A Concise Approach to Site-Specific Topological Protein–Poly(amino acid) Conjugates Enabled by <i>in Situ</i>-Generated Functionalities

Hou, Yingqin; Yuan, Jingsong; Zhou, Yu; Yu, Jiangyong; Lu, Hua

doi:10.1021/jacs.6b05413

Cited by 86 publications

(72 citation statements)

References 74 publications

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“…In light of the advances made by the latest ring opening polymerization ([C]ROP, ROMP) and RDRP (ATRP, SET‐LRP, RAFT, NMP) protocols, such polymers are ideal candidates for post‐polymerization modification and protein/peptide modification via ‘grafting‐to,’ ‘grafting‐from,’ and ‘grafting‐through’ techniques which can be acheieved via covalent or non‐covalent intereactions. ROP of N ‐carboxyanhydrides has been developed whereby functionality for site‐specific protein ligation can be topologically installed in situ . Cationic ROP of oxazolines can be terminated using functional nucleophilies, and the resulting polymers have been ‘grafted‐to’ proteins .…”

Section: Synthetic Approaches To Covalently‐linked Protein/peptide‐pomentioning

confidence: 99%

“…ROP of N-carboxyanhydrides has been developed whereby functionality for site-specific protein ligation can be topologically installed in situ. [43] Cationic ROP of oxazolines can be terminated using functional nucleophilies, and the resulting polymers have been 'grafted-to' proteins. [44] Furthermore, side chain functionality, incorporated either in the oxazoline monomer or through post-polymerization modification has been exploited for the 'grafting-through' modification of polymer chains [45] and particles.…”

Section: Synthetic Approaches To Covalently-linked Protein/ Peptide-pmentioning

confidence: 99%

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Synthesis and Applications of Protein/Peptide-Polymer Conjugates

Wilson

2017

Macromol. Chem. Phys.

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Recent advances in synthetic methodologies have brought us closer than ever to the precision conferred by nature. For example, the control possible in reversible deactivation radical polymerization enables us to design and synthesize macromolecules with unprecedented control over not only the polymer chain ends, but also the side chain functionality. Furthermore, this functionality can be exploited to afford chemical modification of peptides and proteins, with ever‐improving site‐specificity, yielding a range of well‐defined protein/peptide‐hybrid materials. Such materials benefit from the amalgamation of the properties of proteins/peptides with those of the synthetic (macro)molecules in question. Here, the latest developments in the synthesis of functional polymers and their use for preparation of well‐defined protein/peptide‐polymer conjugates will be discussed, with particular attention focused on modulating the stability, efficacy and/or administration of therapeutic peptides.

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Section: Synthetic Approaches To Covalently‐linked Protein/peptide‐pomentioning

confidence: 99%

Section: Synthetic Approaches To Covalently-linked Protein/ Peptide-pmentioning

confidence: 99%

Synthesis and Applications of Protein/Peptide-Polymer Conjugates

Wilson

2017

Macromol. Chem. Phys.

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“…Polypeptides are attractive materials with protein‐like structures for numerous applications in biochemical and biomedicine due to their excellent biocompatibility with blood and tissue, biodegradability, and biorecognition properties . Amino acids (AAs) with various side groups qualify polypeptides with various properties, fascinating researchers with great interests . For example, polylysine and poly(glutamic acid), bearing amino groups and carboxyl groups, respectively, are widely used in stimuli‐responsive biomaterials .…”

Section: Introductionmentioning

confidence: 99%

Hydroxyl‐tolerated polymerization of N‐phenoxycarbonyl α‐amino acids: A simple way to polypeptides bearing hydroxyl groups

