Engineered Bifunctional Proteins for Targeted Cancer Therapy: Prospects and Challenges

Du, Yue; Xu, Jian

doi:10.1002/adma.202103114

Cited by 8 publications

(6 citation statements)

References 334 publications

(338 reference statements)

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“…However, due to the lack of an Fc region, the flexible linker makes non‐IgG‐like bispecific antibodies have a shorter serum half‐life, weaker stability, and less biological activity compared to the IgG‐like bispecific antibodies (contains Fab, Fab’, and Fc region). [ 30 ] Similarly, a flexible linker applied for the assembly of a bivalent aptamer allows two aptamers to move randomly, resulting in a large entropy barrier (loss in rotational and translational entropy) when the bivalent aptamer binds to target molecules. So, the benefit of multivalent interactions is not maximized due to the flexibility of scaffold linkers.…”

Section: Resultsmentioning

confidence: 99%

“…As shown in Scheme 1, a Y-shaped bispecific antibody contains a constant region (Fc) and two variable antigen-binding fragment arms (Fab and Fab'), which can recognize and bind to two different antigens or two different epitopes of one antigen. [30,31] Like Fab and Fab' arms, two different nonoverlapping DNA monovalent aptamers can bind to two distinct epitopes on one target. More design details are presented in Figure S4, Supporting Information.…”

Section: Design Of Preorganized Dna Framework Librarymentioning

confidence: 99%

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De Novo Evolution of an Antibody‐Mimicking Multivalent Aptamer via a DNA Framework

et al. 2023

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Multivalent interactions can often endow ligands with more efficient binding performance toward target molecules. Generally speaking, a multivalent aptamer can be constructed via post-assembly based on chemical structural information of target molecules and pre-identified monovalent aptamers derived from traditional systematic evolution of ligands by exponential enrichment (SELEX) technology. However, many target molecules may not have known matched aptamer partners, thus a de novo evolution will be highly desired as an alternative strategy for directed selection of a high-avidity, multivalent aptamer. Here, inspired by the superiority of multivalent interactions between antibodies and antigens, a direct SELEX strategy with a preorganized DNA framework library for an "Antibody-mimicking multivalent aptamer" (Amap) selection to epithelial cell adhesion molecule (EpCAM), a model target protein is reported. The Amap presents a relatively good binding affinity through both aptamer moieties concurrently binding to EpCAM, which has been confirmed by affinity analysis and molecular modeling. Furthermore, dynamic interactions between Amap and EpCAM are directly visualized by magnetic tweezers at the single-molecule level. A nice binding affinity of Amap to EpCAM-positive cancer cells has also been verified, which hints that their Amap-SELEX strategy has the potential to be a new route for de novo evolution of multivalent aptamers.

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Section: Resultsmentioning

confidence: 99%

Section: Design Of Preorganized Dna Framework Librarymentioning

confidence: 99%

De Novo Evolution of an Antibody‐Mimicking Multivalent Aptamer via a DNA Framework

et al. 2023

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“…The success of the E 246 mutation in increasing the rate of Pa DADH turnover with d -arginine is a prime example of how deconstructing catalytic processes and targeting specific steps in the catalytic cycle of an enzyme can be explored for the bioengineering of biocatalysts. An important implication of this study is that we have engineered a d -amino acid oxidizing enzyme that can detect and consume its substrate faster at 500 s –1 , providing a highly efficient system for applications in the food and l -amino acid industries. − With the surging interest in gating residues as targets for protein engineering toward therapeutic development, it is vital to identify the properties of gating residues that alter enzyme activity and specificity. ,− ,,− Given that gates control the flux of substances in and out of the active site, ,,− and because most gating residues are distal from the active site, their mutations tend to alter substrate selectivity and not enzyme catalysis. ,,,, This study demonstrates that the proximity of a gating residue to the active site and interactions with ligands are two important factors to consider during protein engineering. Residues like E 246 of Pa DADH, which is close to the active site and interacts with a substrate or product, could be prime targets for engineering faster biological catalysts.…”

Section: Discussionmentioning

confidence: 99%

“…Scientists do not fully understand the effects of enzyme motions on enzyme catalysis, such as loop dynamics. Hence, engineered proteins often exhibit poor catalytic abilities compared to their native proteins. − Most enzymes undergo natural evolutionary processes that fashion them for better functionality in an organism, including mutations into more active forms that result in improved enzyme flexibility for catalysis. − , For protein engineering for therapeutics, such as in treating cardiovascular diseases and cancer therapy, − and for applications in the food industry, studies on flexible enzyme dynamics are also necessary to generate better biocatalysts.…”

