Core Concept: SELEX SELEX (Systematic Evolution of Ligands by Exponential Enrichment) is an iterative process to select high-affinity, specific nucleic acid aptamers (ssDNA or RNA) against a target molecule. The magnetic bead-based method revolutionizes this by using beads as a solid, easily separable support, drastically improving speed and efficiency. How Magnetic Bead-Based SELEX Works (The Process) A professional service provider will execute this cyclic process, usually over 8-15 rounds: Key Advantages of the Magnetic Bead Method (Why it's the service of choice) Rapid Separation: Magnetic stands enable quick washing and buffer exchange, shortening each selection round from hours to minutes. Reduced Non-Specific Binding: Efficient washing minimizes background, leading to cleaner selection. Automation-Friendly: Perfectly suited for robotic liquid handlers, enabling high-throughput, reproducible selections. Flexibility with Targets: Immobilized Targets: Proteins, small molecules, cells, or viruses can be directly conjugated to the beads. Counter-Selection: Beads coated with non-target molecules (e.g., a related protein, cell type) can be used to subtract non-specific binders, dramatically enhancing specificity. What a Full-Service Provider Typically Offers 1. Project Design & Consultation Target characterization and strategy (native vs. tagged protein, cell surface marker). Selection of library type (DNA, RNA, modified nucleotides like 2'-F for stability). Design of counter-selection steps. 2. The SELEX Selection Process Library Synthesis: Starting with…
Tissue-SELEX Aptamer Screening Service This refers to a specialized contract research service that uses Systematic Evolution of Ligands by EXponential Enrichment (SELEX) to discover aptamers that specifically bind to molecular targets within a complex tissue environment, rather than purified proteins or isolated cells. Core Concept & Key Differentiator While Cell-SELEX uses whole live cells as targets, Tissue-SELEX advances the complexity by using: Tissue sections (fresh, frozen, or FFPE - Formalin-Fixed Paraffin-Embedded) Tissue homogenates Tissue-specific extracellular matrix (ECM) components The goal is to find aptamers that recognize targets in their native, histological context, preserving post-translational modifications and local microenvironments. This is crucial for developing reagents for histopathology and tissue-specific targeting. Typical Workflow Target Preparation: Provider prepares or client supplies well-characterized tissue sections (often on glass slides). Counter-selection tissues (e.g., healthy vs. diseased, organ A vs. organ B) are critical. SELEX on Tissue: The oligonucleotide library is incubated directly on the tissue section. After washing, bound sequences are eluted, often by laser capture microdissection of bound areas or direct extraction. Amplification & Iteration: Recovered sequences are amplified (PCR) and used for subsequent selection rounds, with increasing stringency. Sequencing & Analysis: High-throughput sequencing (NGS) identifies enriched sequence families. Validation: Top candidates are synthesized and validated via: Tissue Staining: Fluorescently-labeled aptamers used like antibodies in immunohistochemistry (IHC). Specificity: Testing on…
1. Core Concept: What is Capture-SELEX? Capture-SELEX (Systematic Evolution of Ligands by EXponential Enrichment) is an advanced selection technique used to discover single-stranded DNA or RNA aptamers that bind to a specific target molecule. The key innovation is that the target molecule is immobilized (or "captured") on a solid support via a short, known oligonucleotide sequence that is part of the initial random library. This makes it exceptionally powerful for selecting aptamers against small molecules or targets without natural immobilization sites. 2. The Key Differentiator: How It Differs from Classical SELEX Classical SELEX: The target itself is immobilized directly on a surface (e.g., a bead or plate). This can sometimes lead to aptamers that bind to the surface or the immobilized region of the target, which may not function well in solution. Capture-SELEX: The library itself is immobilized via a complementary "capture sequence." Only sequences that bind to the free, unmodified target in solution undergo a conformational change that releases them from the capture strand for collection. 3. Step-by-Step Process of a Capture-SELEX Service A service provider will typically manage this entire pipeline: Step 1: Project Design & Library Synthesis You define the target (e.g., a small molecule, protein, cell). The service designs a custom single-stranded DNA (ssDNA) library: [5' Fixed Primer Sequence - RANDOM Region…
What is Whole-cell SELEX? Whole-cell SELEX (Systematic Evolution of Ligands by EXponential enrichment) is a technique used to discover aptamers (single-stranded DNA or RNA molecules) that bind specifically to a target living cell. Unlike traditional SELEX that uses a purified protein target, whole-cell SELEX presents the target in its native, complex cellular environment. This allows for the selection of aptamers against: Native cell-surface proteins in their proper folding and post-translational modifications. Complex targets like transmembrane receptors in their natural lipid environment. Unknown surface biomarkers without prior knowledge of the cell's molecular makeup. Specific cell states (e.g., activated, cancerous, infected) based on differences in surface expression. The Core Process: How Whole-cell SELEX Works A professional service will manage this complex, iterative pipeline: Library & Design: Starting with a vast, random synthetic oligonucleotide library (10^14 - 10^15 unique sequences). Positive Selection: Incubating the library with the target cells (e.g., cancer cells, stem cells, bacteria). Aptamers that bind to any surface structure are retained. Counter-Selection (Critical Step): The bound pool is then exposed to non-target or control cells (e.g., healthy cells, a different cell line). Sequences that bind to these are discarded. This step is crucial for generating specificity. Elution & Amplification: Aptamers specifically bound to the target cells are recovered, amplified by PCR…
What is Solution-Phase SELEX? SELEX (Systematic Evolution of Ligands by EXponential Enrichment) is the iterative process used to discover aptamers—single-stranded DNA or RNA molecules that bind to a specific target with high affinity and specificity. Solution-Phase SELEX refers to performing the selection process with the target molecule free in solution, rather than immobilized on a solid surface (like beads or a column). This often involves a partitioning step that separates bound from unbound sequences using a method like filtration, capillary electrophoresis, or magnetic bead capture of the target. Key Advantages of Solution-Phase SELEX Preservation of Native Target Conformation: The target is in its natural, free state in solution. This is crucial for complex targets like membrane proteins, which can denature or present epitopes unnaturally when immobilized. Access to All Binding Sites: All surfaces of the target are available for aptamer binding, increasing the diversity of potential aptamers discovered. Avoidance of Non-Specific Binding to Solid Support: Reduces background noise from library sequences sticking to the immobilization matrix (e.g., sepharose beads, plastic wells), leading to cleaner selections. Better for Small Molecules and Peptides: Ideal for targets that are difficult to immobilize without blocking their functional groups. Mimics Physiological Conditions: More closely replicates how the aptamer will interact with its target in real-world applications…
