耐热MHET水解酶的计算重设计及其作为endo-PETase在促进PET解聚中的作用

doi:10.1016/S1872-2067(25)64802-9

催化学报 ›› 2025, Vol. 78: 182-191.DOI: 10.1016/S1872-2067(25)64802-9

耐热MHET水解酶的计算重设计及其作为endo-PETase在促进PET解聚中的作用

刘晓萌^a^,^b^,¹, 陈泽华^a^,¹, 刘欣悦^a, 朱彤^a, 孙瑨原^a, 李春立^c^,^d^,^*(), 崔颖璐^a^,^d^,^e^,^*(), 吴边^a^,^f^,^*()

^aAIM中心, 北京化工大学生命科学与技术学院, 中国科学院微生物研究所, 北京 100101
^b中国科学院大学存济医学院, 北京 100101
^c中国科学院微生物研究所, 北京 100101
^d微生物多样性与资源创新利用全国重点实验室, 北京 100101
^e合成生物制造元件智能创制北京市重点实验室, 北京 100101
^f绿色生物制造全国重点实验室, 北京 100101

收稿日期:2025-04-26 接受日期:2025-07-01 出版日期:2025-11-18 发布日期:2025-10-14
通讯作者: *电子信箱: licl@im.ac.cn (李春立), cuiyinglu@im.ac.cn (崔颖璐), thebianwu@outlook.com (吴边).
作者简介:¹共同第一作者.
基金资助:
国家重点研发计划(2023YFC3905000);国家自然科学基金(32170033);国家自然科学基金(32225002);国家自然科学基金(32422001);中国科学院战略先导研究专项(XDB0810000);中国科学院生物资源项目(KFJ-BRP-009);北京市科技计划项目(Z241100007724009);中国科学院生物资源项目(KFJ-BRP-017-58);中国科学院青年创新促进会(2022086)

Computational redesign of a thermostable MHET hydrolase and its role as an endo-PETase in promoting PET depolymerization

Xiaomeng Liu^a^,^b^,¹, Zehua Chen^a^,¹, Xinyue Liu^a, Tong Zhu^a, Jinyuan Sun^a, Chunli Li^c^,^d^,^*(), Yinglu Cui^a^,^d^,^e^,^*(), Bian Wu^a^,^f^,^*()

^aAIM Center, College of Life Sciences and Technology, Beijing University of Chemical Technology, Institute of Microbiology, Chinese Academy of Sciences, Beijing 100101, China
^bCunji Medical College, University of Chinese Academy of Sciences, Beijing 100101, China
^cInstitute of Microbiology, Chinese Academy of Sciences, Beijing 100101, China
^dState Key Laboratory of Microbial Diversity and Innovative Utilization, Beijing 100101, China
^eBeijing Key Laboratory of Genetic Element Biosourcing & Intelligent Design for Biomanufacturing, Beijing 100101, China
^fState Key Laboratory of Green Manufacturing, Beijing 100101, China

Received:2025-04-26 Accepted:2025-07-01 Online:2025-11-18 Published:2025-10-14
Contact: *E-mail: licl@im.ac.cn (C. Li), cuiyinglu@im.ac.cn (Y. Cui), thebianwu@outlook.com (B. Wu).
About author:¹Contributed equally to this work.
Supported by:
National Key R&D Program of China(2023YFC3905000);National Natural Science Foundation of China(32170033);National Natural Science Foundation of China(32225002);National Natural Science Foundation of China(32422001);Strategic Priority Research Program of the Chinese Academy of Sciences(XDB0810000);Biological Resources Program (KFJ-BRP-009, KFJ-BRP-017-58) from the Chinese Academy of Sciences, Beijing Municipal Science & Technology Project, China(Z241100007724009);Youth Innovation Promotion Association CAS(2022086)

摘要/Abstract

摘要：

随着塑料污染问题日益严峻和循环经济战略的持续推进, 酶法塑料解聚与再生技术因其绿色、高效、环境友好等特点受到广泛关注, 尤其在聚对苯二甲酸乙二醇酯(PET)的回收再利用方面展现出巨大的潜力. 近年来, 尽管多种高温高效的PET水解酶不断涌现, 但仍面临诸多问题, 如中间产物引发的产物抑制效应、降解终产物组成复杂等问题, 严重制约了PET产物的高值利用. 因此, 开发可在高温下协同降解中间产物的水解酶, 构建高效、产物单一的塑料酶解体系, 对于缓解产物抑制、简化产物分离流程, 推动酶法再生走向产业化具有重要意义.

