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 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…
Core Concept The central idea is "Target-based Drug Discovery." Instead of screening compounds on whole cells or organisms (phenotypic screening), you start with a specific protein (e.g., a kinase, receptor, ion channel) implicated in a disease. Services then help you understand that target and find molecules that modulate it. Categories of Protein Target Services These services typically follow the drug discovery pipeline: 1. Target Identification & Validation Bioinformatics & Omics Analysis: Mining genomic, proteomic, and clinical data to identify novel disease-associated targets. Genetic Validation: CRISPR/Cas9 gene editing (knock-out/knock-in), siRNA/shRNA knockdown to confirm the target's role in disease pathways. Functional Validation: Cell-based assays to see if modulating the target affects disease-relevant phenotypes. 2. Protein Expression & Purification Recombinant Protein Production: Cloning, expressing (in E. coli, insect, or mammalian cells), and purifying milligram to gram quantities of the target protein. This is essential for structural studies and biochemical assays. Membrane Protein Expertise: Specialized services for difficult-to-express targets like GPCRs and ion channels. Tagging & Labeling: Adding tags (His, GST, FLAG) for purification or fluorescent/isotopic labels for assays. 3. Structural Biology & Biophysics X-ray Crystallography: Determining high-resolution 3D structures of protein-ligand complexes. Cryo-Electron Microscopy (Cryo-EM): For large complexes or membrane proteins unsuitable for crystallography. Nuclear Magnetic Resonance (NMR) Spectroscopy: For studying dynamics and ligand binding in solution. Surface…
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 are Aptamers? Aptamers are short, single-stranded DNA or RNA oligonucleotides (typically 20-80 nucleotides) that fold into specific three-dimensional shapes, enabling them to bind to target molecules with high affinity and specificity. They are often called "chemical antibodies." The process of creating them is called SELEX (Systematic Evolution of Ligands by EXponential enrichment), which iteratively selects aptamers from vast random-sequence libraries against a desired target (e.g., a protein, small molecule, or even a whole cell). Key Advantages of Aptamers as Therapeutics Compared to traditional protein-based biologics like antibodies, aptamers offer several compelling benefits: High Specificity & Affinity: Can distinguish between closely related targets (e.g., different protein isoforms). Small Size: Typically 8-25 kDa, much smaller than antibodies (~150 kDa). This can improve tissue penetration. Full Chemical Synthesis: Produced in vitro via chemical synthesis, eliminating batch-to-batch variability and the need for biological systems (cells or animals). This makes manufacturing scalable and consistent. Low Immunogenicity: Being nucleic acids, they are generally less likely to trigger immune reactions than foreign proteins. Excellent Stability: DNA aptamers, in particular, are thermally stable and can be stored easily. Stability in biological fluids can be engineered. Ease of Modification: Can be chemically modified to enhance stability (e.g., resist nucleases), prolong half-life (e.g., PEGylation), or add functional groups…
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."…
