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Strep-tag

The Strep-tag is a short synthetic affinity tag designed for the one-step purification and detection of recombinant proteins via specific binding to or its engineered derivatives, such as Strep-Tactin. The original Strep-tag consists of a nine-amino-acid sequence (AWRHPQFGG) that exhibits intrinsic affinity for , enabling gentle elution with while maintaining protein functionality. Developed in the early 1990s by Thomas G.M. Schmidt and Arne Skerra through screening of a random library expressed on the surface of the fragment of an , the tag was initially optimized for C-terminal to facilitate without disrupting or activity. A modified version, Strep-tag II (sequence: WSHPQFEK), was subsequently introduced to allow versatile placement at either the N- or C-terminus of proteins, with a (Kd) of approximately 1–13 μM to wild-type and improved binding (Kd ≈ 1 μM) to Strep-Tactin. This variant binds up to 100-fold more tightly to Strep-Tactin than to native , reducing non-specific interactions and enabling under mild physiological conditions using 2.5 mM desthiobiotin, which preserves enzymatic activity and protein complexes. Further enhancements include the Twin-Strep-tag, comprising two Strep-tag II sequences linked by a short flexible (e.g., WSHPQFEK-GGGSGGGS-WSHPQFEK), which increases and binding strength (Kd ≈ 30 nM to Strep-Tactin) for higher purification efficiency, particularly in complex matrices like mammalian cell lysates. The technology is compatible with various expression systems, including E. coli, , and mammalian cells, and supports applications beyond purification, such as protein detection via Strep-tag-specific antibodies, for studies, and workflows. Compared to other tags like , Strep-tag offers superior specificity (>95% purity in single-step protocols), resistance, and minimal interference with protein function due to its small size and neutral charge, though it requires biotin-free environments to avoid competition. Engineered mutants, such as those with stabilized "open" lid conformations (e.g., SAm1 and SAm2), further enhance affinity through entropic gains, as revealed by crystallographic studies. Overall, the Strep-tag system remains a cornerstone in for its balance of affinity, gentleness, and versatility in handling challenging proteins.

History and Development

Invention and Early Design

The Strep-tag was invented by Thomas G. M. Schmidt and Arne Skerra in 1993 while working at the Max-Planck-Institut für Biophysik, , . The design aimed to create a genetically encodable tag that could mimic the high-affinity biotin-streptavidin interaction for and detection, thereby eliminating the need for chemical of recombinant proteins. This approach leveraged streptavidin's natural binding pocket to enable reversible, one-step under mild conditions. The original Strep-tag I is a nine-amino-acid with AWRHPQFGG, selected through a stepwise screening process from a genetic library of random peptides displayed as C-terminal fusions to a model antibody fragment ( of the D1.3 Fv). From a genetic library of random peptides expressed as C-terminal fusions in , through iterative rounds of and selection on -coated surfaces to optimize binding while preserving the host protein's functionality. The final peptide exhibited moderate for native streptavidin, occupying the biotin-binding site without irreversible attachment. The first experimental validation appeared in a 1994 publication, where Strep-tag I was fused to the of various recombinant proteins, including the bacterial 562, and expressed in E. coli. These fusions demonstrated effective one-step purification on immobilized recombinant core columns, with yields up to 140 mg per liter of culture and elution using free under nondenaturing conditions. and later quantified the initial binding affinity to native as Kd ≈ 37 μM, confirming its utility for proof-of-concept applications in bacterial expression systems despite the modest strength compared to (Kd ≈ 10-15 M).

Optimization to Strep-tag II

Following the initial development of the original Strep-tag in 1994, which comprised a nine-amino-acid sequence (AWRHPQFGG) suitable primarily for C-terminal fusions to recombinant proteins, researchers optimized the system in the late to enhance versatility and binding efficiency. This led to Strep-tag II, an eight-amino-acid (WSHPQFEK) designed for stronger intrinsic affinity toward while reducing overall size to minimize potential interference with protein function. The shortened sequence maintained the core binding but improved compatibility for both N- and C-terminal attachments, as well as internal positioning within polypeptides, without compromising specificity. A major advancement came with the engineering of Strep-Tactin, a streptavidin analogue featuring targeted mutations in the lid-like loop region (residues 45–52) to stabilize an open conformation at the binding site. This modification increased the affinity of Strep-tag II for Strep-Tactin by approximately 100-fold compared to native streptavidin, achieving a dissociation constant (K_d) of about 1 μM, which facilitates efficient one-step purification under mild conditions. The structural basis for this enhancement was elucidated through crystallographic studies, confirming that the optimized loop allows better accommodation of the peptide ligand. The refined Strep-tag II system was standardized for practical use in a 2007 protocol, enabling rapid purification of fusion proteins and their complexes from diverse expression systems, including bacterial and eukaryotic sources. Extensive testing demonstrated the tag's biochemical inertness, with minimal disruption to , membrane translocation, or enzymatic activity in various recombinant constructs. Additionally, Strep-tag II exhibits high proteolytic stability under physiological conditions and compatibility with standard buffers at pH greater than 7, ensuring broad applicability without requiring harsh agents.

