What is an Aptamer? An aptamer is a short, single-stranded DNA or RNA oligonucleotide that folds into a specific 3D structure, allowing it to bind to a target molecule (like a cytokine) with high affinity and specificity, akin to a monoclonal antibody. Why Target Cytokines with Aptamers? Cytokines are key signaling proteins in immune and inflammatory responses. Dysregulation is implicated in diseases like: Autoimmune disorders: Rheumatoid arthritis, psoriasis, inflammatory bowel disease. Cancer: Tumor microenvironment signaling. Cytokine Storms: Severe COVID-19, sepsis. Neurological diseases. Aptamers offer advantages over traditional antibody-based therapies: High Specificity: Can distinguish between closely related cytokine isoforms or conformational states. Controlled Synthesis: Chemically produced, no batch-to-batch variation. Modifiability: Easily conjugated with drugs, fluorophores, or nanoparticles. Low Immunogenicity: Less likely to cause an immune response. Stability: Generally more stable than proteins. The Aptamer Screening Service Workflow (SELEX) A professional service will manage the entire SELEX (Systematic Evolution of Ligands by EXponential Enrichment) process. Here’s a typical pipeline: Phase 1: Project Design & Target Preparation Consultation: Define the goal—neutralization, detection, or delivery. Target Selection: Which cytokine? (e.g., TNF-α, IL-6, IL-1β, IFN-γ). Requires a high-purity, bioactive protein. Services often help with recombinant expression/purification if needed. Library Design: A vast random-sequence oligonucleotide library (10^14-10^15 unique sequences) is the starting point. Libraries can be DNA, RNA, or contain modified…
What is an Aptamer? An aptamer is a short, single-stranded DNA or RNA oligonucleotide that binds to a specific target molecule (like a protein) with high affinity and specificity. They are often called "chemical antibodies" but offer advantages like smaller size, chemical stability, and in-vitro generation. The Core Service: SELEX (Systematic Evolution of Ligands by EXponential Enrichment) The standard method for aptamer screening is SELEX. A specialized service will manage this entire iterative, high-complexity process for you. General SELEX Workflow: Target Preparation & Immobilization: Your service provider will prepare your purified protein. It is often immobilized on a solid support (beads, column, plate) to separate bound from unbound sequences. Incubation with Library: A vast, random synthetic oligonucleotide library (10^13 - 10^15 unique sequences) is incubated with the target. Partitioning: Weak or non-binding sequences are washed away. Tightly bound aptamers are retained. Elution & Amplification: The bound sequences are eluted and amplified by PCR (for DNA) or RT-PCR (for RNA). Stringency & Counter-SELEX: Subsequent rounds introduce increased washing stringency and incubation with non-target molecules (e.g., similar proteins, immobilization matrix) to filter out non-specific binders. This is crucial for specificity. Cloning & Sequencing: After 8-15 rounds, the enriched pool is cloned and sequenced to identify individual candidate aptamers. Characterization &…
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…
What is Subtractive SELEX? It is a specialized version of SELEX used to generate aptamers (single-stranded DNA or RNA oligonucleotides) that bind with high affinity and specificity to a target of interest (e.g., a protein, cell, small molecule) while actively excluding binding to closely related non-targets (e.g., a non-pathogenic vs. pathogenic strain, a healthy vs. cancerous cell, or a target in a complex mixture). The "subtractive" step removes sequences that bind to unwanted counter-targets, ensuring the final aptamer pool is highly specific. Core Workflow of a Subtractive SELEX Service A typical service follows these key stages: 1. Project Design & Library Synthesis Client Consultation: Defining the target of interest (e.g., recombinant protein, whole cell) and the critical counter-target(s) for subtraction (e.g., isotype control protein, non-target cell line). Library Design: A service provider synthesizes a vast random-sequence oligonucleotide library (typically 10^14 - 10^15 unique sequences) flanked by constant primer regions. 2. The Subtractive SELEX Cycle (Repeated 8-15 Rounds) This is the iterative heart of the service: * a. Negative Selection (Subtraction): The oligonucleotide pool is incubated with the counter-target (or complex background, like serum). Sequences that bind to this unwanted material are discarded. * b. Positive Selection: The unbound sequences from (a) are then incubated with the target of interest. The bound sequences are recovered. * c. Washing: Non-specific or weakly bound sequences are washed away.…