Yang

Bai

Ling

et al. 2019

J. Polym. Sci. Part A: Polym. Chem.

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Differing from the moisture‐sensitive α‐amino acid N‐carboxyanhydrides (AA‐NCAs) monomers, N‐phenoxycarbonyl α‐amino acids (AA‐NPCs) can be prepared and stored in open air. In this contribution, we report that the controlled polymerizations of AA‐NPC monomers of O‐tert‐butyl‐dl‐serine (BRS‐NPC), Nε‐benzyloxycarbonyl‐l‐lysine (ZLL‐NPC) and Nε‐trifluoroacetyl‐l‐lysine (FLL‐NPC) initiated by amines are surprisingly able to tolerate common nucleophilic impurities such as water and alcohols at a level of monomer concentration. The structures of polypeptides synthesized in the presence of water or alcohols agree well with the designed ones in the case of repeated chain extensions. Detailed mechanism study and density functional theory calculation reveal that the low concentration of AA‐NCA and the high activity of amines are the key factors to the controllability of AA‐NPC polymerizations. The water‐ and alcohol‐tolerant property in polymerizations of AA‐NPCs encourages the following studies on unprotected (phenolic) hydroxyl groups containing AA‐NPCs. The controllable polymerizations of N‐phenoxycarbonyl l‐tyrosine (LT‐NPC) and N‐phenoxycarbonyl S‐(3‐hydroxypropyl)‐l‐cysteine (HLC‐NPC) initiated by amines are confirmed and reported for the first time, which extends the library of AA‐NPCs and polypeptides as well. All the universality of library, the convenience of monomer preparation, and the controllability and water‐ and alcohol‐tolerant property of polymerization of AA‐NPCs significantly enhance the feasibility of polypeptide synthesis, making AA‐NPC approach a promising synthetic method of polypeptides. © 2019 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2019, 57, 907–916

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“…12 Among them, cyclic topology is the most commonly encountered nonlinear protein topology in nature and has also been extensively studied to date. 18−20 Various technologies have been developed to prepare cyclic proteins, both in vivo (21) and in vitro , 22 including intein technology, 23 SpyTag-SpyCatcher chemistry, 24,25 sortase/butlase-mediated ligation, 26−30 etc. Typical benefits from backbone cyclization include the dramatically improved stability against both thermal denaturation and proteolytic digestion.…”

Section: Introductionmentioning

confidence: 99%

Topology Engineering of Proteins in Vivo Using Genetically Encoded, Mechanically Interlocking SpyX Modules for Enhanced Stability

Liu

et al. 2017

ACS Cent. Sci.

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Recombinant proteins are traditionally limited to linear configuration. Herein, we report in vivo protein topology engineering using highly efficient, mechanically interlocking SpyX modules named AXB and BXA. SpyX modules are protein domains composed of p53dim (X), SpyTag (A), and SpyCatcher (B). The p53dim guides the intertwining of the two nascent protein chains followed by autocatalytic isopeptide bond formation between SpyTag and SpyCatcher to fulfill the interlocking, leading to a variety of backbone topologies. Direct expression of AXB or BXA produces protein catenanes with distinct ring sizes. Recombinant proteins containing SpyX modules are obtained either as mechanically interlocked obligate dimers if the protein of interest is fused to the N- or C-terminus of SpyX modules, or as star proteins if the protein is fused to both N- and C-termini. As examples, cellular syntheses of dimers of (GB1)2 (where GB1 stands for immunoglobulin-binding domain B1 of streptococcal protein G) and of four-arm elastin-like star proteins were demonstrated. Comparison of the catenation efficiencies in different constructs reveals that BXA is generally much more effective than AXB, which is rationalized by the arrangement of three domains in space. Mechanical interlocking induces considerable stability enhancement. Both AXB and BXA have a melting point ∼20 °C higher than the linear controls and the BXA catenane has a melting point ~2 °C higher than the cyclic control BX’A. Notably, four-arm elastin-like star proteins demonstrate remarkable tolerance against trypsin digestion. The SpyX modules provide a convenient and versatile approach to construct unconventional protein topologies via the “assembly-reaction” synergy, which opens a new horizon in protein science for stability enhancement and function reinforcement via topology engineering.

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A Concise Approach to Site-Specific Topological Protein–Poly(amino acid) Conjugates Enabled by in Situ-Generated Functionalities

Cited by 86 publications

References 74 publications

Synthesis and Applications of Protein/Peptide-Polymer Conjugates

Synthesis and Applications of Protein/Peptide-Polymer Conjugates

Hydroxyl‐tolerated polymerization of N‐phenoxycarbonyl α‐amino acids: A simple way to polypeptides bearing hydroxyl groups

Topology Engineering of Proteins in Vivo Using Genetically Encoded, Mechanically Interlocking SpyX Modules for Enhanced Stability

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