Biochemical Properties

Peptide Sequence and Structure

The Strep-tag II is a short synthetic composed of eight with the sequence Trp-Ser-His-Pro-Gln-Phe-Glu-Lys (WSHPQFEK). This sequence corresponds to a molecular weight of approximately 1 kDa. The was rationally designed as an optimized variant of the original nine-residue Strep-tag I to enhance performance while maintaining a compact size. As a linear , the Strep-tag II lacks defined secondary in isolation, adopting a flexible conformation that minimizes interference with the host protein's folding. Key structural features include the presence of (Trp) and (His) residues, which contribute to hydrophobic and potential coordination properties, alongside a balanced composition of polar and non-polar that supports overall neutrality. The Strep-tag II exhibits high placement flexibility, functioning effectively when fused to the , , or even internal positions of a target protein, provided it does not disrupt the protein's native function or structure. Its biophysical properties include high aqueous solubility due to the hydrophilic residues (Ser, Gln, Glu, Lys), resistance to degradation by common cellular proteases, and chemical inertness that avoids altering the or aggregation propensity of fusion proteins in neutral cellular environments. For recombinant expression, the Strep-tag II sequence is genetically encoded using codon-optimized DNA constructs tailored for various host systems, such as Escherichia coli or mammalian cells, to ensure efficient translation without rare codon biases.

Binding to Streptavidin Analogues

The Strep-tag II peptide, a short eight-amino acid sequence (WSHPQFEK), serves as the binding motif that interacts specifically with Strep-Tactin, an engineered streptavidin analogue designed to recognize this peptide with enhanced affinity compared to native streptavidin. The molecular basis of this interaction involves the peptide occupying the biotin-binding pocket of Strep-Tactin, where it mimics aspects of biotin's binding mode but exploits distinct structural features of the engineered ligand. Crystal structures of Strep-Tactin mutants in complex with Strep-tag II reveal that the peptide adopts an extended conformation within this pocket, enabling key residue-specific contacts that drive the association. Central to the binding are hydrophobic interactions involving the (Trp2) and (Phe6) residues of the Strep-tag II, which engage complementary hydrophobic pockets on Strep-Tactin formed by aromatic residues such as Tyr43, Tyr54, and Trp79. These engagements stabilize the complex through van der Waals forces and contribute to the overall specificity. The of this under physiological conditions (pH 7–8, low concentrations around 150 mM NaCl) is characterized by a (Kd) of approximately 1 μM, reflecting a balance between enthalpic contributions from these contacts and entropic gains from the pre-organized "open" conformation of Strep-Tactin's lid-like loop. In contrast, the Kd for native is about 13 μM, underscoring the engineering improvements in Strep-Tactin. The reversible nature of the Strep-tag II–Strep-Tactin interaction arises from a moderate off-rate, which is further reduced through multivalency in the tetrameric of Strep-Tactin; each subunit's can cooperatively stabilize the , enhancing without compromising releasability. This multimeric arrangement minimizes while maintaining specificity, as Strep-Tactin shows low with native or other biotin-mimicking peptides due to the tailored pocket geometry that favors the Strep-tag II's unique sequence. Environmentally, the binding remains stable in the presence of mild detergents, such as up to 1% dodecyl-β-D-maltoside or Igepal CA-630, which are commonly used for solubilization, but it is sensitive to extreme values outside the optimal range, with reduced observed below 6 or above 9.

