Key Characteristics of a Toggle-SELEX Service: Alternating Rounds: The library is selected against Target A in one round, then against Target B in the next, and so on. The stringency can be adjusted in each path. Strategic Goal: The design is flexible. It can aim for aptamers that bind both A and B (by keeping sequences that bind each during its respective round) OR for aptamers that bind A but not B (by using B as a structured counter-selection). Applications: Ideal for developing diagnostics for variable pathogens (e.g., influenza, SARS-CoV-2 variants), targeting conserved regions in protein families, or creating sensors for a class of compounds (e.g., related antibiotics or toxins). Typical Service Workflow Outline: Design: Defining the two targets (A & B), the desired binding profile (broad or specific), and the toggling protocol. Library & Immobilization: Preparing a naive library, often with one target (e.g., Target A) immobilized. Toggling Selection Cycles: Iterative rounds where: Round A: Select for binders to immobilized Target A. Elute, recover, and amplify bound sequences. Round B: Use the enriched pool against immobilized Target B (either to capture shared binders or to discard cross-reactive ones). The process repeats, toggling between targets, with increasing stringency. Sequencing & Analysis: Identifying enriched sequence families and analyzing their binding patterns to both targets. Characterization: Testing candidate aptamers for affinity (Kd) against both Target A and Target…
What is Whole Cell-SELEX? SELEX (Systematic Evolution of Ligands by EXponential enrichment) is a technique used to develop aptamers—single-stranded DNA or RNA oligonucleotides that bind to a specific target molecule with high affinity and specificity, akin to antibodies. Whole Cell-SELEX is a variant where the target is not a purified protein, but an entire living cell. This is crucial for discovering aptamers against: Native cell-surface proteins in their natural conformation and modification state. Complex membrane protein complexes. Disease-specific cell markers (e.g., on cancer cells, pathogens) without prior knowledge of the specific molecular target. Specific cell types in a heterogeneous mixture (e.g., cancer stem cells within a tumor). A service provider performs this technically demanding and iterative process on behalf of researchers or companies. The Core Process of a Whole Cell-SELEX Service A typical service workflow involves close collaboration with the client: 1. Project Design & Consultation Defining Targets: Client specifies the positive selection cell (e.g., human glioblastoma cells) and the critical negative/counter selection cell (e.g., normal astrocytes or a related cell line). This is key to generating selective aptamers. Library Design: The service provider uses a vast (10^14 - 10^15 sequences) random oligonucleotide library. 2. The SELEX Cycle (Iterative Rounds) This is the core experimental phase performed by the service provider: Incubation: The library is incubated…
Membrane Protein Aptamer Screening Service is a highly specialized contract research service designed to discover aptamers that bind to integral membrane proteins, such as GPCRs, ion channels, transporters, and receptor tyrosine kinases. This is one of the most challenging and technically demanding areas of aptamer development due to the inherent complexity of maintaining the native structure and function of membrane proteins outside their lipid environment. Unique Challenges & Solutions: Target Integrity: The target protein must be kept in its native, correctly folded conformation. Services use advanced systems like: Nanodiscs: Membrane proteins embedded in a lipid bilayer stabilized by a belt protein (e.g., MSP). Proteoliposomes: Reconstituted into lipid vesicles. Detergent Micelles: Using compatible mild detergents. Whole Cell-SELEX (or Cell-SELEX): Using live cells expressing the target protein, ensuring native presentation and post-translational modifications. Hydrophobicity: The screening process must manage hydrophobic surfaces to prevent non-specific selection of sequences that simply bind lipids or detergents through careful counter-selection strategies. Specialized Screening Workflow: 1. Project Design & Target Presentation: Define Target & Goal: Specify the membrane protein (e.g., human EGFR, specific GPCR) and desired aptamer function (antagonist, agonist, simple binder for detection). Choose Presentation Platform: This is the most critical decision. The provider will advise on the optimal system: Purified Protein in Mimetics: Best for defined specificity…
What is an Aptamer? Aptamers are single-stranded DNA or RNA oligonucleotides that fold into specific 3D shapes, enabling them to bind to target molecules (proteins, small molecules, cells, viruses) with high affinity and specificity, similar to antibodies. They are often called "chemical antibodies." Why Use Aptamer Screening Services in Drug Discovery? Efficiency: Outsourcing to experts with specialized platforms (SELEX) accelerates discovery. Cost-Effectiveness: Avoids capital investment in complex SELEX and NGS infrastructure. Expertise: Leverages specialized knowledge in oligonucleotide chemistry, bioinformatics, and target biology. Focus: Allows internal teams to concentrate on downstream therapeutic development. Core Components of an Aptamer Screening Service A full-service provider typically offers an end-to-end pipeline: 1. Project Design & Target Preparation Consultation: Defining the target (recombinant protein, cell surface marker, whole cell), desired affinity (nM-pM), and specificity (e.g., against homologs). Counter-SELEX Strategy: Planning to eliminate binders to non-desired epitopes or related targets to ensure high specificity. 2. In Vitro Selection (SELEX) The core technology is SELEX (Systematic Evolution of Ligands by EXponential enrichment). Advanced variants are used for complex targets: Protein-SELEX: For purified recombinant proteins. Cell-SELEX: For membrane proteins in their native conformation on live cells; identifies aptamers for diseased vs. healthy cells. Tissue-SELEX: For even more complex biological environments. Capture-SELEX: For small molecules that are difficult to immobilize. High-Throughput SELEX (HT-SELEX): Uses NGS early…
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 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.…
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…
