Department of Chemical and Materials Engineering, University of Alberta, Edmonton, Alberta, T6G 1H9, Canada.
Appl Microbiol Biotechnol. 2018 Sep;102(18):8049-8067. doi: 10.1007/s00253-018-9153-8. Epub 2018 Jun 27.
The biodegradation of polyhydroxybutyrate (PHB) has been broadly investigated, but studies typically focus on a single strain or enzyme and little attention has been paid to comparing the interaction of different PHB depolymerase (PhaZ)-producing strains with this biopolymer. In this work, we selected nine bacterial strains-five with demonstrated and four with predicted PhaZ activity-to compare their effectiveness at degrading PHB film provided as sole carbon source. Each of the strains with demonstrated activity were able to use the PHB film (maximum mass losses ranging from 12% after 2 days for Paucimonas lemoignei to 90% after 4 days for Cupriavidus sp.), and to a lower extent Marinobacter algicola DG893 (with a predicted PhaZ) achieved PHB film mass loss of 11% after 2 weeks of exposure. Among the strains with proven PhaZ activity, Ralstonia sp. showed the highest specific activity since less biomass was required to degrade the polymer in comparison to the other strains. In the case of Ralstonia sp., PHB continued to be degraded at pH values as low as pH 3.3-3.7. In addition, analysis of the extracellular fractions of the strains with demonstrated activity showed that Comamonas testosteroni, Cupriavidus sp., and Ralstonia sp. readily degraded both PHB film and PHB particles in agar suspensions. This study highlights that whole cell cultures and enzymatic (extracellular) fractions display different levels of activity, an important factor in the development of PHB-based applications and in understanding the fate of PHB and other PHAs released in the environment. Furthermore, predictions of PhaZ functionality from genome sequencing analyses remain to be validated by experimental results; PHB-degrading ability could not be proven for three of four investigated species predicted by the polyhydroxyalkanoates (PHA) depolymerase engineering database.
聚羟基丁酸酯 (PHB) 的生物降解已得到广泛研究,但研究通常集中在单个菌株或酶上,很少关注比较不同 PHB 解聚酶 (PhaZ) 产生菌株与这种生物聚合物的相互作用。在这项工作中,我们选择了九种细菌菌株-五种具有证明的和四种具有预测的 PhaZ 活性-以比较它们降解作为唯一碳源提供的 PHB 薄膜的有效性。具有证明活性的菌株都能够使用 PHB 薄膜(最大质量损失范围从 2 天后的 Paucimonas lemoignei 的 12%到 4 天后 Cupriavidus sp. 的 90%),并且 Marinobacter algicola DG893 的程度较低(预测有 PhaZ)在暴露 2 周后 PHB 薄膜的质量损失达到 11%。在具有证明 PhaZ 活性的菌株中,Ralstonia sp. 显示出最高的比活性,因为与其他菌株相比,降解聚合物所需的生物量更少。在 Ralstonia sp. 的情况下,PHB 继续在低至 pH 3.3-3.7 的 pH 值下降解。此外,对具有证明活性的菌株的细胞外部分的分析表明,Comamonas testosteroni、Cupriavidus sp. 和 Ralstonia sp. 很容易在琼脂悬浮液中降解 PHB 薄膜和 PHB 颗粒。这项研究强调了完整细胞培养物和酶(细胞外)部分显示出不同水平的活性,这是 PHB 基应用开发和理解 PHB 和其他在环境中释放的 PHAs 命运的重要因素。此外,从基因组测序分析预测的 PhaZ 功能仍有待实验结果验证;无法证明聚羟基烷酸酯 (PHA) 解聚酶工程数据库预测的四种研究物种中的三种具有 PHB 降解能力。
