PEGA supports for combinatorial peptide synthesis and solid-phase enzymatic library assays

Renil, Manat; Ferreras, Mercedes; Delaissé, Jean Marie; Foged, Niels T.; Meldal, Morten

doi:10.1002/(sici)1099-1387(199805)4:3<195::aid-psc141>3.0.co;2-r

Cited by 69 publications

(39 citation statements)

References 35 publications

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“…We found that the non-functionalized PEG microbeads were more compatible with various solvents due to the increase in amphiphilicity [22]. Compared with commercially available PEG-based microbeads, such as PEGA resin [23,24], TentaGel XV resin [25,26], and ChemMatrix resin [27,28], PEG-amine hydrogel microbeads did not swell relatively with various solvents because of the high degree of crosslink [4,5]. However, our PEG-amine microbeads did not need a high swelling ratio because most of the active functional groups were exposed at the shell region [22,29].…”

Section: Resultsmentioning

confidence: 98%

Microfluidic Generation of Amino-Functionalized Hydrogel Microbeads Capable of On-Bead Bioassay

Kim

Lee

et al. 2019

Micromachines

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Microfluidic generation of hydrogel microbeads is a highly efficient and reproducible approach to create various functional hydrogel beads. Here, we report a method to prepare crosslinked amino-functionalized polyethylene glycol (PEG) microbeads using a microfluidic channel. The microbeads generated from a microfluidic device were evaluated by scanning electron microscopy (SEM), energy dispersive X-ray spectroscopy (EDS) and confocal laser scanning microscopy, respectively. We found that the microbeads were monodisperse and the amino groups were localized on the shell region of the microbeads. A swelling test exhibited compatibility with various solvents. A cell binding assay was successfully performed with RGD peptide-coupled amino-functionalized hydrogel microbeads. This strategy will enable the large production of the various functional microbeads, which can be used for solid phase peptide synthesis and on-bead bioassays.

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Section: Resultsmentioning

confidence: 98%

Microfluidic Generation of Amino-Functionalized Hydrogel Microbeads Capable of On-Bead Bioassay

Kim

Lee

et al. 2019

Micromachines

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“…Here we demonstrated the feasibility of using glass, agarose and TentaGel® beads for Bead-GPS, although other bead types that are commonly used for libraries may also be compatible (e.g. PEGA 30 acrylamide-PEG co-polymer beads). While further study is needed comparing these different bead types, several factors appear to affect the ability to obtain strong MALDI-MSI signals, well-defined spot morphology and to measure functional interaction of prey biomolecules (e.g.…”

Section: Discussionmentioning

confidence: 99%

Correlated matrix‐assisted laser desorption/ionization mass spectrometry and fluorescent imaging of photocleavable peptide‐coded random bead‐arrays

Lim

Liu

Braunschweiger

et al. 2013

Rapid Comm Mass Spectrometry

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RATIONALERapidly performing global proteomic screens is an important goal in the post-genomic era. Correlated matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) and fluorescent imaging of photocleavable peptide-coded random bead-arrays was evaluated as a critical step in a new method for proteomic screening that combines many of the advantages of MS with fluorescence-based microarrays.METHODSSmall peptide-coded model bead libraries containing up to 20 different bead species were constructed by attaching peptides to 30–34 µm diameter glass, agarose or TentaGel® beads using photocleavable biotin or a custom-designed photocleavable linker. The peptide-coded bead libraries were randomly arrayed into custom gold-coated micro-well plates with 45 µm diameter wells and subjected to fluorescence and MALDI mass spectrometric imaging (MALDI-MSI).RESULTSPhotocleavable mass-tags from individual beads in these libraries were spatially localized as ∼65 µm spots using MALDI-MSI with high sensitivity and mass resolution. Fluorescently tagged beads were identified and correlated with their matching photocleavable mass-tags by comparing the fluorescence and MALDI-MS images of the same bead-array. Post-translational modification of the peptide Kemptide was also detected on individual beads in a photocleavable peptide-coded bead-array by MALDI-MSI alone, after exposure of the beads to protein kinase A (PKA).CONCLUSIONSCorrelated MALDI-MS and fluorescent imaging of photocleavable peptide-coded random bead-arrays can provide a basis for performing global proteomic screening. © 2013 The Authors. Rapid Communications in Mass Spectrometry published by John Wiley & Sons, Ltd.

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“…The highly permeable nature of the SPOCC resin allows enzymes to diffuse into the polymer matrix and perform chemical reactions 10. 18 It was possible to inhibit the enzymatic activity of trypsin by using EETI‐II that had been synthesized and folded on the SPOCC resin, thus demonstrating the ability of trypsin to diffuse into the resin. The enzyme and inhibitor can also be recovered from the resin after TFA cleavage.…”

Section: Methodsmentioning

confidence: 99%

Total Chemical Synthesis, Folding, and Assay of a Small Protein on a Water‐Compatible Solid Support

2006

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Chemical ligation of unprotected peptides has enabled the successful synthesis of a large number of diverse proteins. [1] The native chemical ligation (NCL) reaction, [2] which proceeds in water at neutral pH to yield a native amide bond at the ligation site, has proven to be the most effective chemistry for the ligation of unprotected peptides. A major limitation of protein synthesis by NCL, and indeed all peptide chemicalligation methods, is the steady decrease in yield because of losses from intermediate handling and purification. Although recent one-pot schemes [3] for chemical protein synthesis have helped eliminate some intermediate purification steps and, therefore, increased yields, one-pot reactions can, over time and multiple ligations, lead to a large accumulation of byproducts that are difficult to purify from the target polypeptide. For certain classes of proteins, such as integral membrane proteins, an additional major problem is the poor solubility of many intermediate polypeptide products in the solvents used for ligation. There is currently no effective and general strategy for solubilizing poorly soluble intermediate polypeptides in ligation buffers without introducing modifications to the peptide building blocks. We aimed to perform protein synthesis by NCL on a cross-linked polymer support to address these limitations.Polymer-supported synthetic chemistry, originally introduced by Merrifield for peptide synthesis, [4] is known to have a number of advantages over traditional solution-phase chemistry. These advantages include simple purification through[*] Prof.

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PEGA supports for combinatorial peptide synthesis and solid-phase enzymatic library assays

Cited by 69 publications

References 35 publications

Microfluidic Generation of Amino-Functionalized Hydrogel Microbeads Capable of On-Bead Bioassay

Microfluidic Generation of Amino-Functionalized Hydrogel Microbeads Capable of On-Bead Bioassay

Correlated matrix‐assisted laser desorption/ionization mass spectrometry and fluorescent imaging of photocleavable peptide‐coded random bead‐arrays

Total Chemical Synthesis, Folding, and Assay of a Small Protein on a Water‐Compatible Solid Support

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