Department of Proteomics and Microbiology, University of Monsgrid.8364.9, Mons, Belgium.
Materia Nova, Mons, Belgium.
Appl Environ Microbiol. 2022 Mar 22;88(6):e0158621. doi: 10.1128/AEM.01586-21. Epub 2022 Jan 26.
Poly(hydroxybutyrate--hydroxyhexanoate) [P(HB--HHx)] and poly(hydroxybutyrate--hydroxyvalerate-hydroxyhexanoate) [P(HB--HV--HHx)] demonstrate interesting mechanical and thermal properties as well as excellent biocompatibility, making them suitable for multiple applications and notably biomedical purposes. The production of such polymers was described in Rhodospirillum rubrum, a purple nonsulfur bacteria in a nutrient-lacking environment where the HHx synthesis is triggered by the presence of hexanoate in the medium. However, the production of P(HB--HHx) under nutrient-balanced growth conditions in has not been described so far, and the assimilation of hexanoate is poorly documented. In this study, we used proteomic analysis and a mutant fitness assay to demonstrate that hexanoate assimilation involve β-oxidation and the ethylmalonyl-coenzyme A (CoA) (EMC) and methylbutanoyl-CoA (MBC) pathways, both being anaplerotic pathways already described in . Polyhydroxyalkanoate (PHA) production is likely to involve the fatty acid synthesis pathway. Concerning the polymer composition, HB is the main component of the polymer, probably as acetyl-CoA and butyryl-CoA are intermediates of hexanoate assimilation pathways. When no essential nutrient is lacking in the medium, the synthesis of PHA seems to help maintain the redox balance of the cell. In this framework, we showed that the fixation of CO is required to sustain the growth. An increase in the proportion of HHx in the polymer was observed when redox stress was engendered in the cell under bicarbonate-limiting growth conditions. The addition of isoleucine or valerate in the medium also increased the HHx content of the polymer and allowed the production of a terpolymer of P(HB--HV--HHx). The use of purple bacteria, which can assimilate volatile fatty acids, for biotechnological applications has increased, since they reduce the production costs of added-value compounds such as PHA. P(HB--HHx) and P(HB--HV--HHx) have demonstrated interesting properties, notably for biomedical applications. In a nutrient-lacking environment, is known to synthesize such polymers when hexanoate is used as the carbon source. However, their production in in non-nutrient-lacking growth conditions has not been described so far, and the assimilation of hexanoate is poorly documented. As the carbon source and its assimilation directly impact the polymer composition, we studied under non-nutrient-lacking growth conditions the assimilation pathway of hexanoate and PHA production in Proteomic analysis and mutant fitness assays allowed us to explain PHA production and composition. An increase in HHx content of the polymer and production of P(HB--HV--HHx) was possible using the knowledge gained on metabolism under hexanoate growth conditions.
聚(羟基丁酸酯-羟基己酸酯)[P(HB-HHx)]和聚(羟基丁酸酯-羟基戊酸酯-羟基己酸酯)[P(HB-HV-HHx)]具有有趣的机械和热性能以及出色的生物相容性,使其适用于多种应用,尤其是在生物医学领域。这些聚合物的生产在 Rhodospirillum rubrum 中已有描述,Rhodospirillum rubrum 是一种在营养缺乏的环境中的紫色非硫细菌,其中 HHx 的合成是由介质中己酸酯的存在引发的。然而,迄今为止,尚未描述在营养平衡生长条件下生产 P(HB-HHx),并且对己酸酯的同化作用记录甚少。在这项研究中,我们使用蛋白质组学分析和突变体适合度测定来证明己酸酯的同化作用涉及β-氧化和乙基丙二酸辅酶 A(CoA)(EMC)和甲基丁酰 CoA(MBC)途径,这两种途径都是在 中已经描述的氨酰基途径。聚羟基烷酸酯(PHA)的生产可能涉及脂肪酸合成途径。关于聚合物组成,HB 是聚合物的主要成分,可能是因为乙酰辅酶 A 和丁酰辅酶 A 是己酸酯同化途径的中间体。当介质中没有必需的营养物质缺乏时,PHA 的合成似乎有助于维持细胞的氧化还原平衡。在这种情况下,我们表明需要固定 CO 以维持生长。当在碳酸氢盐限制生长条件下引起细胞中的氧化还原应激时,观察到聚合物中 HHx 的比例增加。在介质中添加异亮氨酸或戊酸也增加了聚合物中 HHx 的含量,并允许生产 P(HB-HV-HHx)的三元共聚物。由于可以同化挥发性脂肪酸的紫色细菌增加了用于生物技术应用的价值,因此降低了添加价值化合物(如 PHA)的生产成本。P(HB-HHx)和 P(HB-HV-HHx)已显示出有趣的特性,特别是在生物医学应用中。在缺乏营养的环境中,当己酸酯用作碳源时, 已知会合成此类聚合物。然而,迄今为止,尚未描述在非营养缺乏生长条件下在 中生产,并且对己酸酯的同化作用记录甚少。由于碳源及其同化作用直接影响聚合物组成,因此我们在非营养缺乏生长条件下研究了 中己酸酯的同化途径和 PHA 的生产。蛋白质组学分析和突变体适合度测定使我们能够解释 PHA 的生产和组成。通过利用在己酸酯生长条件下获得的代谢知识,可以增加聚合物中 HHx 的含量并生产 P(HB-HV-HHx)。
