“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…
1. What is SELEX? SELEX stands for Systematic Evolution of Ligands by EXponential enrichment. It is a laboratory technique used to identify aptamers—short single-stranded DNA or RNA sequences that can bind specifically to a target molecule (proteins, small molecules, cells, or even viruses). Aptamers act similarly to antibodies but are synthetic, highly stable, and can be chemically modified. 2. Principle of SELEX The SELEX process is based on iterative rounds of selection and amplification: Library Preparation Start with a large randomized pool of oligonucleotides (typically 10^13–10^15 unique sequences). Each sequence is a potential aptamer candidate. Binding (Target Incubation) Incubate the library with the target molecule. Only sequences that can bind the target will stay attached; non-binders are washed away. Partitioning (Separation of Binders and Non-binders) Physically separate bound sequences from unbound sequences. Techniques depend on the target (magnetic beads, affinity columns, etc.). Elution Bound sequences are eluted (released) from the target. Amplification The eluted sequences are amplified using PCR (for DNA aptamers) or RT-PCR (for RNA aptamers). This generates an enriched pool for the next round. Iterative Rounds Steps 2–5 are repeated for 8–15 rounds to gradually enrich sequences with high affinity and specificity for the target. Sequence Identification After…
Core Principle & Typical Service Workflow A professional service for Conventional SELEX typically follows this established, iterative cycle (8-15 rounds), as visualized below: Key Service Characteristics Target Immobilization: The target molecule is fixed to a solid support (e.g., magnetic beads, column resin, nitrocellulose membrane). Positive Selection: The library is passed over the immobilized target. Sequences with some binding affinity are retained, while others are washed away. Stringency Control: The service provider systematically increases selection pressure across rounds (e.g., by reducing target concentration, increasing wash stringency, adding counter-targets in Negative SELEX steps) to drive the evolution of high-affinity, specific binders. Monitoring: Enrichment is tracked via quantitative PCR, and final pools are analyzed by Next-Generation Sequencing (NGS) to identify convergent sequence families. Common Applications for this Service This classic approach is ideal for: Proteins that are stable and can be immobilized without losing native conformation (e.g., antibodies, enzymes, recombinant tags). Large molecules or complexes (e.g., viruses, whole cells—though Cell-SELEX is now more common for cells). Establishing proof-of-concept for a new target class where simpler, robust methodology is preferred. Deliverables Similar to other SELEX services, clients receive: A final report detailing the selection process and conditions. A list of top-ranked aptamer sequences with affinity (Kd) and specificity data. Aliquots of synthesized, validated…
What is Filter Membrane Binding SELEX? SELEX (Systematic Evolution of Ligands by EXponential enrichment) is the standard method for discovering high-affinity, specific nucleic acid aptamers. The Filter Membrane Binding variant is one of the most classic and robust SELEX techniques. Core Principle: It leverages a nitrocellulose or mixed cellulose ester filter membrane, which irreversibly binds proteins and other macromolecules but allows short, unbound single-stranded DNA or RNA oligonucleotides to pass through. The Selection Mechanism: During each selection round, the target molecule (e.g., a protein) is immobilized on the filter. An immense library of random oligonucleotides (10^13 - 10^15 unique sequences) is applied. Only sequences that bind to the target are retained on the filter with it. Unbound sequences are washed away. The bound aptamer candidates are then eluted, amplified by PCR (or RT-PCR for RNA), and used as the enriched library for the next round. Key Features of the Service A professional service will typically offer: Target Flexibility: Optimal for purified proteins (recombinant or native), protein complexes, viruses, and even some small molecules if conjugated to a carrier protein. Counter-SELEX: A critical step to ensure specificity. The enriched library is passed through a filter bound to non-target molecules (e.g., related proteins, cell lysates, immobilization matrix) to subtract cross-reactive binders. High-Throughput…
