Search results for "Systematic evolution of ligands by exponential enrichment"

showing 4 items of 4 documents

Differential binding cell-SELEX method to identify cell-specific aptamers using high-throughput sequencing

2018

AbstractAptamers have in recent years emerged as a viable alternative to antibodies. High-throughput sequencing (HTS) has revolutionized aptamer research by increasing the number of reads from a few (using Sanger sequencing) to millions (using an HTS approach). Despite the availability and advantages of HTS compared to Sanger sequencing, there are only 50 aptamer HTS sequencing samples available on public databases. HTS data in aptamer research are primarily used to compare sequence enrichment between subsequent selection cycles. This approach does not take full advantage of HTS because the enrichment of sequences during selection can be due to inefficient negative selection when using live…

0301 basic medicineComputer scienceAptamerlcsh:MedicineGenomicsComputational biologyCell selexLigandsArticleDNA sequencingCell Line03 medical and health sciencessymbols.namesakeNegative selectionDrug Delivery Systems0302 clinical medicineCell Line TumorHumansGenomic librarylcsh:ScienceCarcinoma Renal CellSelection (genetic algorithm)Gene LibrarySanger sequencingMultidisciplinaryMolecular medicinelcsh:RSELEX Aptamer TechniqueHigh-throughput screeningComputational BiologyHigh-Throughput Nucleotide SequencingNucleotide MetabolismGenomicsAptamers NucleotideFlow CytometryMolecular medicineKidney Neoplasms030104 developmental biologyDrug DesignDrug deliverysymbolsNucleic Acid Conformationlcsh:QFunctional genomics030217 neurology & neurosurgerySystematic evolution of ligands by exponential enrichment
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The selection of aptamers specific for membrane molecular targets

2010

AbstractA growing number of RNA aptamers have been selected experimentally using the SELEX combinatorial approach, and these aptamers have several advantages over monoclonal protein antibodies or peptides with respect to their applications in medicine and nanobiotechnology. Relatively few successful selections have been reported for membrane molecular targets, in contrast to the situation with non-membrane molecular targets. This review compares the procedures and techniques used in selections against membrane proteins and membrane lipids. In the case of membrane proteins, the selections were performed against soluble protein fragments, detergent-membrane protein mixed micelles, whole cells…

AptamerMembrane lipidsReviewBiologyAptamersBiochemistryCell membraneMembrane LipidsRaftsMembrane transportersmedicineMolecular BiologyMembranesSELEXVesicleCell MembraneSELEX Aptamer TechniqueMembrane ProteinsCell BiologyAptamers NucleotideLipidsmedicine.anatomical_structureMembraneMembrane proteinBiochemistryLiposomesVirusesSELEX Aptamer TechniqueRNASystematic evolution of ligands by exponential enrichmentCellular and Molecular Biology Letters
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Binding of RNA Aptamers to Membrane Lipid Rafts: Implications for Exosomal miRNAs Transfer from Cancer to Immune Cells

2020

Intraluminal vesicles (ILVs) are released into the extracellular space as exosomes after the fusion of multivesicular bodies (MVBs) with the plasma membrane. miRNAs are delivered to the raft-like region of MVB by RNA-binding proteins (RBPs). RNA loading into exosomes can be either through direct interaction between RNA and the raft-like region of the MVB membrane, or through interaction between an RBP&ndash

liposomesendocrine systemmacromolecular substancesexosomesArticleCatalysisraftslcsh:ChemistryInorganic ChemistryMembrane LipidsMembrane Microdomainsimmune cellsCell Line TumorNeoplasmsmicroRNAHumansRNA aptamersPhysical and Theoretical Chemistrylcsh:QH301-705.5Molecular BiologyLipid raftSpectroscopyChemistrySELEXMacrophagesVesicleCell MembraneOrganic ChemistryMultivesicular BodiesRNA-Binding ProteinsRNADendritic CellsGeneral MedicineRaftAptamers NucleotideMicrovesiclesComputer Science ApplicationsCell biologyKiller Cells NaturalMicroRNAslcsh:Biology (General)lcsh:QD1-999Cancer cellmiRNAslipids (amino acids peptides and proteins)Systematic evolution of ligands by exponential enrichmentInternational Journal of Molecular Sciences
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Selection of Membrane RNA Aptamers to Amyloid Beta Peptide: Implications for Exosome-Based Antioxidant Strategies

2019

The distribution of amyloid beta peptide 42 (Aβ42) between model exosomal membranes and a buffer solution was measured. The model membranes contained liquid-ordered regions or phosphatidylserine. Results demonstrated that up to ca. 20% of amyloid peptide, generated in the plasma (or intracellular) membrane as a result of proteolytic cleavage of amyloid precursor proteins by β- and γ-secretases, can stay within the membrane milieu. The selection of RNA aptamers that bind to Aβ42 incorporated into phosphatidylserine-containing liposomal membranes was performed using the selection-amplification (SELEX) method. After eight selection cycles, the pool of RNA aptamers was isol…

liposomesphosphatidylserineAmyloidAmyloid betaPeptideexosomesPhosphatidylserinesExosomeCatalysisAntioxidantsraftsInorganic Chemistrylcsh:Chemistrychemistry.chemical_compoundDown’s syndromeoxidative stressHumansRNA aptamersPhysical and Theoretical ChemistryMolecular Biologylcsh:QH301-705.5Spectroscopychemistry.chemical_classificationAmyloid beta-PeptidesbiologyChemistrySELEXCommunicationOrganic ChemistryCell MembraneSELEX Aptamer TechniqueamyloidGeneral MedicinePhosphatidylserineAptamers NucleotideMicrovesiclesPeptide FragmentsComputer Science ApplicationsMembraneBiochemistrylcsh:Biology (General)lcsh:QD1-999biology.proteinAlzheimer’s diseaseSystematic evolution of ligands by exponential enrichmentInternational Journal of Molecular Sciences
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