“High-throughput aptamer screening” is a method used to rapidly identify aptamers—short single-stranded DNA or RNA molecules—that can bind specifically to a target molecule, such as a protein, small molecule, or even whole cells. Let’s break this down in detail: 1. What Are Aptamers? Aptamers are oligonucleotides (DNA or RNA) that fold into specific three-dimensional shapes allowing them to bind with high affinity and specificity to their targets. They function similarly to antibodies but are synthetic, smaller, more stable, and can be chemically modified. 2. High-Throughput Screening (HTS) in Aptamer Discovery Traditional aptamer discovery uses SELEX (Systematic Evolution of Ligands by Exponential Enrichment), which involves multiple iterative rounds of binding, separation, and amplification. High-throughput aptamer screening accelerates this process by using automation and large-scale technologies to simultaneously test thousands to millions of sequences against the target. 3. Key Techniques in High-Throughput Aptamer Screening Microarray-Based Screening Thousands of aptamer candidates are immobilized on a chip. The target (protein, small molecule, or cell) is fluorescently labeled and applied. Aptamers that bind the target emit signals detected by imaging. Next-Generation Sequencing (NGS)-Coupled SELEX After each SELEX round, sequences are analyzed via NGS. Sequence enrichment patterns reveal high-affinity aptamer candidates without the need for extensive…
What is SELEX? First, a quick recap: SELEX (Systematic Evolution of Ligands by EXponential enrichment) is the gold-standard process for discovering aptamers (single-stranded DNA or RNA molecules that bind to a specific target with high affinity and specificity). It involves iterative cycles of binding, partitioning, and amplification. "Free Solution SELEX" Explained Free Solution SELEX (also known as non-immobilized SELEX) is a specific technical approach. Its key characteristic is that neither the target molecule nor the library is fixed to a solid support (like beads, a column, or a chip) during the binding step. How it works: Binding: The random oligonucleotide library is mixed with the free, soluble target in solution. Partitioning: The key challenge is separating the bound sequences from the unbound ones without using immobilization. Common methods include: Nitrocellulose Filter Binding: Aptamer-target complexes are trapped on a filter, while free sequences pass through. Gel Filtration/Size Exclusion: Separates complexes (larger) from unbound sequences (smaller). Capture Techniques: Using a brief, weak tag on the target (like biotin) to pull down complexes after binding in solution. Amplification: The bound sequences are eluted, amplified by PCR (for DNA) or RT-PCR (for RNA), and purified for the next round. Advantages of Free Solution SELEX: Native Target Conformation: The target is in its natural, free state. There's no risk of…
Aptamer Capture-SELEX Service refers to a specialized, outsourced process where a company or academic core facility performs the entire Capture-SELEX procedure to develop DNA or RNA aptamers for a client's specific target molecule. This is a crucial service for researchers and companies who need high-affinity, specific aptamers but lack the specialized equipment, expertise, or time to run the SELEX process in-house. Let's break down what this service entails. 1. What is Capture-SELEX? First, understand the standard SELEX (Systematic Evolution of Ligands by EXponential enrichment). It's an iterative process to select aptamers from a vast random oligonucleotide library (10^14 - 10^15 different sequences). Capture-SELEX is a specific variant designed primarily for small molecules or targets that are difficult to immobilize directly on a solid support without affecting their structure/function. The Key Difference: Instead of immobilizing the target itself, a short, complementary "capture strand" is immobilized on beads or a surface. The initial ssDNA library is designed with a region complementary to this capture strand. The target is free in solution. How it Works: The library is bound to the surface via the capture strand. The target molecule is introduced in solution. Only library sequences that fold into a structure capable of binding the target will undergo a conformational change. This binding event often weakens or…
What is Live Cell SELEX? Traditional SELEX uses purified target proteins. Live Cell SELEX uses intact, living cells in their native state. This is crucial because: It selects for aptamers that bind to targets in their natural conformation and post-translational modifications (e.g., glycosylation). It inherently selects for cell-specificity (e.g., cancer cell vs. healthy cell) without needing to know the exact molecular target upfront. It can discover aptamers against unknown or membrane-bound targets that are difficult to purify. Core Workflow of a Typical Service A full-service provider will manage the entire pipeline: 1. Project Design & Consultation Target Cell Line Definition: Defining the "positive" cell line (e.g., patient-derived cancer cells, activated immune cells). Counter-Selection Strategy: Choosing the "negative" cell line(s) (e.g., healthy counterpart, isogenic control) to eliminate non-specific binders. Library Design: Recommending or customizing the starting random oligonucleotide library (length, modifications like 2'-F pyrimidines for RNA aptamers for stability). 2. The Selection Phase (The Iterative SELEX Cycles) Incubation: The random library is incubated with the counter-selection cells. Unbound/non-specific sequences are collected. Positive Selection: The pre-cleared library is incubated with the target cells. Cells are washed stringently. Recovery: Cell-bound aptamers are recovered (e.g., by cell lysis, heat elution, or protease treatment). Amplification: Recovered sequences are amplified by PCR (for DNA) or RT-PCR (for…
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…
The unique secondary and tertiary structures of aptamers provide the specificity to detect even small structural changes in the target molecule, including the presence or absence of methyl or hydroxyl groups or differences in enantiomeric configurations. Aptamers that bind specific targets are identified through a process known as Systematic Evolution of Ligands by Exponential enrichment (SELEX) in which binding molecules are selected from a large and diverse library of nucleic acids (either DNAs or RNAs). In this process, the nucleic acid library is incubated with the target molecule. Non-binding nucleic acids are then washed away, leaving behind only the molecules that have a capacity to bind to the target molecule. The nucleic acids that are not washed away are then used to create a new library of nucleic acids that is enriched for the subset that binds the desired target. Repeating this selection-cycle on each subsequent library with increasing stringency of binding (e.g. lower concentration of target), ensures that nucleic acids that bind to the target with both high specificity and high affinity are enriched. Aptamers are short, single-stranded oligonucleotides (DNA or RNA) that bind to specific target molecules with high affinity and specificity. They are often called "chemical antibodies."…
