迈向循环生物经济：为生物降解设计微生物和聚合物。

IF 3.9 2区生物学 Q1 BIOCHEMICAL RESEARCH METHODS

ACS Synthetic Biology Pub Date : 2024-06-25 DOI:10.1021/acssynbio.4c00077

Vikram Mubayi, Colleen B. Ahern, Magdalena Calusinska and Michelle A. O’Malley*,

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引用次数: 0

摘要

聚合物生产正在迅速增长，但目前还没有大规模的技术来有效缓解这些难降解材料的大量积累。一种潜在的解决方案是开发碳中和聚合物生命周期，即微生物将植物生物质转化为化学物质，再利用这些化学物质合成可生物降解的材料，最终促进新植物的生长。实现循环碳生命周期需要整合微生物学、生物工程学、材料科学和有机化学等方面的知识，而这些知识本身就阻碍了大规模的工业进步。本综述探讨了常见合成聚合物的生物降解状况，确定了能够代谢这些难降解材料的新型微生物和酶，以及增强其生物降解途径的工程方法。此外，还综述了下一代可生物降解聚合物的设计考虑因素，最后讨论了将木质纤维素生物降解的研究成果应用于类似难降解合成聚合物的设计和生物降解的机会。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Toward a Circular Bioeconomy: Designing Microbes and Polymers for Biodegradation

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Toward a Circular Bioeconomy: Designing Microbes and Polymers for Biodegradation

Polymer production is rapidly increasing, but there are no large-scale technologies available to effectively mitigate the massive accumulation of these recalcitrant materials. One potential solution is the development of a carbon-neutral polymer life cycle, where microorganisms convert plant biomass to chemicals, which are used to synthesize biodegradable materials that ultimately contribute to the growth of new plants. Realizing a circular carbon life cycle requires the integration of knowledge across microbiology, bioengineering, materials science, and organic chemistry, which itself has hindered large-scale industrial advances. This review addresses the biodegradation status of common synthetic polymers, identifying novel microbes and enzymes capable of metabolizing these recalcitrant materials and engineering approaches to enhance their biodegradation pathways. Design considerations for the next generation of biodegradable polymers are also reviewed, and finally, opportunities to apply findings from lignocellulosic biodegradation to the design and biodegradation of similarly recalcitrant synthetic polymers are discussed.

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来源期刊

ACS Synthetic Biology 生物-

CiteScore

8.00

自引率

10.60%

发文量

380

审稿时长

6-12 weeks

期刊介绍： The journal is particularly interested in studies on the design and synthesis of new genetic circuits and gene products; computational methods in the design of systems; and integrative applied approaches to understanding disease and metabolism. Topics may include, but are not limited to: Design and optimization of genetic systems Genetic circuit design and their principles for their organization into programs Computational methods to aid the design of genetic systems Experimental methods to quantify genetic parts, circuits, and metabolic fluxes Genetic parts libraries: their creation, analysis, and ontological representation Protein engineering including computational design Metabolic engineering and cellular manufacturing, including biomass conversion Natural product access, engineering, and production Creative and innovative applications of cellular programming Medical applications, tissue engineering, and the programming of therapeutic cells Minimal cell design and construction Genomics and genome replacement strategies Viral engineering Automated and robotic assembly platforms for synthetic biology DNA synthesis methodologies Metagenomics and synthetic metagenomic analysis Bioinformatics applied to gene discovery, chemoinformatics, and pathway construction Gene optimization Methods for genome-scale measurements of transcription and metabolomics Systems biology and methods to integrate multiple data sources in vitro and cell-free synthetic biology and molecular programming Nucleic acid engineering.