本文围绕PET酶解过程中的关键中间产物对苯二甲酸单(2-羟乙基)酯(MHET)积累问题, 采用课题组自主开发的蛋白质计算稳定性设计策略——greedy accumulated strategy for protein engineering(GRAPE), 以天然MHET水解酶(IsMHETase)为模板, 构建了耐热突变体DuraMHETase (A66P/S136E/T159V/M192F/T328R/A330K/A333R/Q410F/S413N/T434D/A501I/ A509K/S561V). DuraMHETase在与底物结合状态下的表观熔融温度达72 °C, 在60 °C反应条件下的总转换数(TTN)较野生型收获了6倍的提升, 展现出较好的热稳定性与催化效率. 将DuraMHETase与多种高效PET水解酶联合使用, 均显著促进了PET降解效率; 进一步构建的DuraMHETase-TurboPETase融合蛋白不仅提升了整体降解性能, 还实现了高达99%以上的TPA终产物纯度. 为探究热稳定性提升的结构基础, 本文通过分子动力学模拟分析了突变对蛋白质构象的影响, 发现优化的静电相互作用、更紧密的疏水核心堆积以及未折叠区域构象熵的降低, 是增强稳定性的主要贡献因素. 同时, 本文在验证该酶具有外切型PET酶(exo-PETase)活性的基础上, 首次观察到其对环状五聚PET(PET₅)及未预处理无定形PET膜的降解能力, 揭示该酶兼具内切型PET酶(endo-PETase)与外切型PET酶(exo-PETase)活性. 进一步分析发现, endo-PETase活性在此类酶中具有一定普遍性, 提示其在PET酶法协同降解中的潜在重要作用.

综上, 本文基于计算设计成功获得了具备良好热稳定性的PET降解协同酶DuraMHETase, 并通过构建融合酶体系有效缓解了产物抑制, 提升了酶法解聚过程的产物纯度与整体效率. 同时, 首次揭示了MHETase的endo-PETase活性, 拓展了其功能认识, 为多功能协同酶体系的构建提供了新思路和理论基础. 展望未来, 基于多功能酶的理性设计与高效协同, 或将进一步推动酶法塑料再生技术向绿色、高效及工业化方向发展.

关键词: 酶的计算重设计, 生物催化, 塑料降解, 酶机理, 热稳定性

Abstract:

Biotechnological strategies for plastic depolymerization and recycling have emerged as transformative approaches to combat the global plastic pollution crisis, aligning with the principles of a sustainable and circular economy. Despite advances in engineering PET hydrolases, the degradation process is frequently compromised by product inhibition and the heterogeneity of final products, thereby obstructing subsequent PET recondensation and impeding the synthesis of high-value derivatives. In this work, we utilized previously devised computational strategies to redesign a thermostable DuraMHETase, achieving an apparent melting temperature of 72 °C in complex with MHET and a 6-fold higher in total turnover number (TTN) toward MHET than the wild-type enzyme at 60 °C. The fused enzyme system composed of DuraMHETase and TurboPETase demonstrated higher efficiency than other PET hydrolases and the separated dual enzyme systems. Furthermore, we identified both exo- and endo-PETase activities in DuraMHETase, whereas the endo- activity was previously unobserved at ambient temperatures. These results expand the functional scope of MHETase beyond mere intermediate hydrolysis, and may provide guidance for the development of more synergistic approaches to plastic biodepolymerization and recycling.