Purification Principle

Strep-Tactin System

The Strep-Tactin system utilizes Strep-Tactin, an engineered tetrameric mutant with modified biotin-binding pockets to enable reversible, high-specificity binding to the Strep-tag peptide under physiological conditions. This is covalently immobilized on solid supports such as cross-linked resins, including beads, to form affinity matrices suitable for column or batch purification formats. The binding affinity of Strep-Tactin for the Strep-tag II is in the micromolar range, facilitating selective capture without disrupting . The purification workflow follows a one-step protocol beginning with cell lysis in neutral buffers, such as or , to release the Strep-tagged recombinant protein while maintaining compatibility with additives like inhibitors. The lysate is then applied to the Strep-Tactin resin, where the target protein binds selectively at neutral (typically 7.0–8.0) due to the specific peptide-ligand interaction. Washing steps employ buffers supplemented with non-ionic detergents, such as up to 2% or Tween 20, along with salts (up to 1 M NaCl) to remove non-specifically bound contaminants without eluting the target. This system is compatible with both prokaryotic expression hosts like E. coli and eukaryotic systems such as mammalian cells, allowing purification from diverse sources while preserving protein functionality. It routinely achieves greater than 95% purity in a single step, attributed to the high specificity of the interaction. The protocol scales effectively from analytical levels (milligrams of protein) using spin columns or small gravity-flow setups to preparative scales (grams) via larger FPLC columns or batch processes. Strep-Tactin is commercially available through IBA Lifesciences, the patent holder, in various formats including pre-packed columns, bulk resins, and complete kits optimized for gravity-flow or FPLC applications.

Elution and Regeneration

In the Strep-tag system, elution of bound proteins from Strep-Tactin is achieved through competitive displacement using desthiobiotin at concentrations ranging from 0.1 to 2.5 mM, typically in a such as 100 mM Tris/HCl ( 8.0), 150 mM NaCl, and 1 mM EDTA. This process occurs under mild, physiological conditions that avoid harsh denaturants like or low , thereby preserving the and structural integrity of the eluted proteins, including multi-subunit complexes. An alternative elution strategy employs , which binds more tightly to Strep-Tactin and results in irreversible displacement, necessitating subsequent regeneration of the matrix but allowing for complete release in cases where desthiobiotin affinity is insufficient. Regeneration of the Strep-Tactin matrix following involves washing with denaturing agents to remove residual or desthiobiotin and restore binding capacity. Common protocols use 6 M HCl for up to 30 minutes or 100 mM NaOH (freshly prepared) applied in multiple column volumes (e.g., 15 ), followed by extensive rinsing with buffer to neutralize and re-equilibrate the . These treatments effectively strip bound ligands without compromising the matrix, enabling reuse for 10 or more cycles while retaining over 90% of the original binding capacity. Elution yields in the Strep-tag system typically achieve 80-95% recovery of functional proteins, with any residual desthiobiotin removable post-elution via or if needed for downstream applications. The process is compatible with physiological salt concentrations (e.g., 150 mM NaCl) and mild detergents, minimizing risks of or aggregation during release.

Applications

Recombinant Protein Purification

The Strep-tag II is genetically fused to the N- or C-terminus of a target protein during cloning to enable affinity-based purification. This fusion is typically achieved by inserting the Strep-tag II sequence (WSHPQFEK) into expression vectors such as pET series for bacterial systems like Escherichia coli, or pcDNA derivatives for mammalian cells, allowing seamless integration via restriction enzyme sites or PCR-based methods. Similar vectors are available for yeast (Saccharomyces cerevisiae) and insect cell expression, supporting a range of host organisms to match the protein's folding requirements. In bacterial expression, Strep-tag II fusions are induced using IPTG in systems like , yielding soluble proteins that bind specifically to Strep-Tactin resin under physiological conditions, followed by with desthiobiotin. For mammalian expression via pcDNA vectors, transient in HEK293 cells produces glycosylated proteins suitable for eukaryotic studies, with purification maintaining native-like conditions to preserve folding. and systems offer intermediate options for proteins requiring post-translational modifications, with overall yields often exceeding 1 mg/L culture depending on the target. Case studies demonstrate effective purification of enzymes like , where C-terminal Strep-tag II fusion in E. coli allowed single-step isolation with full retention of bioluminescent activity, enabling downstream assays without tag interference. This example highlights the tag's compatibility with functional proteins. Strep-tag II enables single-step purification to near-homogeneity, typically achieving >95% purity from crude lysates with minimal co-purification of host cell proteins due to the tag's high specificity (Kd ≈ 1 μM). This results in low contamination levels, often <5% non-specific binders, making it ideal for structural biology preparations. In proteomics, the system's compatibility with automated platforms supports high-throughput screening, processing hundreds of samples per run for interaction studies or library expression. To obtain tag-free proteins, Strep-tag II fusions are often engineered with an intervening protease cleavage site, such as TEV or factor Xa, positioned between the tag and the target protein. Post-purification, incubation with the specific protease removes the tag in a single step, followed by a secondary passage over Strep-Tactin to separate cleaved products, yielding >90% untagged protein without activity loss in most cases.

