Synthesis of Multi-Protein Complexes through Charge-Directed Sequential Activation of Tyrosine Residues

Mogilevsky, Casey S.; Lobba, Marco; Brauer, Daniel; Marmelstein, Alan M.; Maza, Johnathan C.; Gleason, Jamie M.; Doudna, Jennifer A.; Francis, Matthew B.

doi:10.26434/chemrxiv.14251649.v1

Cited by 3 publications

(5 citation statements)

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“…Previous work from our lab has shown that tyrosinase from Bacillus megatarium (megaTYR) is capable of oxidizing phenols to o-quinones that show excellent selectivity for free thiol additions. 26 We have demonstrated that megaTYR can be easily obtained through recombinant protein expression in Escherichia coli and maintains high levels of activity under proper storage conditions at −80 °C. 27 Furthermore, due to the size difference between the enzyme (∼35 kDa) and the antibody, purification with high-molecular weight cut off filters or size exclusion chromatography can be used for sample preparation.…”

Section: ■ Results and Discussionmentioning

confidence: 96%

“…11 With the generation of several megaTYR variants, our lab has been able to install negatively charged oligonucleotide cargo onto proteins site-specifically. 26 The D55R megaTYR variant has the strongest preference for negatively charge substrates and has been used to attach DNA to proteins. We explored the conjugation of murine and human TLR9 agonists�ODN1826 and ODN2006, respectively� using D55R megaTYR (Supplementary Figure S6).…”

Section: Bioconjugatementioning

confidence: 99%

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Modification of Cysteine-Substituted Antibodies Using Enzymatic Oxidative Coupling Reactions

et al. 2023

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Cysteines are routinely used as site-specific handles to synthesize antibody–drug conjugates for targeted immunotherapy applications. Michael additions between thiols and maleimides are some of the most common methods for modifying cysteines, but these functional groups can be difficult to prepare on scale, and the resulting linkages have been shown to be reversible under some physiological conditions. Here, we show that the enzyme tyrosinase, which oxidizes conveniently accessed phenols to afford reactive ortho-quinone intermediates, can be used to attach phenolic cargo to cysteines engineered on antibody surfaces. The resulting linkages between the thiols and ortho-quinones are shown to be more resistant than maleimides to reversion under physiological conditions. Using this approach, we construct antibody conjugates bearing cytotoxic payloads, which exhibit targeted cell killing, and further demonstrate this method for the attachment of a variety of cargo to antibodies, including fluorophores and oligonucleotides.

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Section: ■ Results and Discussionmentioning

confidence: 96%

Section: Bioconjugatementioning

confidence: 99%

Modification of Cysteine-Substituted Antibodies Using Enzymatic Oxidative Coupling Reactions

et al. 2023

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“…This is necessary because proteins are generally present in low concentrations (1−100 μM) and are also large in size, rendering them sterically encumbered coupling partners. 18,19 However, in the case of protein−protein coupling reactions, it is generally not practical to use a larger stoichiometric excess of one partner. The protein−protein coupling problem arises because two of these sterically encumbered coupling partners, both present at low concentrations, must come together to form the desired protein−protein conjugate.…”

Section: The Protein−protein Coupling Problemmentioning

confidence: 99%

“…122 Further work explored the use of different tyrosinases to expand the scope of tyrosine residues that could be targeted in this manner. 19 A tyrosinase from Bacillus megaterium (megaTYR) was found to be more promiscuous and enabled the oxidation of tyrosine residues in a high number of sequence motifs, as assayed by peptide experiments. Further engineering of megaTYR led to a variant that displayed high activity toward tyrosine residues in the E 4 Y motif, ultimately enabling the construction of a linear triple-protein conjugate comprising nanoluciferase, GFP, and mCherry.…”

Section: Approaches Mediated By Tyrosine Oxidationmentioning

confidence: 99%

Chemical and Enzymatic Methods for Post-Translational Protein–Protein Conjugation

et al. 2022

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Fusion proteins play an essential role in the biosciences but suffer from several key limitations, including the requirement for N-to-C terminal ligation, incompatibility of constituent domains, incorrect folding, and loss of biological activity. This perspective focuses on chemical and enzymatic approaches for the post-translational generation of well-defined protein−protein conjugates, which overcome some of the limitations faced by traditional fusion techniques. Methods discussed range from chemical modification of nucleophilic canonical amino acid residues to incorporation of unnatural amino acid residues and a range of enzymatic methods, including sortase-mediated ligation. Through summarizing the progress in this rapidly growing field, the key successes and challenges associated with using chemical and enzymatic approaches are highlighted and areas requiring further development are discussed.

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“…To modify the existing dTMV constructs at the S123(′)C position with a His-tag, we employed an oxidative coupling reaction using the enzyme tyrosinase for the conjugation of phenol-containing peptides, small molecules, or proteins to cysteine residues on protein surfaces (36)(37)(38). Short peptide sequences with a C-terminal tyrosine and an N-terminal His-tag were designed to conjugate to the dTMV double disks at S123(′)C and subsequently coordinate with nickelnitrilotriacetic acid (Ni 2+ -NTA) lipids in SLBs.…”

Section: Asymmetric Dual-functionalization Of Dtmv Allows Dye-labeled...mentioning

confidence: 99%

A membrane-associated light harvesting model is enabled by functionalized assemblies of gene-doubled TMV proteins

Dai¹,

Wilhelm²,

Bischoff³

et al. 2022

Preprint

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Photosynthetic light harvesting requires efficient energy transfer within dynamic networks of light harvesting complexes embedded within phospholipid membranes. Artificial light harvesting models are valuable tools for understanding the structural features underpinning energy absorption and transfer within chromophore arrays. Most artificial light harvesting complexes are static or in the solution phase, rather than in a two-dimensional fluid environment as in natural photosynthesis. We have developed a method for attaching a protein-based light harvesting model to a supported lipid bilayer (SLB), which provides an extended fluid membrane surface stably associated with a solid substrate. The protein model consisted of the tobacco mosaic viral capsid proteins (TMV) that were gene-doubled to create a tandem dimer (dTMV). Assemblies of dTMV were shown to break the facial symmetry of the double disk to allow for differentiation between the disk faces. Single reactive lysine and cysteine residues were incorporated into opposing surfaces of each monomer of the dTMV assemblies. This allowed for the site-selective attachment of both chromophores for light absorption and a peptide for attachment to the SLB. A cysteine modification strategy using the enzyme tyrosinase was employed for the bioconjugation of a peptide containing a polyhistidine tag for association with SLBs. The dual-modified dTMV complexes showed significant association with SLBs and exhibited mobility on the bilayer. The techniques used herein offer a new method for protein-surface attachment and provide a platform for evaluating excited state energy transfer events in a dynamic, fully synthetic artificial light harvesting system.

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Synthesis of Multi-Protein Complexes through Charge-Directed Sequential Activation of Tyrosine Residues

Cited by 3 publications

References 1 publication

Modification of Cysteine-Substituted Antibodies Using Enzymatic Oxidative Coupling Reactions

Modification of Cysteine-Substituted Antibodies Using Enzymatic Oxidative Coupling Reactions

Chemical and Enzymatic Methods for Post-Translational Protein–Protein Conjugation

A membrane-associated light harvesting model is enabled by functionalized assemblies of gene-doubled TMV proteins

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