Key words: Computational enzyme redesign, Biocatalysis, Plastic degradation, Enzyme mechanism, Thermostability

刘晓萌, 陈泽华, 刘欣悦, 朱彤, 孙瑨原, 李春立, 崔颖璐, 吴边. 耐热MHET水解酶的计算重设计及其作为endo-PETase在促进PET解聚中的作用[J]. 催化学报, 2025, 78: 182-191.

Xiaomeng Liu, Zehua Chen, Xinyue Liu, Tong Zhu, Jinyuan Sun, Chunli Li, Yinglu Cui, Bian Wu. Computational redesign of a thermostable MHET hydrolase and its role as an endo-PETase in promoting PET depolymerization[J]. Chinese Journal of Catalysis, 2025, 78: 182-191.

×
扫码分享

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://www.cjcatal.com/CN/10.1016/S1872-2067(25)64802-9

https://www.cjcatal.com/CN/Y2025/V78/I11/182

图/表 4

Fig. 1. Thermostable mutant DuraMHETase obtained via the GRAPE strategy. (a) The GRAPE strategy comprises three sequential steps: generation of a single-point mutation library, clustering of beneficial mutations, and combination of mutations within each cluster through a greedy approach. (b) The accumulation process of the beneficial mutations using the GRAPE strategy. Mutants were selected in each round based on the MHET hydrolytic activity and thermal stability. MHET hydrolysis activity was determined by measuring the TPA production after subtracting chemical hydrolysis background. Reactions were performed with 40 mmol/L MHET, 39 nmol/L enzyme in 100 mmol/L phosphate buffer (pH = 7.0) for 2 h at 58 °C for the mutations in the 1st cluster and at 60 °C for the mutations in the 2nd and 3rd clusters. Data are from one independent experiment. (c) Time-course hydrolysis of MHET by IsMHETase (wild-type), DuraMHETase (M13), and other intermediate-hydrolyzing enzymes at 60 °C. MHET hydrolysis activity was determined by measuring the TPA production after subtracting chemical hydrolysis background. Reactions were performed with 40 mmol/L MHET, 39 nmol/L enzyme in 100 mmol/L phosphate buffer (pH = 7.0) (Fig. S1) for 8 h at 60 °C. Each experiment was performed in triplicate (n = 3).

Fig. 2. Dual- and fusion-enzyme systems combining DuraMHETase with thermostable PET hydrolases on Gf-PET Films (?8 mm, ~15 mg, 7% crystallinity) (a) Time course comparison of total product release (TPA+MHET+BHET) between the dual-enzyme systems and PETase-only controls. Bar colors represent individual degradation products: TPA (medium purple), MHET (light purple), and BHET (black). Circles represent PETase-only reactions and diamonds represent dual-enzyme reactions, respectively. Reactions were conducted in 50 mmol/L phosphate buffer (pH 8.0) with 30 gPET/kg substrate loading and 0.1 μmol/L enzyme loading of PETases. The molar ratio of PETase to DuraMHETase was 1:0.3. DepoPETase and FastPETase were assayed at 50 °C; PES-H1L92F/Q94Y, HotPETase, LCCICCG, and TurboPETase were assayed at 60 °C. Each experiment was performed in triplicate (n = 3). (b) Degradation of PET film using DT at 60 °C. Reaction were performed with an enzyme loading of 1 μmol/L and a substrate concentration of 30 gPET/kg. Each experiment was performed in triplicate (n = 3). (c) SEM images showing the effects of the fusion enzyme on PET degradation.

Fig. 3. Overall structure and key mutations of DuraMHETase. (a) The Q410F mutation may introduce a π-π stacking interaction between W397, F415, and the aromatic ring of MHET. (b) The overall structure of DuraMHETase, with α-helices colored blue, β-sheets colored purple, and key mutations highlighted in pink. (c) The S413N mutation may enhance the hydrogen bond network involving D276, Q278, N407, and S413. (d) The S136E mutation is suggested to strengthen the hydrogen bond between E136 and N168. (e) The homologous protein AoFaeB is shown as a dimer in its crystal structure, whereas IsMHETase exists as a monomer. The extended loop between residues 320 and 340 in IsMHETase and DuraMHETase may interfere dimerization.

