Biomimetic Affinity Ligands for Protein Purification

Sousa, Isabel T.; Taipa, M. A.

doi:10.1007/978-1-62703-977-2_20

Cited by 3 publications

(5 citation statements)

References 43 publications

(79 reference statements)

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“…Of late, there has been resurgence of interest in the construction of fully synthetic low-molecular weight affinity ligands from small-molecule screening methodologies instead of biological ligands that suffered from instability, high production costs and low reusability . In a very interesting work in 2009, Lowe et al profited from the outstanding features of MCRs; being “one-pot” and high-structural variations due their inherent combinatorial nature, to combining with chromatographic solid supports for rational design of spectrum of beneficial affinity ligands-modified sepharose supports via Ugi-4CR that are suitable for the purification of immunoglobulins and their fragments by affinity chromatography .…”

Section: Covalent Functionalization Through Multicomponent Reactionsmentioning

confidence: 99%

Materials Functionalization with Multicomponent Reactions: State of the Art

Afshari

Shaabani

2018

ACS Comb. Sci.

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The emergence of neoteric synthetic routes for materials functionalization is an interesting phenomenon in materials chemistry. In particular, the union of materials chemistry with multicomponent reactions (MCRs) opens a new avenue leading to the realm of highly innovative functionalized architectures with unique features. MCRs have recently been recognized as considerable part of the synthetic chemist's toolbox due to their great efficiency, inherent molecular diversity, atom and pot economy along with operational simplicity. Also, MCRs can improve E-factor and mass intensity as important green chemistry metrics. By rational tuning of the materials, as well as the MCRs, wide ranges of functionalized materials can be produced with tailorable properties that can play important roles in the plethora of applications. To date, there has not reported any exclusive review of a materials functionalization with MCRs. This critical review highlights the state-of-the-art on the one-pot functionalization of carbonaceous and siliceous materials, polysaccharides, proteins, enzymes, synthetic polymers, etc., via diverse kind of MCRs like Ugi, Passerini, Petasis, Khabachnik-Fields, Biginelli, and MALI reactions through covalent or noncovalent manners. Besides the complementary discussion of synthetic routes, superior properties and detailed applicability of each functionalized material in modern technologies are discussed. Our outlook also emphasizes future strategies for this unprecedented area and their use as materials for industrial implementation. With no doubt, MCRs-functionalization of materials bridges the gap between materials science domain and applied chemistry.

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Section: Covalent Functionalization Through Multicomponent Reactionsmentioning

confidence: 99%

Materials Functionalization with Multicomponent Reactions: State of the Art

Afshari

Shaabani

2018

ACS Comb. Sci.

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“…2.4. Solid-Phase Synthesis of Ligand 11/3 ′ Ligand 11/3 ′ was synthesized by a well-established solid-phase synthesis protocol, as described in [28]. Sepharose CL-6B (support matrix) was activated with epichlorohydrin, followed by amination and reaction with cyanuric chloride.…”

Section: Screening Of Biomimetic Affinity Ligands Via Affinity Chroma...mentioning

confidence: 99%

“…However, its use instead of classic chromatographic techniques is often limited by the availability of a cost-effective ligand recognizing the protein of interest. Affinity ligands for protein purification (as well as for other purposes that take advantage of affinity interactions) can be natural molecules, such as enzyme substrates and inhibitors, effectors, coenzymes, hormones, antigens, nucleic acids and sugars, for example, [21] or bioinspired affinity ligands [22] such as short mimetic peptides [23], aptamers [24], or rationally designed biomimetic triazine-scaffolded affinity ligands [25][26][27][28]. Triazine-based synthetic ligands are nontoxic, highly stable, cost-effective, low-molecular weight compounds that can replace advantageously natural biological ligands in the purification of proteins by affinity chromatographic methods [27,28].…”

Section: Introductionmentioning

confidence: 99%

“…Affinity ligands for protein purification (as well as for other purposes that take advantage of affinity interactions) can be natural molecules, such as enzyme substrates and inhibitors, effectors, coenzymes, hormones, antigens, nucleic acids and sugars, for example, [21] or bioinspired affinity ligands [22] such as short mimetic peptides [23], aptamers [24], or rationally designed biomimetic triazine-scaffolded affinity ligands [25][26][27][28]. Triazine-based synthetic ligands are nontoxic, highly stable, cost-effective, low-molecular weight compounds that can replace advantageously natural biological ligands in the purification of proteins by affinity chromatographic methods [27,28]. These synthetic ligands mimic the structure and binding of natural ligands and are easily synthetized by a solid-phase assembly method on agarose matrix with a triazine scaffold.…”

Section: Introductionmentioning

confidence: 99%

“…These synthetic ligands mimic the structure and binding of natural ligands and are easily synthetized by a solid-phase assembly method on agarose matrix with a triazine scaffold. The triazine scaffold allows for the display of attached functional groups and the possibility of attaining molecular diversity by serial substitution of the chlorines in the triazine ring by commercially available aliphatic and aromatic amines [28].…”

Section: Introductionmentioning

confidence: 99%

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One-Step Purification of Recombinant Cutinase from an E. coli Extract Using a Stabilizing Triazine-Scaffolded Synthetic Affinity Ligand

Fonseca,

Taipa

2024

Biomimetics

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Cutinase from Fusarium solani pisi is an enzyme that bridges functional properties between lipases and esterases, with applications in detergents, food processing, and the synthesis of fine chemicals. The purification procedure of recombinant cutinase from E. coil extracts is a well-established but time-consuming process, which involves a sequence of two anionic exchange chromatography steps followed by dialysis. Affinity chromatography is the most efficient method for protein purification, the major limitation of its use being often the availability of a ligand selective for a given target protein. Synthetic affinity ligands that specifically recognize certain sites on the surface of proteins are highly desirable for affinity processes due to their cost-effectiveness, durability, and reusability across multiple cycles. Additionally, these ligands establish moderate affinity interactions with the target protein, making it possible to purify proteins under gentle conditions while maintaining high levels of activity recovery. This study aimed to develop a new method for purifying cutinase, utilizing triazine-scaffolded biomimetic affinity ligands. These ligands were previously screened from a biased-combinatorial library to ensure their binding ability to cutinase without compromising its biological function. A lead ligand, designated as 11/3′, [4-({4-chloro-6-[(2-methylbutyl)amino]-1,3,5-triazin-2-yl}amino)benzoic acid], was chosen and directly synthesized onto agarose. Experiments conducted at different scales demonstrated that this ligand (with an affinity constant Ka ≈ 104 M−1) exhibited selectivity towards cutinase, enabling the purification of the enzyme from an E. coli crude production medium in a single step. Under optimized conditions, the protein and activity yields reached 25% and 90%, respectively, with a resulting cutinase purity of 85%.

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