Toggle-SELEX is a sophisticated and powerful variant of the traditional SELEX process for aptamer development, specifically designed to generate aptamers that recognize multiple, closely related targets or a specific epitope common across different species/conditions. Let's break down what an Aptamer Screening Service using Toggle-SELEX entails, its applications, and what you should consider when selecting a service provider. What is Toggle-SELEX? The core idea of Toggle-SELEX is to "toggle" or alternate the selection pressure between two (or more) related target molecules during the SELEX rounds. Traditional SELEX: Uses a single target to evolve aptamers with high affinity for that specific target. It often negatively selects against related molecules (counter-selection) to ensure specificity. Toggle-SELEX: Actively uses two positive selection targets in an alternating pattern. For example: Round 1: Select against Target A (e.g., human protein). Round 2: Select against Target B (e.g., mouse ortholog of the same protein). Round 3: Back to Target A, and so on. Counter-selection against unrelated structures is still used to maintain general specificity. This process enriches for nucleic acid sequences that bind to a conserved structural epitope present on both targets, while sequences that bind to unique epitopes on only one target are filtered out. Key Applications of Toggle-SELEX This method is invaluable when you need cross-reactive or broad-spectrum recognition: Cross-Species Reactive Aptamers: Develop aptamers for preclinical research. For example, an…
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…
Core Principle Nitrocellulose membrane filter binding exploits a simple but powerful property: nitrocellulose avidly binds proteins and protein-nucleic acid complexes, but does not efficiently bind free, single-stranded DNA or RNA. By passing a mixture of the target protein and a random oligonucleotide library through the membrane, sequences that bind to the protein are retained (as a complex), while unbound sequences are washed away. Typical Workflow of a Service Provider A professional service will manage this complex, iterative process for you: 1. Project Design & Library Synthesis Consultation: Defining your target (purified protein is essential), desired aptamer properties (affinity, specificity, buffer conditions), and format (DNA or RNA). Library Design: A synthetic library of up to 10^15 random sequences (e.g., 40-60 nt random core, flanked by constant primer regions) is prepared. 2. The SELEX Cycles (Iterative Screening) Incubation: The target protein is incubated with the nucleic acid library under optimized conditions (buffer, temperature, time). Positive Selection (Binding & Capture): The mixture is passed through a nitrocellulose membrane. Protein-aptamer complexes stick to the membrane. Washing: Mild washing removes weakly bound or non-specific sequences. Elution: Bound sequences are recovered by denaturing the protein (e.g., using heat, phenol-chloroform, or high-concentration urea). Amplification: For DNA SELEX: The eluted DNA is directly amplified by PCR. For…
What is Magnetic Bead SELEX? 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, similar to antibodies. Magnetic Bead SELEX is a widely used variant where the target molecule is immobilized on magnetic beads. This format offers significant advantages in automation, handling, and efficiency. Why Choose a Magnetic Bead SELEX Service? Developing aptamers in-house is time-consuming, requires specialized expertise, and involves significant optimization. A professional service provides: Expertise & Experience: Knowledge of library design, PCR optimization, and counter-selection strategies. Specialized Equipment: Access to automated magnetic separation systems, NGS, and bioinformatics. Time & Cost Efficiency: Faster turnaround (typically 2-4 months) than setting up a new lab. Higher Success Rate: Proven protocols to avoid common pitfalls like PCR bias or selection of non-specific binders. Typical Workflow of a Magnetic Bead SELEX Service Phase 1: Project Design & Target Preparation Consultation: You define the target (e.g., a protein, small molecule, cell), desired affinity (Kd), and application (diagnostics, therapeutics, sensors). Target Immobilization: The service provider chemically conjugates your target to the surface of magnetic beads (e.g., streptavidin-biotin, NHS-amine coupling). A "negative selection" bead (without target) is also prepared to remove…
What is Whole-tissue Section SELEX? It's an advanced Systematic Evolution of Ligands by EXponential enrichment (SELEX) technique where the selection target is not a purified protein or single cell type, but an intact, pathological tissue section (e.g., a slice of a human tumor biopsy on a glass slide). The core idea is to select DNA or RNA aptamers that bind specifically to the molecular landscape of diseased tissue, while simultaneously negating binding to adjacent healthy tissue from the same patient. The Standard SELEX vs. Whole-Tissue Section SELEX Feature Standard SELEX Whole-Tissue Section SELEX Target Purified protein, single cell type, or simple mixture. Complex, native tissue architecture with millions of molecular targets in their natural context. Goal Find an aptamer for a known, pre-defined target. Discover aptamers for unknown, disease-specific biomarkers without prior target identification. Context Target is isolated, may have altered conformation. Targets are in their native state, with intact post-translational modifications, protein complexes, and tissue microenvironments. Counter-Selection Against a buffer or a simple non-target (e.g., BSA). Against a serial section of adjacent healthy tissue from the same patient, ensuring disease specificity. Why Is This a Powerful Service? Target-Agnostic Discovery: You don't need to know the biomarker in advance. The process "lets the tissue decide" what the best molecular targets are.…