Core Concept: What is SELEX? SELEX (Systematic Evolution of Ligands by EXponential Enrichment) is an iterative, in vitro selection process. It starts with a vast, random library of oligonucleotides (10^14 - 10^15 unique sequences) and, over multiple rounds, enriches for those that bind to the target. Standard Multi-Round SELEX Screening Service Workflow A full-service provider will typically manage the entire process, which can be broken down into key phases: Phase 1: Project Design & Target Preparation Target Consultation: Defining the target (e.g., protein, small molecule, cell, virus). Critical discussion of target purity, immobilization strategy, and selection conditions (buffer, temperature, counter-selection). Library Design: Selection of a random library (e.g., 40-nt random core with fixed primer sites). Options include DNA, RNA (requiring reverse transcription), or modified libraries (e.g., with 2'-F pyrimidines for nuclease resistance). Immobilization Strategy: The service provider will choose the best method: Immobilized Target: (Most common for proteins) Binding target to beads (streptavidin, Ni-NTA for His-tag) or columns. Counter-Selection: Using negative control surfaces (e.g., blank beads, related but undesired proteins) to subtract non-specific binders. Phase 2: The SELEX Cycle (Repeated 8-15 Rounds) This is the core iterative screening process. Each round consists of: Incubation: The oligonucleotide library is incubated with the target under defined conditions. Partitioning: Separation of…
Aptamer Screening via HT-SELEX (High-Throughput Systematic Evolution of Ligands by Exponential Enrichment) is the modern, powerful method for discovering aptamers. Let's break down what this service entails, its process, advantages, and key considerations. What is an Aptamer? First, a quick reminder: Aptamers are single-stranded DNA or RNA oligonucleotides that bind to a specific target molecule (proteins, small molecules, cells, viruses) with high affinity and specificity, analogous to antibodies. They are often called "chemical antibodies." What is HT-SELEX? Traditional SELEX is iterative and low-throughput. HT-SELEX supercharges this process by integrating: Next-Generation Sequencing (NGS): To analyze the entire aptamer pool at each round. Advanced Bioinformatics: To identify binding motifs and track enrichment. Automation: Using robotics for partitioning (e.g., magnetic beads, microfluidics) to increase throughput and reproducibility. This results in a faster, more efficient, and data-driven screening process. Standard HT-SELEX Service Workflow A typical service provider will follow these steps: 1. Project Design & Library Synthesis Target Preparation: You provide the target (recombinant protein, small molecule conjugate, whole cell, etc.). Its purity and stability are critical. Library Design: A randomized oligonucleotide library is synthesized (typically 10^14 - 10^15 unique sequences). Libraries can be DNA, RNA, or modified nucleotides (e.g., SOMAmers) for enhanced stability and affinity. 2. The Selection Rounds (Cycles of…
Core Concept of NGS-SELEX Traditional SELEX uses a few rounds of selection and cloning/Sanger sequencing of a handful of clones. NGS-SELEX performs deep sequencing (millions to billions of reads) at every selection round. This allows you to: Track the entire evolution of the oligonucleotide pool in real-time. Identify enriched sequences and families early. Perform sophisticated bioinformatics analysis to find winners, not just rely on final round abundance. Dramatically reduce the number of selection rounds needed (often 3-6 rounds instead of 8-15). Standard Service Workflow A full-service provider would typically offer the following pipeline: 1. Project Design & Library Synthesis Consultation: Target properties (protein, small molecule, cell), desired aptamer properties (Kd, specificity, buffer conditions). Library Design: Standard (40-60 nt random region) or custom (doped libraries, modified nucleotides like 2'-F, 2'-OMe, SOMAmers). Primer & Library Synthesis: Providing the initial, highly diverse DNA or RNA library (10^14 - 10^15 unique sequences). 2. SELEX Selection Immobilization: Immobilizing the target (on beads, column, plate) or using solution-based techniques (capture-SELEX, toggle-SELEX). Counter-Selection: Including steps to remove binders to immobilization matrix or off-targets. Stringency Control: Increasing selection pressure over rounds (e.g., reduced target concentration, increased wash stringency). Amplification: Careful PCR (with optimization to minimize bias) to regenerate the pool for the next round. 3. NGS & Core Bioinformatics Sample Preparation: Preparing sequencing…