Fig. 4. The exo-PETase and endo-PETase activities of MHETase. (a) Time-course analysis of exo-PETase activity at 60 °C by IsMHETase (wild-type) and DuraMHETase. The PET films were pretreated by TurboPETase to allow for preliminary degradation, generating additional PET chain ends. After incubation, the films were removed from the TurboPETase enzyme solution and immersed in water for 3 h, followed by one methanol wash and three water washes. Subsequently, the dried pretreated films were hydrolyzed by 1 μmol/L MHETases in 50 mmol/L phosphate buffer (pH = 8.0) for 8 h. Exo-PETase activity was determined by measuring the total released products (TPA+MHET+BHET) after subtracting background control values. Each experiment was performed in triplicate (n = 3). (b) Schematic representation of exo-PETase and endo-PETase mechanisms. (c) Endo-PETase activity of well-known intermediate-hydrolyzing enzymes over 24 h at 63 °C. The untreated PET films were hydrolyzed by MHETases using an enzyme loading of 1 μmol/L in 50 mmol/L phosphate buffer (pH = 8.0) at 63 °C for 24 h. Each experiment was performed in triplicate (n = 3).

参考文献

[1]	A. D. Barnosky, E. A. Hadly, J. Bascompte, E. L. Berlow, J. H. Brown, M. Fortelius, W. M. Getz, J. Harte, A. Hastings, P. A. Marquet, N. D. Martinez, A. Mooers, P. Roopnarine, G. Vermeij, J. W. Williams, R. Gillespie, J. Kitzes, C. Marshall, N. Matzke, D. P. Mindell, E. Revilla, A. B. Smith, Nature, 2012, 486, 52-58.
[2]	C. J. Moore, Environ. Res., 2008, 108, 131-139.
[3]	J. R. Jambeck, R. Geyer, C. Wilcox, T. R. Siegler, M. Perryman, A. Andrady, R. Narayan, K. L. Law, Science, 2015, 347, 768-771.
[4]	R. G. Santos, G. E. Machovsky-Capuska, R. Andrades, Science, 2021, 373, 56-60.
[5]	M. MacLeod, H. P. H. Arp, M. B. Tekman, A. Jahnke, Science, 2021, 373, 61-65.
[6]	N. Simon, K. Raubenheimer, N. Urho, S. Unger, D. Azoulay, T. Farrelly, J. Sousa, H. van Asselt, G. Carlini, C. Sekomo, M. L. Schulte, P.-O. Busch, N. Wienrich, L. Weiand, Science, 2021, 373, 43-47.
[7]	T. Narancic, S. Verstichel, S. Reddy Chaganti, L. Morales-Gamez, S. T. Kenny, B. De Wilde, R. Babu Padamati, K. E. O’Connor, Environ. Sci. Technol., 2018, 52, 10441-10452.
[8]	J. Guo, S. Ali, M. Xu, Green Carbon, 2023, 1, 150-153.
[9]	I. Taniguchi, S. Yoshida, K. Hiraga, K. Miyamoto, Y. Kimura, K. Oda, ACS Catal., 2019, 9, 4089-4105.
