Bacterial species-structure-property relationships of polyhydroxyalkanoate biopolymers produced on simple sugars for thin film applications.

IF 4.9 2区生物学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Microbial Cell Factories Pub Date : 2025-09-16 DOI:10.1186/s12934-025-02833-7

Edward Attenborough, Farin Yazdan Parast, Reza Nosrati, Mark M Banaszak Holl, Leonie van 't Hag

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引用次数: 0

Abstract

Background: The bacterial production of polyhydroxyalkanoates (PHAs), a class of non-toxic, biodegradable, and bio-based polymers, has gained increasing attention as a sustainable alternative to petrochemical plastics. Among PHA producers, Cupriavidus necator H16 and Pseudomonas putida KT2440 are used for their ability to synthesise short- and medium-chain-length PHAs, respectively. While PHAs have been produced from simple hexoses like glucose and fructose, there remains a lack of systematic and integrated analysis linking carbon source, strain selection, monomer composition, and polymer crystallinity to blend behavior in ultrathin films.

Results: PHB and mcl-PHA production using Cupriavidus necator H16 and Pseudomonas putida KT2440 on glucose and fructose were compared herein. C. necator accumulated PHB up to 60 wt% on fructose and 45 wt% on glucose, with high molecular weight (0.7-1.3 MDa), while P. putida produced mcl-PHA up to 22 wt% on fructose and 18 wt% on glucose, with lower molecular weight (46-47 kDa) and a C6 - C12 monomer profile. Notably, C. necator exhibited extreme cell elongation (up to 30 μm) during PHB accumulation on fructose. Extracted polymers were systematically solvent-blended at defined ratios (100:0, 80:20, 60:40, 40:60, and 20:80 PHB:mcl-PHA) and cast into ultrathin films (~ 20 μm) with varying composition. Crystallinity was modelled using a Gaussian fitting approach on FTIR spectra via custom MATLAB code, enabling localised phase analysis and offering a rapid alternative to DSC for thin film crystallinity estimation. While film blends exhibited tunable crystallinity and multiple melting transitions, elongation at break was consistent across compositions, with increases observed at higher mcl-PHA content.

Conclusions: This study provides a systematic comparison of PHAs from C. necator H16 and P. putida KT2440 grown on common hexoses, with full characterisation of monomer composition, molecular weight, and thermal behaviour to guide thin film bioplastic design. Blending PHB and mcl-PHA in ultrathin films revealed reduced melting points and crystallinity, likely due to reduced crystal size from film thickness constraints. This work offers a comparative reference for microbial PHA production and presents a strategy to design bioplastics with tunable properties for temperature-responsive packaging and drug delivery applications.

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用单糖制备薄膜用聚羟基烷酸酯生物聚合物的细菌种类-结构-性质关系。

背景：细菌生产聚羟基烷酸酯（PHAs）是一类无毒、可生物降解的生物基聚合物，作为石化塑料的可持续替代品而受到越来越多的关注。在PHA产生菌中，Cupriavidus necator H16和Pseudomonas putida KT2440分别因其合成短链和中链长的PHA的能力而被使用。虽然已经从葡萄糖和果糖等简单的己糖中制备了相芳烃，但仍然缺乏将碳源、菌株选择、单体组成和聚合物结晶度与超薄膜中的混合行为联系起来的系统和综合分析。结果：比较了Cupriavidus necator H16和Pseudomonas putida KT2440对葡萄糖和果糖产生的PHB和mcl-PHA。C. necator在果糖和葡萄糖上积累的PHB分别高达60 wt%和45 wt%，具有高分子量（0.7-1.3 MDa），而P. putida在果糖和葡萄糖上产生的mcl-PHA分别高达22 wt%和18 wt%，具有较低分子量（46-47 kDa）和C6 - C12单体谱。值得注意的是，C. necator在PHB对果糖的积累过程中表现出极端的细胞伸长（高达30 μm）。提取的聚合物按规定的比例（PHB:mcl-PHA: 100:0、80:20、60:40、40:60和20:80）进行系统的溶剂混合，并浇铸成不同成分的超薄薄膜（~ 20 μm）。通过定制的MATLAB代码，使用FTIR光谱的高斯拟合方法对结晶度进行建模，从而实现局部相分析，并为薄膜结晶度估计提供快速替代DSC的方法。虽然共混膜的结晶度和熔融转变可调，但断裂伸长率在各组分中是一致的，在mcl-PHA含量较高时观察到增加。结论：本研究提供了C. necator H16和P. putida KT2440在普通己糖上生长的pha的系统比较，并充分表征了单体组成、分子量和热行为，以指导薄膜生物塑料的设计。PHB和mcl-PHA在超薄膜中混合显示熔点和结晶度降低，可能是由于薄膜厚度限制导致晶体尺寸减小。这项工作为微生物PHA生产提供了比较参考，并提出了一种设计具有可调性能的生物塑料的策略，用于温度响应包装和药物输送应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Microbial Cell Factories 工程技术-生物工程与应用微生物

CiteScore

9.30

自引率

4.70%

发文量

235

审稿时长

2.3 months

期刊介绍： Microbial Cell Factories is an open access peer-reviewed journal that covers any topic related to the development, use and investigation of microbial cells as producers of recombinant proteins and natural products, or as catalyzers of biological transformations of industrial interest. Microbial Cell Factories is the world leading, primary research journal fully focusing on Applied Microbiology. The journal is divided into the following editorial sections: -Metabolic engineering -Synthetic biology -Whole-cell biocatalysis -Microbial regulations -Recombinant protein production/bioprocessing -Production of natural compounds -Systems biology of cell factories -Microbial production processes -Cell-free systems