What is Counter-SELEX? First, a quick recap of SELEX (Systematic Evolution of Ligands by EXponential Enrichment): SELEX is an iterative process to isolate specific DNA or RNA aptamers from a vast random library (10^14 - 10^15 sequences) that bind tightly to a target molecule (e.g., a protein, small molecule, cell). Counter-SELEX is a powerful refinement to this process. Its core purpose is to improve specificity by negative selection. How it works: During or between rounds of positive selection (binding to the desired target), the oligonucleotide pool is exposed to one or more counter-targets. The Goal: Sequences that bind to these counter-targets are deliberately removed or depleted from the pool. Only sequences that bind specifically to the desired target and not to the closely related counter-targets are carried forward. Common Counter-Targets: Structural analogs: For a small-molecule drug, you might use its inactive metabolite or a similar drug from the same class. Protein isoforms or family members: To develop an aptamer for a specific kinase, you'd use other kinases from the same family as counter-targets. Immobilization matrix: If the target is immobilized on beads, pre-incubating the library with "blank" beads removes matrix binders. Related cell types: For a cell-specific aptamer (e.g., cancer vs. healthy), the healthy cells are used as the counter-target. What Does a…
What is Protein SELEX? SELEX (Systematic Evolution of Ligands by EXponential Enrichment) is an iterative, in vitro process used to discover aptamers—single-stranded DNA or RNA molecules that bind to a specific target (like a protein) with high affinity and specificity. Protein SELEX specifically refers to using a purified protein as the target to isolate aptamers against it. These aptamers are often called "chemical antibodies" due to their similar binding function. Core Workflow of a Protein SELEX Service A professional service will manage this entire complex process, typically involving the following stages: 1. Project Design & Consultation Target Characterization: Discussing the target protein's properties (size, purity, stability, domains, post-translational modifications). Selection Strategy: Choosing the right SELEX variant (e.g., Nitrocellulose filter, Magnetic bead, Capillary Electrophoresis, or Cell-SELEX for membrane proteins). Defining counter-selection steps to avoid binders to unwanted tags or impurities. Library Design: Using a standard or custom random oligonucleotide library (e.g., 40-60 random nucleotides flanked by primer sites). 2. The SELEX Cycle (Repeated 8-15 Rounds) mermaid graph TD A[Start: ssDNA/RNA Library<br>~10^15 unique sequences] --> B{Incubation with<br>Target Protein}; B --> C[Partition: Separate<br>Bound from Unbound Sequences]; C --> D[Elution: Recover<br>Bound Sequences]; D --> E[Amplification:<br>PCR (DNA) or RT-PCR (RNA)]; E --> F[Purification:<br>Regenerate ssDNA/RNA for next round]; F --> G{Enrichment<br>Sufficient?}; G -- No…
Traditional SELEX (Systematic Evolution of Ligands by EXponential enrichment) is a method to select high-affinity, specific nucleic acid aptamers from a vast random library (10¹³-10¹⁵ sequences). The bottleneck has always been the final cloning and Sanger sequencing of only a few dozen candidates, which often misses rare, high-performance aptamers. NGS-assisted SELEX integrates Next-Generation Sequencing at multiple rounds of the SELEX process. This provides a massive, data-rich view of the entire evolutionary landscape, enabling intelligent selection and identification of the best aptamers. Typical Workflow of an NGS-Assisted SELEX Service A professional service provider will manage this entire pipeline: Project Design & Library Synthesis: Collaboration to define target (protein, small molecule, cell), counter-selection requirements, and library design (random region length, fixed primers for NGS). Parallel SELEX Execution: Performing the iterative selection process (binding, partitioning, amplification) across multiple rounds (usually 8-12). Key NGS Integration Points: Initial Library Analysis: Sequencing the naive library to confirm diversity and complexity. Monitoring Rounds (e.g., Rounds 3, 6, 9): Taking small samples from intermediate rounds for NGS. This is the critical advantage. It tracks: Sequence Enrichment: Which families are becoming more abundant. Diversity Collapse: When to stop selection before losing good candidates. Informed Decision-Making: Data guides adjustments in selection stringency for subsequent rounds. Final Round Deep Sequencing: Comprehensive NGS of…