[10]	H. Lu, D. J. Diaz, N. J. Czarnecki, C. Zhu, W. Kim, R. Shroff, D. J. Acosta, B. R. Alexander, H. O. Cole, Y. Zhang, N. A. Lynd, A. D. Ellington, H. S. Alper, Nature, 2022, 604, 662-667.
[11]	E. L. Bell, R. Smithson, S. Kilbride, J. Foster, F. J. Hardy, S. Ramachandran, A. A. Tedstone, S. J. Haigh, A. A. Garforth, P. J. R. Day, C. Levy, M. P. Shaver, A. P. Green, Nat. Catal., 2022, 5, 673-681.
[12]	L. Pfaff, J. Gao, Z. Li, A. Jäckering, G. Weber, J. Mican, Y. Chen, W. Dong, X. Han, C. G. Feiler, Y.-F. Ao, C. P. S. Badenhorst, D. Bednar, G. J. Palm, M. Lammers, J. Damborsky, B. Strodel, W. Liu, U. T. Bornscheuer, R. Wei, ACS Catal., 2022, 12, 9790-9800.
[13]	Y. Cui, Y. Chen, X. Liu, S. Dong, Y.-E. Tian, Y. Qiao, R. Mitra, J. Han, C. Li, X. Han, W. Liu, Q. Chen, W. Wei, X. Wang, W. Du, S. Tang, H. Xiang, H. Liu, Y. Liang, K. N. Houk, B. Wu, ACS Catal., 2021, 11, 1340-1350.
[14]	L. Shi, P. Liu, Z. Tan, W. Zhao, J. Gao, Q. Gu, H. Ma, H. Liu, L. Zhu, Angew. Chem. Int. Ed., 2023, 62, e202218390.
[15]	V. Tournier, C. M. Topham, A. Gilles, B. David, C. Folgoas, E. Moya-Leclair, E. Kamionka, M.-L. Desrousseaux, H. Texier, S. Gavalda, M. Cot, E. Guémard, M. Dalibey, J. Nomme, G. Cioci, S. Barbe, M. Chateau, I. André, S. Duquesne, A. Marty, Nature, 2020, 580, 216-219.
[16]	Y. Cui, Y. Chen, J. Sun, T. Zhu, H. Pang, C. Li, W.-C. Geng, B. Wu, Nat. Commun., 2024, 15, 1417.
[17]	R. Wei, D. Breite, C. Song, D. Gräsing, T. Ploss, P. Hille, R. Schwerdtfeger, J. Matysik, A. Schulze, W. Zimmermann, Adv. Sci., 2019, 6, 1900491.
[18]	M. Barth, R. Wei, T. Oeser, J. Then, J. Schmidt, F. Wohlgemuth, W. Zimmermann, J. Membr. Sci., 2015, 494, 182-187.
[19]	S. Yoshida, K. Hiraga, T. Takehana, I. Taniguchi, H. Yamaji, Y. Maeda, K. Toyohara, K. Miyamoto, Y. Kimura, K. Oda, Science, 2016, 351, 1196-1199.
[20]	B. C. Knott, E. Erickson, M. D. Allen, J. E. Gado, R. Graham, F. L. Kearns, I. Pardo, E. Topuzlu, J. J. Anderson, H. P. Austin, G. Dominick, C. W. Johnson, N. A. Rorrer, C. J. Szostkiewicz, V. Copié, C. M. Payne, H. L. Woodcock, B. S. Donohoe, G. T. Beckham, J. E. McGeehan, Proc. Natl. Acad. Sci. U. S. A., 2020, 117, 25476-25485.
[21]	G. von Haugwitz, X. Han, L. Pfaff, Q. Li, H. Wei, J. Gao, K. Methling, Y. Ao, Y. Brack, J. Mican, C. G. Feiler, M. S. Weiss, D. Bednar, G. J. Palm, M. Lalk, M. Lammers, J. Damborsky, G. Weber, W. Liu, U. T. Bornscheuer, R. Wei, ACS Catal., 2022, 12, 15259-15270.
