Artificial metalloenzymes in complex biological environments


  • Liu, W.-l. et al. New insights into exploring new functional enzymes through the enzyme promiscuity. Int. J. Biol. Macromol. 304, 140576 (2025).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Vornholt, T. et al. Artificial metalloenzymes. Nat. Rev. Methods Primers 4, 78 (2024).

    Article 
    CAS 

    Google Scholar
     

  • Klein, A. S. et al. A de novo metalloenzyme for cerium photoredox catalysis. J. Am. Chem. Soc. 146, 25976–25985 (2024).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Chang, T.-C. & Tanaka, K. In vivo organic synthesis by metal catalysts. Biorg. Med. Chem. 46, 116353 (2021).

    Article 
    CAS 

    Google Scholar
     

  • Wilson, Y. M., Dürrenberger, M., Nogueira, E. S. & Ward, T. R. Neutralizing the detrimental effect of glutathione on precious metal catalysts. J. Am. Chem. Soc. 136, 8928–8932 (2014).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • James, C. C., de Bruin, B. & Reek, J. N. H. Transition metal catalysis in living cells: progress, challenges, and novel supramolecular solutions. Angew. Chem. Int. Ed. Engl. 62, e202306645 (2023).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Jeschek, M., Panke, S. & Ward, T. R. Artificial metalloenzymes on the verge of new-to-nature metabolism. Trends Biotechnol. 36, 60–72 (2018).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Markel, U., Sauer, D. F., Schiffels, J., Okuda, J. & Schwaneberg, U. Towards the evolution of artificial metalloenzymes—a protein engineer’s perspective. Angew. Chem. Int. Ed. Engl. 58, 4454–4464 (2019).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Wittwer, M. et al. Engineering and emerging applications of artificial metalloenzymes with whole cells. Nat. Catal. 4, 814–827 (2021).

    Article 
    CAS 

    Google Scholar
     

  • Ilie, A. & Reetz, M. T. Directed evolution of artificial metalloenzymes. Isr. J. Chem. 55, 51–60 (2015).

    Article 
    CAS 

    Google Scholar
     

  • Reetz, M. T. Directed evolution of artificial metalloenzymes: a universal means to tune the selectivity of transition metal catalysts? Acc. Chem. Res. 52, 336–344 (2019).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Ullah, M. W. et al. Cell-free systems for biosynthesis: towards a sustainable and economical approach. Green Chem. 25, 4912–4940 (2023).

    Article 
    CAS 

    Google Scholar
     

  • Christoffel, F. et al. Design and evolution of chimeric streptavidin for protein-enabled dual gold catalysis. Nat. Catal. 4, 643–653 (2021).

    Article 
    CAS 

    Google Scholar
     

  • Chen, D. et al. An evolved artificial radical cyclase enables the construction of bicyclic terpenoid scaffolds via an H-atom transfer pathway. Nat. Chem. 16, 1656–1664 (2024).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Reetz, M. T. et al. A robust protein host for anchoring chelating ligands and organocatalysts. ChemBioChem 9, 552–564 (2008).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Morita, I. et al. Directed evolution of an artificial hydroxylase based on a thermostable human carbonic anhydrase protein. ACS Catal. 14, 17171–17179 (2024).

    Article 
    CAS 

    Google Scholar
     

  • Yang, H. et al. Evolving artificial metalloenzymes via random mutagenesis. Nat. Chem. 10, 318–324 (2018).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Jiang, R., Casilli, F., Thunnissen, A.-M. W. H. & Roelfes, G. An artificial copper-Michaelase featuring a genetically encoded bipyridine ligand for asymmetric additions to nitroalkenes. Angew. Chem. Int. Ed. Engl. 64, e202423182 (2025).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Pordea, A. Metal-binding promiscuity in artificial metalloenzyme design. Curr. Opin. Chem. Biol. 25, 124–132 (2015).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Amrein, B. et al. Identification of two-histidines one-carboxylate binding motifs in proteins amenable to facial coordination to metals. Metallomics 4, 379–388 (2012).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Fujieda, N. et al. Enzyme repurposing of a hydrolase as an emergent peroxidase upon metal binding. Chem. Sci. 6, 4060–4065 (2015).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Matsumoto, R. et al. An artificial metallolyase with pliable 2-His-1-carboxylate facial triad for stereoselective Michael addition. Chem. Sci. 14, 3932–3937 (2023).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Podtetenieff, J., Taglieber, A., Bill, E., Reijerse, E. J. & Reetz, M. T. An artificial metalloenzyme: creation of a designed copper binding site in a thermostable protein. Angew. Chem. Int. Ed. Engl. 49, 5151–5155 (2010).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Shen, X. et al. Enantioconvergent benzylic C(sp3)–N coupling with a copper-substituted nonheme enzyme. Science 389, 741–746 (2025). The simplicity of screening artificial metalloenzymes in cell lysate by addition of excess transition metal salts is innovative.