Detection and Functional Studies

The Strep-tag system facilitates sensitive detection of recombinant proteins in immunological assays such as Western blotting and enzyme-linked immunosorbent assay (), leveraging conjugates like Strep-Tactin fused to (HRP). In Western blotting, Strep-Tactin-HRP enables direct visualization of Strep-tagged proteins on membranes without the need for secondary antibodies, achieving detection limits in the nanogram range (typically 1-10 ng per band) through chemiluminescent or chromogenic substrates, with recommended dilutions of 1:4,000 for chromogenic detection or up to 1:100,000 for chemiluminescence. For ELISA, the same conjugate supports quantitative detection of Strep-tagged analytes in sandwich formats, with dilutions ranging from 1:2,000 to 1:10,000 yielding signal-to-noise ratios suitable for low-abundance proteins, often down to nanogram levels per well. Beyond static detection, the Strep-tag enables protein immobilization for dynamic studies of interactions, such as in (SPR) and pull-down assays. In SPR, Strep-tagged proteins are captured on Strep-Tactin-coated sensor chips, allowing real-time monitoring of binding kinetics with interacting partners while preserving native conformations, with association constants often in the nanomolar range for high-affinity pairs. Pull-down assays utilize Strep-Tactin magnetic beads to immobilize Strep-tagged bait proteins under native conditions, co-capturing interacting partners for downstream identification by or , thereby mapping protein-protein interaction networks without denaturing quaternary structures. These methods often follow initial purification steps to enrich the tagged protein. For functional assays at the single-molecule level, the Strep-tag serves as a tethering handle in experiments, enabling precise manipulation and force of individual proteins. Monovalent Strep-Tactin derivatives bind the Strep-tag II with high specificity ( ~1 μM), allowing site-directed attachment to optical traps for studying mechanical properties, such as unfolding pathways or ligand-induced conformational changes, in . This approach has been applied to track Strep-tagged enzymes or receptors under physiological forces, revealing insights into that ensemble methods cannot resolve. The Strep-tag also supports the isolation of native protein complexes for , capturing multi-subunit assemblies intact during steps. Using Strep-Tactin resins, complexes are pulled down under mild, non-denaturing buffers, maintaining interactions critical for enzymatic activity or signaling, as demonstrated in tandem protocols that yield highly pure native assemblies for reconstitution studies. This preserves quaternary structure, enabling downstream assays like activity profiling or interaction mapping without disruption. Recent applications include integration with techniques, such as TurboID, for mapping protein interactions in live cells (as of 2024) and in structural workflows (as of 2025). In vivo applications of the Strep-tag remain limited, particularly for live-cell imaging, due to its reliance on -based detection that introduces bulkiness and potential interference with cellular dynamics despite the tag's small size (8 ). While the tag itself is inert and minimally perturbative, conjugating fluorescent derivatives often results in suboptimal brightness or localization in dynamic environments, restricting its use to fixed-cell or contexts rather than real-time tracking.

Variants and Enhancements

Twin-Strep-tag

The Twin-Strep-tag is a variant of the Strep-tag II affinity tag designed to enhance binding affinity through bivalent interaction with Strep-Tactin. It consists of two Strep-tag II sequences (WSHPQFEK) connected by a flexible linker, with the predominant version having the full sequence SAWSHPQFEKGGGSGGGSGGSAWSHPQFEK, resulting in a total length of 30 . This tandem arrangement allows both Strep-tag II units to bind simultaneously to a single Strep-Tactin tetramer, promoting synergistic binding that significantly reduces the dissociation rate compared to the monomeric Strep-tag II. Developed in 2013 by Schmidt et al., the Twin-Strep-tag addresses limitations of the original Strep-tag II, such as insufficient in low-concentration or dilute samples, by leveraging effects for more stable complex formation under physiological conditions. The design maintains compatibility with the Strep-Tactin system while improving overall performance for demanding purification scenarios. The affinity of the Twin-Strep-tag to Strep-Tactin is approximately 10-fold higher than that of Strep-tag II alone, with a (Kd) in the range of 10-100 , primarily due to the lowered off-rate from bivalent engagement. This boost enables the use of more stringent washing conditions during purification, minimizing non-specific binding and improving yield from challenging samples. In applications, the Twin-Strep-tag excels in the purification of weakly expressed or unstable recombinant proteins, where standard tags may fail due to insufficient retention, as well as in high-stringency pull-down assays requiring robust complex stability. For instance, it facilitates efficient recovery of proteins from large-volume mammalian supernatants, preserving functionality without harsh denaturants. Elution of Twin-Strep-tag fusions from Strep-Tactin remains compatible with competitive using desthiobiotin, a analog that binds the engineered pocket, though the higher affinity often necessitates elevated concentrations (e.g., 5-50 mM) or prolonged incubation for complete recovery under mild, non-denaturing conditions.

