Characterization of the structure and interactions of P450 BM3 using hybrid mass spectrometry approaches

Jeffreys, Laura N.; Pacholarz, Kamila J.; Johannissen, Linus O.; Girvan, Hazel M.; Barran, Perdita E.; Voice, Michael W.; Munro, Andrew W.

doi:10.1074/jbc.ra119.011630

Cited by 11 publications

(8 citation statements)

References 47 publications

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“…By using SaSrtA, the heme and reductase domain are reconstituted into the active and full-length P450 BM3 monooxygenase, which forms ad imer preventing ab ack reaction( Figure 1a). [34,35] The amount of reconstituted P450 BM3 was detectedb yareported fluorogenica ssay using 7benzoxy-3-carboxycoumarin ethyl ester (BCCE) as the substrate (Figure 1a). [36] Reconstitution of heme and reductase domain to full-length P450 BM3 using SaSrtA WT was previously reported.…”

mentioning

confidence: 99%

Enhancing Robustness of Sortase A by Loop Engineering and Backbone Cyclization

Zhi

Maté

Nöth

et al. 2020

Chemistry A European J

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mentioning

confidence: 99%

Enhancing Robustness of Sortase A by Loop Engineering and Backbone Cyclization

Zhi

Maté

Nöth

et al. 2020

Chemistry A European J

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“…A dimerization was observed on the whole P450 BM3 of which BMR is a domain [ 70–73 ] but a direct BMR to BMR interaction was also observed under several conditions. [ 74,75 ] Here, a dimerization could compete with or hinder the productive interaction with CbA5H, leading to the strong decrease observed (Figure 3B).…”

Section: Discussionmentioning

confidence: 99%

Cascade reactions with two non‐physiological partners for NAD(P)H regeneration via renewable hydrogen

Gasteazoro,

Catucci,

Barbieri

et al. 2024

Biotechnology Journal

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An attractive application of hydrogenases, combined with the availability of cheap and renewable hydrogen (i.e., from solar and wind powered electrolysis or from recycled wastes), is the production of high‐value electron‐rich intermediates such as reduced nicotinamide adenine dinucleotides.Here, the capability of a very robust and oxygen‐resilient [FeFe]‐hydrogenase (CbA5H) from Clostridium beijerinckii SM10, previously identified in our group, combined with a reductase (BMR) from Bacillus megaterium (now reclassified as Priestia megaterium) was tested. The system shows a good stability and it was demonstrated to reach up to 28 ± 2 nmol NADPH regenerated s−1 mg of hydrogenase−1 (i.e., 1.68 ± 0.12 U mg−1, TOF: 126 ± 9 min−1) and 0.46 ± 0.04 nmol NADH regenerated s−1 mg of hydrogenase−1 (i.e., 0.028 ± 0.002 U mg−1, TOF: 2.1 ± 0.2 min−1), meaning up to 74 mg of NADPH and 1.23 mg of NADH produced per hour by a system involving 1 mg of CbA5H. The TOF is comparable with similar systems based on hydrogen as regenerating molecule for NADPH, but the system is first of its kind as for the [FeFe]‐hydrogenase and the non‐physiological partners used. As a proof of concept a cascade reaction involving CbA5H, BMR and a mutant BVMO from Acinetobacter radioresistens able to oxidize indole is presented. The data show how the cascade can be exploited for indigo production and multiple reaction cycles can be sustained using the regenerated NADPH.

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“…The evidence suggests that in CYP116B5 the electron transfer chain may be less efficient than the one of other CYP116B subfamily members but it cannot be excluded that a different molecular mechanism takes place and that for this cytochrome the electron transfer relies more on the structural arrangement of the domains, which is supposed to be more dynamic and may involve less or no amino acid residues. [ 8,48 ] The fact that the reductase domain of CYP116B5 has the lowest cofactor conversion rate among the CYP116B isoenzymes, added to the evidence that the electron transfer chain may be less efficient than the one of other CYP116B isoenzymes. This is also in support of the assumption that CYP116B5 may have a different evolutionary path and that it is more related to peroxygenases rather than monooxygenases.…”

Section: Discussionmentioning

confidence: 99%

Catalytically self‐sufficient CYP116B5: Domain switch for improved peroxygenase activity

Correddu

Catucci

Giuriato

et al. 2023

Biotechnology Journal

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Self‐sufficient cytochromes P450 of the sub‐family CYP116B have gained great attention in biotechnology due to their ability to catalyze challenging reactions toward a wide range of organic compounds. However, these P450s are often unstable in solution and their activity is limited to a short reaction time. Previously it has been shown that the isolated heme domain of CYP116B5 can work as a peroxygenase with H2O2 without the addition of NAD(P)H. In this work, protein engineering was used to generate a chimeric enzyme (CYP116B5‐SOX), in which the native reductase domain is replaced by a monomeric sarcosine oxidase (MSOX) capable of producing H2O2. The full‐length enzyme (CYP116B5‐fl) is characterized for the first time, allowing a detailed comparison to the heme domain (CYP116B5‐hd) and CYP116B5‐SOX. The catalytic activity of the three forms of the enzyme was studied using p‐nitrophenol as substrate, and adding NADPH (CYP116B5‐fl), H2O2 (CYP116B5‐hd), and sarcosine (CYP116B5‐SOX) as source of electrons. CYP116B5‐SOX performs better than CYP116B5‐fl and CYP116B5‐hd showing 10‐ and 3‐folds higher activity, in terms of p‐nitrocatechol produced per mg of enzyme per minute. CYP116B5‐SOX represents an optimal model to exploit CYP116B5 and the same protein engineering approach could be used for P450s of the same class.

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Characterization of the structure and interactions of P450 BM3 using hybrid mass spectrometry approaches

Cited by 11 publications

References 47 publications

Enhancing Robustness of Sortase A by Loop Engineering and Backbone Cyclization

Enhancing Robustness of Sortase A by Loop Engineering and Backbone Cyclization

Cascade reactions with two non‐physiological partners for NAD(P)H regeneration via renewable hydrogen

Catalytically self‐sufficient CYP116B5: Domain switch for improved peroxygenase activity

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