Section: Introductionmentioning

confidence: 99%

Targeted Mutation of a Non-catalytic Gating Residue Increases the Rate of Pseudomonas aeruginosa d-Arginine Dehydrogenase Catalytic Turnover

Quaye,

Ouedraogo,

Gadda

2023

J. Agric. Food Chem.

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Commercial food and l-amino acid industries rely on bioengineered d-amino acid oxidizing enzymes to detect and remove d-amino acid contaminants. However, the bioengineering of enzymes to generate faster biological catalysts has proven difficult as a result of the failure to target specific kinetic steps that limit enzyme turnover, k cat, and the poor understanding of loop dynamics critical for catalysis. Pseudomonas aeruginosa d-arginine dehydrogenase (PaDADH) oxidizes most d-amino acids and is a good candidate for application in the l-amino acid and food industries. The side chain of the loop L2 E246 residue located at the entrance of the PaDADH active site pocket potentially favors the closed active site conformation and secures the substrate upon binding. This study used site-directed mutagenesis, steady-state, and rapid reaction kinetics to generate the glutamine, glycine, and leucine variants and investigate whether increasing the rate of product release could translate to an increased enzyme turnover rate. Upon E246 mutation to glycine, there was an increased rate of d-arginine turnover k cat from 122 to 500 s–1. Likewise, the k cat values increased 2-fold for the glutamine or leucine variants. Thus, we have engineered a faster biocatalyst for industrial applications by selectively increasing the rate of the PaDADH product release.

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“…Modern bioengineering approaches make it possible to create bifunctional proteins (BFPs) of various types for targeted cancer therapy, which simultaneously activate or block two signaling pathways [ 39 ]. TRAIL represents one of the most promising cancer treatments due to its specificity, safety and encouraging results in vitro and in vivo.…”

Section: Discussionmentioning

confidence: 99%

Optimized Heterologous Expression and Efficient Purification of a New TRAIL-Based Antitumor Fusion Protein SRH–DR5-B with Dual VEGFR2 and DR5 Receptor Specificity

Yagolovich

Artykov

Isakova

et al. 2022

IJMS

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In the last two decades, bifunctional proteins have been created by genetic and protein engineering methods to increase therapeutic effects in various diseases, including cancer. Unlike conventional small molecule or monotargeted drugs, bifunctional proteins have increased biological activity while maintaining low systemic toxicity. The recombinant anti-cancer cytokine TRAIL has shown a limited therapeutic effect in clinical trials. To enhance the efficacy of TRAIL, we designed the HRH–DR5-B fusion protein based on the DR5-selective mutant variant of TRAIL fused to the anti-angiogenic synthetic peptide HRHTKQRHTALH. Initially low expression of HRH–DR5-B was enhanced by the substitution of E. coli-optimized codons with AT-rich codons in the DNA sequence encoding the first 7 amino acid residues of the HRH peptide. However, the HRH–DR5-B degraded during purification to form two adjacent protein bands on the SDS-PAGE gel. The replacement of His by Ser at position P2 immediately after the initiator Met dramatically minimized degradation, allowing more than 20 mg of protein to be obtained from 200 mL of cell culture. The resulting SRH–DR5-B fusion bound the VEGFR2 and DR5 receptors with high affinity and showed increased cytotoxic activity in 3D multicellular tumor spheroids. SRH–DR5-B can be considered as a promising candidate for therapeutic applications.

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Engineered Bifunctional Proteins for Targeted Cancer Therapy: Prospects and Challenges

Cited by 8 publications

References 334 publications

De Novo Evolution of an Antibody‐Mimicking Multivalent Aptamer via a DNA Framework

De Novo Evolution of an Antibody‐Mimicking Multivalent Aptamer via a DNA Framework

Targeted Mutation of a Non-catalytic Gating Residue Increases the Rate of Pseudomonas aeruginosa d-Arginine Dehydrogenase Catalytic Turnover

Optimized Heterologous Expression and Efficient Purification of a New TRAIL-Based Antitumor Fusion Protein SRH–DR5-B with Dual VEGFR2 and DR5 Receptor Specificity

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