  • Wang, X. et al. Engineering non-haem enzymes for nickel-catalysed C(sp2)‒S coupling via ligand-to-metal charge transfer photocatalysis. Nat. Synth. 5, 835–845 (2026).

    Article 
    CAS 

    Google Scholar
     

  • Ngamchuea, K., Batchelor-McAuley, C. & Compton, R. G. The copper(II)-catalyzed oxidation of glutathione. Chemistry 22, 15937–15944 (2016).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Heinisch, T. et al. E. coli surface display of streptavidin for directed evolution of an allylic deallylase. Chem. Sci. 9, 5383–5388 (2018).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Baiyoumy, A. et al. Directed evolution of a surface-displayed artificial allylic deallylase relying on a GFP reporter protein. ACS Catal. 11, 10705–10712 (2021).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Stein, A. et al. A dual anchoring strategy for the directed evolution of improved artificial transfer hydrogenases based on carbonic anhydrase. ACS Cent. Sci. 7, 1874–1884 (2021).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Xu, Y. et al. Directed evolution of Escherichia coli surface-displayed Vitreoscilla hemoglobin as an artificial metalloenzyme for the synthesis of 5-imino-1,2,4-thiadiazoles. Chem. Sci. 15, 7742–7748 (2024).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Zou, Z. et al. Combining an artificial metathase with a fatty acid decarboxylase in a whole cell for cycloalkene synthesis. Nat. Synth. 3, 1113–1123 (2024). This article demonstrates a path to sequential biocatalytic reactions when artificial metalloenzymes are not robust to cytosolic or cell lysate conditions.

    Article 
    CAS 

    Google Scholar
     

  • Grimm, A. R. et al. A whole cell E. coli display platform for artificial metalloenzymes: poly(phenylacetylene) production with a ahodium–nitrobindin metalloprotein. ACS Catal. 8, 2611–2614 (2018).

    Article 
    CAS 

    Google Scholar
     

  • Fukumoto, K. et al. Rhodium-complex-linked hybrid biocatalyst: stereo-controlled phenylacetylene polymerization within an engineered protein cavity. ChemCatChem 6, 1229–1235 (2014).

    Article 
    CAS 

    Google Scholar
     

  • Jeschek, M. et al. Directed evolution of artificial metalloenzymes for in vivo metathesis. Nature 537, 661–665 (2016).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Zou, Z. et al. De novo design and evolution of an artificial metathase for cytoplasmic olefin metathesis. Nat. Catal. 8, 1208–1219 (2025).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Sreenilayam, G., Moore, E. J., Steck, V. & Fasan, R. Stereoselective olefin cyclopropanation under aerobic conditions with an artificial enzyme incorporating an iron-chlorin e6 cofactor. ACS Catal. 7, 7629–7633 (2017).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Naughton, K. J. et al. In vivo assembly of a genetically encoded artificial metalloenzyme for hydrogen production. ACS Synth. Biol. 10, 2116–2120 (2021).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Robertson, D. E. et al. Design and synthesis of multi-haem proteins. Nature 368, 425–432 (1994).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Watkins, D. W., Armstrong, C. T. & Anderson, J. L. R. De novo protein components for oxidoreductase assembly and biological integration. Curr. Opin. Chem. Biol. 19, 90–98 (2014).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Mann, S. I., Nayak, A., Gassner, G. T., Therien, M. J. & DeGrado, W. F. De novo design, solution characterization, and crystallographic structure of an abiological Mn–porphyrin-binding protein capable of stabilizing a Mn(V) species. J. Am. Chem. Soc. 143, 252–259 (2021).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Polizzi, N. F. et al. De novo design of a hyperstable non-natural protein–ligand complex with sub-Å accuracy. Nat. Chem. 9, 1157–1164 (2017).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Cochran, F. V. et al. Computational de novo design and characterization of a four-helix bundle protein that selectively binds a nonbiological cofactor. J. Am. Chem. Soc. 127, 1346–1347 (2005).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Kalvet, I. et al. Design of heme enzymes with a tunable substrate binding pocket adjacent to an open metal coordination site. J. Am. Chem. Soc. 145, 14307–14315 (2023).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Anderson, J. L. R. et al. Constructing a man-made c-type cytochrome maquette in vivo: electron transfer, oxygen transport and conversion to a photoactive light harvesting maquette. Chem. Sci. 5, 507–514 (2014).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Watkins, D. W. et al. Construction and in vivo assembly of a catalytically proficient and hyperthermostable de novo enzyme. Nat. Commun. 8, 358 (2017). This article establishes that cellular machinery can be used to incorporate a cofactor into designed proteins to form catalytically active artificial metalloenzymes.

