因素还没有得到很好的控制。在这项研究中,我们使用酶测定和宏基因组分析相结合的方法,确定了底栖微生物群落如何催化蛋白质有机碳降解的第一步。我们的结果表明,深层沉积物中的微生物群落适应于获取具有降解有机物质特征的分子,这表明这些异养生物适应于地下生活。