[22]	J. Zhang, H. Wang, Z. Luo, Z. Yang, Z. Zhang, P. Wang, M. Li, Y. Zhang, Y. Feng, D. Lu, Y. Zhu, Commun. Biol., 2023, 6, 1135.
[23]	A. Li, Y. Sheng, H. Cui, M. Wang, L. Wu, Y. Song, R. Yang, X. Li, H. Huang, Nat. Commun., 2023, 14, 4169.
[24]	A. Mrigwani, B. Thakur, P. Guptasarma, Green Chem., 2022, 24, 6707-6719.
[25]	R. Guerois, J. E. Nielsen, L. Serrano, J. Mol. Biol., 2002, 320, 369-387.
[26]	E. H. Kellogg, A. Leaver-Fay, D. Baker, Proteins Struct. Funct. Bioinform., 2011, 79, 830-838.
[27]	P. Xiong, M. Wang, X. Zhou, T. Zhang, J. Zhang, Q. Chen, H. Liu, Nat. Commun., 2014, 5, 5330.
[28]	T. Zhu, J. Sun, H. Pang, B. Wu, JACS Au, 2024, 4, 788-797.
[29]	R. J. Floor, H. J. Wijma, D. I. Colpa, A. Ramos-Silva, P. A. Jekel, W. Szymański, B. L. Feringa, S. J. Marrink, D. B. Janssen, ChemBioChem, 2014, 15, 1660-1672.
[30]	J. Jumper, R. Evans, A. Pritzel, T. Green, M. Figurnov, O. Ronneberger, K. Tunyasuvunakool, R. Bates, A. Žídek, A. Potapenko, A. Bridgland, C. Meyer, S. A. A. Kohl, A.J. Ballard, A. Cowie, B. Romera-Paredes, S. Nikolov, R. Jain, J. Adler, T. Back, S. Petersen, D. Reiman, E. Clancy, M. Zielinski, M. Steinegger, M. Pacholska, T. Berghammer, S. Bodenstein, D. Silver, O. Vinyals, A. W. Senior, K. Kavukcuoglu, P. Kohli, D. Hassabis, Nature, 2021, 596, 583-589.
[31]	D. A. Case, R. M. Betz, D. S. Cerutti, T. E. Cheatham III, T. A. Darden, R. E. Duke, T. J. Giese, H. Gohlke, A. W. Goetz, N. Homeyer, S. Izadi, P. Janowski, J. Kaus, A. Kovalenko, T. S. Lee, S. LeGrand, P. Li, C. Lin, T. Luchko, R. Luo, B. Madej, D. Mermelstein, K. M. Merz, G. Monard, H. Nguyen, H. T. Nguyen, I. Omelyan, A. Onufriev, D. R. Roe, A. Roitberg, C. Sagui, C. L. Simmerling, W. M. Botello-Smith, J. Swails, R. C. Walker, J. Wang, R. M. Wolf, X. Wu, L. Xiao, P. A. Kollman, AMBER 2016, University of California, San Francisco, 2016.
[32]	G. J. Palm, L. Reisky, D. Böttcher, H. Müller, E. A. P. Michels, M. C. Walczak, L. Berndt, M. S. Weiss, U. T. Bornscheuer, G. Weber, Nat. Commun., 2019, 10, 1717.
[33]	H.-Y. Sagong, H. Seo, T. Kim, H. F. Son, S. Joo, S. H. Lee, S. Kim, J.-S. Woo, S. Y. Hwang, K.-J. Kim, ACS Catal., 2020, 10, 4805-4812.
[34]	K. Suzuki, A. Hori, K. Kawamoto, R. R. Thangudu, T. Ishida, K. Igarashi, M. Samejima, C. Yamada, T. Arakawa, T. Wakagi, T. Koseki, S. Fushinobu, Proteins Struct. Funct. Bioinform., 2014, 82, 2857-2867.