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Stenner, R., Steventon, J. W., Seddon, A. & Anderson, J. L. R. A de novo peroxidase is also a promiscuous yet stereoselective carbene transferase. Proc. Natl Acad. Sci. USA 117, 1419–1428 (2020).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Hou, K. et al. De novo design of porphyrin-containing proteins as efficient and stereoselective catalysts. Science 388, 665–670 (2025).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Nies, D. H. & Grass, G. Transition metal homeostasis. EcoSal Plus https://doi.org/10.1128/ecosalplus.5.4.4.3 (2009).

  • Rodemeier, M. E., Holsinger, O. P. & Buller, A. R. Cobalt-substituted hemoprotein expression. Methods Enzymol. 720, 55–76 (2025).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Song, W. J. & Tezcan, F. A. A designed supramolecular protein assembly with in vivo enzymatic activity. Science 346, 1525–1528 (2014).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Salgado, E. N., Faraone-Mennella, J. & Tezcan, F. A. Controlling protein−protein interactions through metal coordination: assembly of a 16-helix bundle protein. J. Am. Chem. Soc. 129, 13374–13375 (2007).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Brodin, J. D. et al. Evolution of metal selectivity in templated protein interfaces. J. Am. Chem. Soc. 132, 8610–8617 (2010).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Zhang, J. G. & Huang, X. Directed evolution of copper-substituted nonheme enzymes for enantioselective alkene oxytrifluoromethylation. J. Am. Chem. Soc. 147, 29624–29630 (2025).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Chordia, S., Narasimhan, S., Lucini Paioni, A., Baldus, M. & Roelfes, G. In vivo assembly of artificial metalloenzymes and application in whole-cell biocatalysis. Angew. Chem. Int. Ed. Engl. 60, 5913–5920 (2021). This is a successful example of an exogenously applied synthetic cofactor that can assemble with the protein scaffold in the cytoplasm to form an active enzyme.

  • Wu, T. et al. Artificial metalloenzyme assembly in cellular compartments for enhanced catalysis. Nat. Chem. Biol. 21, 779–789 (2025).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Huang, J. et al. Unnatural biosynthesis by an engineered microorganism with heterologously expressed natural enzymes and an artificial metalloenzyme. Nat. Chem. 13, 1186–1191 (2021). A milestone was reached in this article by combining an artificial metalloenzyme with a natural biosynthetic pathway inside cells to produce new molecules.

  • Gu, Y. et al. Directed evolution of artificial metalloenzymes in whole cells. Angew. Chem. Int. Ed. Engl. 61, e202110519 (2022).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Bloomer, B. J. et al. Enantio- and diastereodivergent cyclopropanation of allenes by directed evolution of an iridium-containing cytochrome. J. Am. Chem. Soc. 146, 1819–1824 (2024).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Woodward, J. J., Martin, N. I. & Marletta, M. A. An Escherichia coli expression-based method for heme substitution. Nat. Methods 4, 43–45 (2007).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Liu, Z. et al. Assembly and evolution of artificial metalloenzymes within E. coli Nissle 1917 for enantioselective and site-selective functionalization of C—H and C=C Bonds. J. Am. Chem. Soc. 144, 883–890 (2022).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Eda, S. et al. Biocompatibility and therapeutic potential of glycosylated albumin artificial metalloenzymes. Nat. Catal. 2, 780–792 (2019).