Strep-Tactin XT and Other Ligands

Strep-Tactin XT represents an advanced engineered streptavidin variant designed to enhance the affinity and versatility of the Strep-tag system. Developed and patented by IBA Lifesciences, it was introduced around to provide significantly higher binding strength compared to the original Strep-Tactin, achieving approximately 10-fold improvement in affinity for the Strep-tag , with a (Kd) of about 100 nM. This variant maintains compatibility with the standard Strep-tag sequence without requiring any modifications, while also optimizing performance for the Twin-Strep-tag through synergistic bivalent binding. The binding mechanism of Strep-Tactin XT relies on multimeric effects, where the tetrameric structure of the facilitates cooperative interactions with the tag, stabilizing the complex under varied conditions. of bound proteins is achieved using -based competitors, which reversibly displace the tag from the binding pocket due to the ligand's retained affinity for . Strep-Tactin XT demonstrates broad buffer tolerance, operating effectively across a range of 6 to 9 and in the presence of denaturants, high concentrations, detergents, reducing agents, and chelators, robust purification in diverse experimental setups. Beyond the standard resin formats, Strep-Tactin XT has been adapted into engineered ligands for specialized applications, such as magnetic beads (e.g., MagStrep XT) and conjugates, which support automated workflows and high-throughput processing. These variants preserve the core high-affinity properties while improving handling in dynamic systems like flow-based or robotic platforms.

Advantages and Limitations

Key Benefits

The Strep-tag system offers high specificity in due to its engineered peptide-ligand interaction with Strep-Tactin, which minimizes non-specific binding of host cell proteins, unlike the system that relies on coordination with metal ions such as Ni²⁺ and is prone to co-purification of contaminants. This specificity enables the achievement of over 95% purity in a single step for many recombinant proteins, reducing the need for additional polishing steps. A key advantage is the use of mild, physiological conditions with desthiobiotin or , which preserve the native , , and post-translational modifications of the target protein, in contrast to larger tags like or MBP that often require harsher agents such as or , potentially disrupting sensitive modifications or requiring reducing agents to maintain . These gentle conditions are particularly beneficial for purifying enzymes, membrane proteins, or complexes where activity retention is critical, yielding functional proteins without denaturation. The Strep-tag's small size, consisting of just 8-9 , ensures versatility by avoiding steric hindrance to the fusion partner's folding, localization, or interactions, making it suitable for N- or C-terminal across diverse expression systems from bacteria to mammalian cells. Additionally, the Strep-Tactin resins are reusable after regeneration with , typically for 3-5 cycles or more without performance loss, which lowers costs and supports high-throughput applications. Purification protocols using the Strep-tag are notably rapid, often completing in 1-2 hours via gravity flow or spin columns, compared to multi-step processes required for untagged proteins that may involve , , or multiple chromatographic steps. Typical recovery rates range from 80-95% of the target protein, with even higher yields up to 98% achievable under optimized conditions, demonstrating efficient capture and elution. This scalability extends from small-scale laboratory preparations to industrial bioprocessing, facilitating consistent production of milligram to gram quantities.

Comparative Drawbacks

The Strep-tag system relies on proprietary Strep-Tactin resins and desthiobiotin for elution, which are generally more expensive than the widely available Ni-NTA resins and used for purification, potentially increasing overall costs for large-scale or routine applications. Although rare, the Strep-Tactin resin can exhibit non-specific binding to endogenous ylated proteins present in cell lysates, such as the biotin carboxyl carrier protein in E. coli, necessitating additional steps like pre-incubation to block these interactions and ensure specificity. The non-covalent affinity of the Strep-tag to Strep-Tactin, while specific, is lower than that of covalent tags like , which form irreversible bonds suitable for stable protein immobilization in assays or surfaces, making the standard Strep-tag less ideal for applications involving very low-expression targets unless enhanced variants such as Twin-Strep-tag are employed. The Strep-tag system performs optimally at values above 7, preferably around 8, which can limit its use in protocols requiring acidic extraction conditions, such as certain isolations or denaturing environments below 7. Compared to the , the Strep-tag is less universal for high-throughput initial screening due to its reliance on specialized proprietary materials, though it generally yields higher purity than poly-Arg tags, which suffer from non-specific ionic interactions and aggregation risks during purification.

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