耐热MHET水解酶的计算重设计及其作为endo-PETase在促进PET解聚中的作用

Computational redesign of a thermostable MHET hydrolase and its role as an endo-PETase in promoting PET depolymerization

RichHTML

PDF

Supporting Information

可视化

摘要/Abstract

引用本文

使用本文

扫码分享

图/表 4

参考文献

相关文章 15

编辑推荐

Metrics

[1]	衣启松, 林露, 耿华伟, 陈少华, 邵元超, 何平, 刘志峰, 许海梅, 陈铁红, 刘远帅, Valentin Valtchev. 氟离子介导酸性体系合成H-ZSM-5分子筛及其液相环己醇催化转化性能研究[J]. 催化学报, 2025, 74(7): 97-107.
[2]	潘文进, 范鑫龙, 蒋宛彤, 辛思蕊, 王宁致, 王骞, 余克洋, 任鑫坤. 工程化金属酶参与的卡宾、氮宾转移非天然生物催化反应[J]. 催化学报, 2025, 72(5): 4-23.
[3]	董飞祥, 金添, 余小娟, 王红月, 陈琦, 许建和, 郑高伟. 双手性邻位氨基环己醇的人工级联生物催化合成[J]. 催化学报, 2025, 68(1): 345-355.
[4]	吴振华, 石家福, 张博禹, 焦彧帅, 孟祥萱, 储子仪, 陈裕, 程怡然, 姜忠义. 基于共轭微孔聚合物的高性能多酶级联催化系统[J]. 催化学报, 2024, 63(8): 213-223.
[5]	吕宏伟, 国文馨, 陈敏, 周煌, 吴宇恩. 热稳定单原子催化剂的理性构筑: 从原子级结构到实际应用[J]. 催化学报, 2022, 43(1): 71-91.
[6]	曹宇飞, 戈钧. 酶复合催化剂原位合成新方法及生物催化应用[J]. 催化学报, 2021, 42(10): 1625-1633.
[7]	孙丽婧, 杨淼, 曹毅, 田鹏, 吴鹏飞, 曹磊, 徐舒涛, 曾姝, 刘中民. 重构法合成Cu-SAPO-34及其NH₃-SCR催化性能[J]. 催化学报, 2020, 41(9): 1410-1420.
[8]	刘晓娜, 曹毅, 闫娜娜, 马超, 曹磊, 郭鹏, 田鹏, 刘中民. Cu-SAPO-17:一种新颖的NO_x选择性催化还原催化剂[J]. 催化学报, 2020, 41(11): 1715-1722.
[9]	李健, 范江涛, Sajjad Ali, 蓝国钧, 唐浩东, 韩文锋, 刘化章, 李波, 李瑛. 超稳低汞催化剂的稳定机理:炭表面含氧基团及缺陷协同作用实验及理论研究[J]. 催化学报, 2019, 40(2): 141-146.
[10]	贺大威, 袁丹华, 宋智甲, 徐云鹏, 刘中民. 以胆碱为绿色无毒有机结构导向剂合成高硅Y型分子筛[J]. 催化学报, 2019, 40(1): 52-59.
[11]	张泽树, 李经纬, 易婷, 孙立伟, 张一波, 胡学风, 崔文浩, 杨向光. 调控尖晶石Co³⁺和Ni³⁺表面密度来提高催化甲烷氧化活性[J]. 催化学报, 2018, 39(7): 1228-1239.
[12]	赵爽, 黄黎明, 江博琼, 程敏, 张嘉威, 胡一静. 分子筛负载Cu-Mn双金属柴油机尾气脱硝催化剂的稳定性[J]. 催化学报, 2018, 39(4): 800-809.
[13]	Aqib Zafar Khan, Muhammad Bilal, Tahir Rasheed, Hafiz M. N. Iqbal. 生物催化进展:从计算到代谢工程[J]. 催化学报, 2018, 39(12): 1861-1868.
[14]	李清华, 董源, 陈飞飞, 柳磊, 李春秀, 许建和, 郑高伟. Brevibacterium epidermidis催化酮不对称还原胺化合成(S)-手性胺[J]. 催化学报, 2018, 39(10): 1625-1632.
[15]	向骁, 吴鹏飞, 曹毅, 曹磊, 王全义, 徐舒涛, 田鹏, 刘中民. Cu-SAPO-34催化剂的低温水热稳定性及其对NH₃选择催化还原NO_x反应性能的影响[J]. 催化学报, 2017, 38(5): 918-927.