    Article 
    CAS 

    Google Scholar
     

  • Mori, M. et al. From coarse to fine: the absolute Escherichia coli proteome under diverse growth conditions. Mol. Syst. Biol. 17, 1–23 (2021).

    Article 

    Google Scholar
     

  • Han, M.-J., Kim, J. Y. & Kim, J. A. Comparison of the large-scale periplasmic proteomes of the Escherichia coli K-12 and B strains. J. Biosci. Bioeng. 117, 437–442 (2014).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Vallapurackal, J. et al. Ultrahigh-throughput screening of an artificial metalloenzyme using double emulsions. Angew. Chem. Int. Ed. Engl. 61, e202207328 (2022).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Zhao, J. et al. Genetic engineering of an artificial metalloenzyme for transfer hydrogenation of a self-immolative substrate in Escherichia coli’s periplasm. J. Am. Chem. Soc. 140, 13171–13175 (2018).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Vornholt, T. et al. Enhanced sequence-activity mapping and evolution of artificial metalloenzymes by active learning. ACS Cent. Sci. 10, 1357–1370 (2024).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Vornholt, T. et al. Systematic engineering of artificial metalloenzymes for new-to-nature reactions. Sci. Adv. 7, eabe4208 (2021).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Zhao, J., Bachmann, D. G., Lenz, M., Gillingham, D. G. & Ward, T. R. An artificial metalloenzyme for carbene transfer based on a biotinylated dirhodium anchored within streptavidin. Catal. Sci. Technol. 8, 2294–2298 (2018).

    Article 
    CAS 

    Google Scholar
     

  • Pandeya, A. et al. Biotinylation as a tool to enhance the uptake of small molecules in Gram-negative bacteria. PLoS ONE 16, e0260023 (2021).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Casas-Rodrigo, I. et al. Permeabilisation of the outer membrane of Escherichia coli for enhanced transport of complex molecules. Microb. Biotechnol. 18, e70122 (2025).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Köhler, V. et al. Synthetic cascades are enabled by combining biocatalysts with artificial metalloenzymes. Nat. Chem. 5, 93–99 (2013).

    Article 
    PubMed 

    Google Scholar
     

  • Mertens, M. A. S. et al. Chemoenzymatic cascade for stilbene production from cinnamic acid catalyzed by ferulic acid decarboxylase and an artificial metathease. Catal. Sci. Technol. 9, 5572–5576 (2019).

    Article 
    CAS 

    Google Scholar
     

  • Okamoto, Y., Köhler, V., Paul, C. E., Hollmann, F. & Ward, T. R. Efficient in situ regeneration of NADH mimics by an artificial metalloenzyme. ACS Catal. 6, 3553–3557 (2016).

    Article 
    CAS 

    Google Scholar
     

  • Morra, S. & Pordea, A. Biocatalyst–artificial metalloenzyme cascade based on alcohol dehydrogenase. Chem. Sci. 9, 7447–7454 (2018).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Upp, D. M. et al. Engineering dirhodium artificial metalloenzymes for diazo coupling cascade reactions. Angew. Chem. Int. Ed. Engl. 60, 23672–23677 (2021).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Sauer, D. F. et al. Chemogenetic engineering of nitrobindin toward an artificial epoxygenase. Catal. Sci. Technol. 11, 4491–4499 (2021).

    Article 
    CAS 

    Google Scholar
     

  • Szponarski, M., Schwizer, F., Ward, T. R. & Gademann, K. On-cell catalysis by surface engineering of live cells with an artificial metalloenzyme. Commun. Chem. 1, 84 (2018).

    Article 

    Google Scholar
     

  • Ghattas, W. et al. Receptor-based artificial metalloenzymes on living human cells. J. Am. Chem. Soc. 140, 8756–8762 (2018).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Okamoto, Y. et al. A cell-penetrating artificial metalloenzyme regulates a gene switch in a designer mammalian cell. Nat. Commun. 9, 1943 (2018).

