Author
Listed:
- Christopher DelRe
(University of California, Berkeley
Lawrence Berkeley National Laboratory)
- Yufeng Jiang
(University of California, Berkeley
Lawrence Berkeley National Laboratory)
- Philjun Kang
(University of California, Berkeley)
- Junpyo Kwon
(Lawrence Berkeley National Laboratory
University of California, Berkeley)
- Aaron Hall
(University of California, Berkeley)
- Ivan Jayapurna
(University of California, Berkeley)
- Zhiyuan Ruan
(University of California, Berkeley)
- Le Ma
(University of California, Berkeley
Lawrence Berkeley National Laboratory)
- Kyle Zolkin
(University of California, Berkeley)
- Tim Li
(University of California, Berkeley)
- Corinne D. Scown
(Lawrence Berkeley National Laboratory)
- Robert O. Ritchie
(University of California, Berkeley
Lawrence Berkeley National Laboratory
University of California, Berkeley)
- Thomas P. Russell
(Lawrence Berkeley National Laboratory
University of Massachusetts)
- Ting Xu
(University of California, Berkeley
Lawrence Berkeley National Laboratory
University of California, Berkeley)
Abstract
Successfully interfacing enzymes and biomachinery with polymers affords on-demand modification and/or programmable degradation during the manufacture, utilization and disposal of plastics, but requires controlled biocatalysis in solid matrices with macromolecular substrates1–7. Embedding enzyme microparticles speeds up polyester degradation, but compromises host properties and unintentionally accelerates the formation of microplastics with partial polymer degradation6,8,9. Here we show that by nanoscopically dispersing enzymes with deep active sites, semi-crystalline polyesters can be degraded primarily via chain-end-mediated processive depolymerization with programmable latency and material integrity, akin to polyadenylation-induced messenger RNA decay10. It is also feasible to achieve processivity with enzymes that have surface-exposed active sites by engineering enzyme–protectant–polymer complexes. Poly(caprolactone) and poly(lactic acid) containing less than 2 weight per cent enzymes are depolymerized in days, with up to 98 per cent polymer-to-small-molecule conversion in standard soil composts and household tap water, completely eliminating current needs to separate and landfill their products in compost facilities. Furthermore, oxidases embedded in polyolefins retain their activities. However, hydrocarbon polymers do not closely associate with enzymes, as their polyester counterparts do, and the reactive radicals that are generated cannot chemically modify the macromolecular host. This study provides molecular guidance towards enzyme–polymer pairing and the selection of enzyme protectants to modulate substrate selectivity and optimize biocatalytic pathways. The results also highlight the need for in-depth research in solid-state enzymology, especially in multi-step enzymatic cascades, to tackle chemically dormant substrates without creating secondary environmental contamination and/or biosafety concerns.
Suggested Citation
Christopher DelRe & Yufeng Jiang & Philjun Kang & Junpyo Kwon & Aaron Hall & Ivan Jayapurna & Zhiyuan Ruan & Le Ma & Kyle Zolkin & Tim Li & Corinne D. Scown & Robert O. Ritchie & Thomas P. Russell & T, 2021.
"Near-complete depolymerization of polyesters with nano-dispersed enzymes,"
Nature, Nature, vol. 592(7855), pages 558-563, April.
Handle:
RePEc:nat:nature:v:592:y:2021:i:7855:d:10.1038_s41586-021-03408-3
DOI: 10.1038/s41586-021-03408-3
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Citations
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Cited by:
- Halayit Abrha & Jonnathan Cabrera & Yexin Dai & Muhammad Irfan & Abrham Toma & Shipu Jiao & Xianhua Liu, 2022.
"Bio-Based Plastics Production, Impact and End of Life: A Literature Review and Content Analysis,"
Sustainability, MDPI, vol. 14(8), pages 1-20, April.
- Amelia R. Bergeson & Ashli J. Silvera & Hal S. Alper, 2024.
"Bottlenecks in biobased approaches to plastic degradation,"
Nature Communications, Nature, vol. 15(1), pages 1-9, December.
- Jingjing Cao & Huaxing Liang & Jie Yang & Zhiyang Zhu & Jin Deng & Xiaodong Li & Menachem Elimelech & Xinglin Lu, 2024.
"Depolymerization mechanisms and closed-loop assessment in polyester waste recycling,"
Nature Communications, Nature, vol. 15(1), pages 1-12, December.
- Mirsoleimani Azizi, Seyed Mohammad & Haffiez, Nervana & Mostafa, Alsayed & Hussain, Abid & Abdallah, Mohamed & Al-Mamun, Abdullah & Bhatnagar, Amit & Dhar, Bipro Ranjan, 2024.
"Low- and high-temperature thermal hydrolysis pretreatment for anaerobic digestion of sludge: Process evaluation and fate of emerging pollutants,"
Renewable and Sustainable Energy Reviews, Elsevier, vol. 200(C).
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