Fernandez-Lopez Laura, Sanchez-Carrillo Sergio, García-Moyano Antonio, Borchert Erik, Almendral David, Alonso Sandra, Cea-Rama Isabel, Miguez Noa, Larsen Øivind, Werner Johannes, Makarova Kira S, Plou Francisco J, Dahlgren Thomas G, Sanz-Aparicio Julia, Hentschel Ute, Bjerga Gro Elin Kjæreng, Ferrer Manuel
CSIC, Institute of Catalysis, 28049 Madrid, Spain.
NORCE Norwegian Research Centre, P.O. Box 22 Nygårdstangen, 5838 Bergen, Norway.
Comput Struct Biotechnol J. 2021 Nov 23;19:6328-6342. doi: 10.1016/j.csbj.2021.11.027. eCollection 2021.
Many microorganisms feed on the tissue and recalcitrant bone materials from dead animals, however little is known about the collaborative effort and characteristics of their enzymes. In this study, microbial metagenomes from symbionts of the marine bone-dwelling worm , and from microbial biofilms growing on experimentally deployed bone surfaces were screened for specialized bone-degrading enzymes. A total of 2,043 taxonomically (closest match within 40 phyla) and functionally (1 proteolytic and 9 glycohydrolytic activities) diverse and non-redundant sequences (median pairwise identity of 23.6%) encoding such enzymes were retrieved. The taxonomic assignation and the median identity of 72.2% to homologous proteins reflect microbial and functional novelty associated to a specialized bone-degrading marine community. Binning suggests that only one generalist hosting all ten targeted activities, working in synergy with multiple specialists hosting a few or individual activities. Collagenases were the most abundant enzyme class, representing 48% of the total hits. A total of 47 diverse enzymes, representing 8 hydrolytic activities, were produced in , whereof 13 were soluble and active. The biochemical analyses revealed a wide range of optimal pH (4.0-7.0), optimal temperature (5-65 °C), and of accepted substrates, specific to each microbial enzyme. This versatility may contribute to a high environmental plasticity of bone-degrading marine consortia that can be confronted to diverse habitats and bone materials. Through bone-meal degradation tests, we further demonstrated that some of these enzymes, particularly those from and , may be an asset for development of new value chains in the biorefinery industry.
许多微生物以死动物的组织和难降解的骨材料为食,然而对于它们酶的协同作用和特性却知之甚少。在本研究中,对来自海洋栖骨蠕虫共生体的微生物宏基因组,以及在实验部署的骨表面生长的微生物生物膜进行筛选,以寻找专门的骨降解酶。总共检索到2043个分类学上(在40个门内最接近的匹配)和功能上(1种蛋白水解活性和9种糖水解活性)多样且非冗余的编码此类酶的序列(中位成对同一性为23.6%)。分类学归属以及与同源蛋白72.2%的中位同一性反映了与专门的骨降解海洋群落相关的微生物和功能新颖性。分箱分析表明只有一个具有所有十种目标活性的多面手,与多个具有几种或单个活性的专家协同工作。胶原酶是最丰富的酶类,占总命中数的48%。在[具体条件未给出]中总共产生了47种代表8种水解活性的不同酶,其中13种是可溶且有活性的。生化分析揭示了每种微生物酶特有的广泛的最佳pH值(4.0 - 7.0)、最佳温度(5 - 65°C)和可接受底物范围。这种多功能性可能有助于骨降解海洋菌群具有高环境可塑性,使其能够面对不同的栖息地和骨材料。通过骨粉降解试验,我们进一步证明其中一些酶,特别是来自[具体来源未给出]和[具体来源未给出]的酶,可能是生物炼制行业新价值链开发的一项资产。