    Article 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Ogura, A. et al. A viable strategy for screening the effects of glycan heterogeneity on target organ adhesion and biodistribution in live mice. Chem. Commun. 54, 8693–8696 (2018).

    Article 
    CAS 

    Google Scholar
     

  • Nasibullin, I. et al. Synthetic prodrug design enables biocatalytic activation in mice to elicit tumor growth suppression. Nat. Commun. 13, 39 (2022). This article explores an application of artificial metalloenzymes, for the construction of active therapeutics from drug precursors.

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Huang, J. et al. Bioorthogonal gold-catalyzed carbonyl release and its adaptation for prodrug therapy using multivalent lectin-directed artificial metalloenzymes. JACS Au 6, 389–402 (2026).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Gao, Z. et al. Chemocatalytic cell tagging platform for recording cell–cell interactions via engineered palladium-based artificial metalloenzymes. Angew. Chem. Int. Ed. Engl. 64, e202424738 (2025).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Young, S. H. et al. Chemoenzymatic cascade synthesis of metal-chelating α-amino acids. ChemCatChem 17, e202401958 (2025).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Veen, M. J. et al. Artificial gold enzymes using a genetically encoded thiophenol-based noble-metal-binding ligand. Angew. Chem. Int. Ed. Engl. 64, e202421912 (2025).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Drienovská, I., Rioz-Martínez, A., Draksharapu, A. & Roelfes, G. Novel artificial metalloenzymes by in vivo incorporation of metal-binding unnatural amino acids. Chem. Sci. 6, 770–776 (2015).

    Article 
    PubMed 

    Google Scholar
     

  • Jung, S.-M., Yang, M. & Song, W. J. Symmetry-adapted synthesis of dicopper oxidases with divergent dioxygen reactivity. Inorg. Chem. 61, 12433–12441 (2022).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Klemencic, E., Brewster, R. C., Ali, H. S., Richardson, J. M. & Jarvis, A. G. Using BpyAla to generate copper artificial metalloenzymes: a catalytic and structural study. Catal. Sci. Technol. 14, 1622–1632 (2024).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Chronowska, M., Stam, M. J., Woolfson, D. N., di Costanzo, L. F. & Wood, C. W. The Protein Design Archive (PDA): insights from 40 years of protein design. Nat. Biotechnol. 43, 669–671 (2025).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Atta, L. O., Zhou, Z. & Roelfes, G. In vivo biocatalytic cascades featuring an artificial-enzyme-catalysed new-to-nature reaction. Angew. Chem. Int. Ed. Engl. 62, e202214191 (2023).

    Article 

    Google Scholar
     

  • Huang, J. et al. Complete integration of carbene-transfer chemistry into biosynthesis. Nature 617, 403–408 (2023).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Liu, Z. et al. An antibody engineered metalloenzyme for mediating cell–cell communication and activation of immuno- and chemotherapy. Nano Lett. 23, 6424–6432 (2023).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Kurimoto, M. et al. Anticancer approach inspired by the hepatotoxic mechanism of pyrrolizidine alkaloids with glycosylated artificial metalloenzymes. Angew. Chem. Int. Ed. Engl. 61, e202205541 (2022).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Bartolami, E. et al. Diselenolane-mediated cellular uptake: efficient cytosolic delivery of probes, peptides, proteins, artificial metalloenzymes and protein-coated quantum dots. Chemistry 25, 4047–4051 (2019).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Francisco, J. A., Earhart, C. F. & Georgiou, G. Transport and anchoring of β-lactamase to the external surface of Escherichia coli. Proc. Natl Acad. Sci. USA 89, 2713–2717 (1992).

    Article 
    CAS 
    PubMed 
    PubMed Central 

    Google Scholar
     

  • Zhu, Y., Liu, Y., Ai, M. & Jia, X. Surface display of carbonic anhydrase on Escherichia coli for CO2 capture and mineralization. Synth. Syst. Biotechnol. 7, 460–473 (2022).

    Article 
    CAS 
    PubMed 

    Google Scholar
     

  • Becker, S. et al. A generic system for the Escherichia coli cell-surface display of lipolytic enzymes. FEBS Lett. 579, 1177–1182 (2005).

    Article 
    CAS 
    PubMed 

    Google Scholar
     



  • Source link

    Leave a Reply

    Your email address will not be published. Required fields are marked *