World Library  
Flag as Inappropriate
Email this Article

Biotinylation

Article Id: WHEBN0000909363
Reproduction Date:

Title: Biotinylation  
Author: World Heritage Encyclopedia
Language: English
Subject: Biotin, Wiki Ed/Ohio University/Writing in the Life Sciences (Fall), Avidin, Biological processes, Photobiotin
Collection:
Publisher: World Heritage Encyclopedia
Publication
Date:
 

Biotinylation

In biochemistry, biotinylation is the process of covalently attaching biotin to a protein, nucleic acid or other molecule. Biotinylation is rapid, specific and is unlikely to perturb the natural function of the molecule due to the small size of biotin (MW = 244.31 g/mol). Biotin binds to streptavidin and avidin with an extremely high affinity, fast on-rate, and high specificity, and these interactions are exploited in many areas of biotechnology to isolate biotinylated molecules of interest. Biotin-binding to streptavidin and avidin is resistant to extremes of heat, pH and proteolysis, making capture of biotinylated molecules possible in a wide variety of environments. Also, multiple biotin molecules can be conjugated to a protein of interest, which allows binding of multiple streptavidin, avidin or Neutravidin protein molecules and increases the sensitivity of detection of the protein of interest. There is a large number of biotinylation reagents available that exploit the wide range of possible labelling methods.

Contents

  • Labeling methods 1
    • Enzymatic biotinylation 1.1
    • Primary amine biotinylation 1.2
    • Sulfhydryl biotinylation 1.3
    • Carboxyl biotinylation 1.4
    • Glycoprotein biotinylation 1.5
    • Oligonucleotide biotinylation 1.6
    • Non-specific biotinylation 1.7
  • Purpose 2
    • Purification 2.1
    • Detection 2.2
  • Other uses 3
  • Determining the extent of biotinylation 4
    • HABA assay 4.1
    • Streptavidin gel-shift 4.2
  • Further reading 5
  • References 6

Labeling methods

Proteins can be biotinylated chemically or enzymatically. Chemical biotinylation utilises various conjugation chemistries to yield nonspecific biotinylation of amines, carboxylates, sulfhydryls and carbohydrates (e.g., NHS-coupling gives biotinylation of any primary amines in the protein). Enzymatic biotinylation results in biotinylation of a specific lysine within a certain sequence by a bacterial biotin ligase.[1] Most chemical biotinylation reagents consist of a reactive group attached via a linker to the valeric acid side chain of biotin. As the biotin binding pocket in avidin / streptavidin is buried beneath the protein surface, biotinylation reagents possessing a longer linker are desirable, as they enable the biotin molecule to be more accessible to binding avidin/streptavidin/Neutravidin protein. This linker can also mediate the solubility of biotinylation reagents; linkers that incorporate poly(ethylene) glycol (PEG) can make water-insoluble reagents soluble or increase the solubility of biotinylation reagents that are already soluble to some extent.

Enzymatic biotinylation

In contrast to chemical biotinylation methods, enzymatic biotinylation allows biotin to be linked at exactly one residue present in the protein. This biotinylation reaction can also go to completion, meaning that the product is generated with high uniformity and can be linked to streptavidin in a defined orientation e.g. for MHC multimers. Enzymatic biotinylation is most often carried out by genetically linking the protein of interest at its N-terminus, C-terminus or at an internal loop to a 15 amino acid peptide, termed AviTag or Acceptor Peptide (AP).[2] The tagged protein is then incubated with biotin ligase (BirA) in the presence of biotin and ATP.[2] Enzymatic biotinylation can be carried out in vitro but BirA also reacts specifically with its target peptide inside mammalian and bacterial cells and at the cell surface, while other cellular proteins are not modified.[3][4][5]

Primary amine biotinylation

The most common targets for modifying protein molecules are primary amine groups that are present as lysine side chain epsilon-amines and N-terminal α-amines. Amine-reactive biotinylation reagents can be divided into two groups based on water solubility.

dimethyl sulfoxide (DMSO) and dimethyl formamide (DMF), which are compatible with most proteins at low concentrations. Because of the hydrophobicity of NHS-esters, NHS biotinylation reagents can also diffuse through the cell membrane, meaning that they will biotinylate both internal and external components of a cell.

Sulfo-NHS esters are more soluble in water and should be dissolved in water just before use because they hydrolyze easily. The water solubility of sulfo-NHS-esters stems from their cell membrane.

The chemical reactions of NHS- and sulfo-NHS esters are essentially identical, in that they both react spontaneously with amines to form an amide bond. Because the target for the ester is a deprotonated primary amine, the reaction is favored under basic conditions (above pH 7). Hydrolysis of the NHS ester is a major competing reaction, and the rate of hydrolysis increases with increasing pH. NHS- and sulfo-NHS-esters have a half-life of several hours at pH 7 but only a few minutes at pH 9.

There is some flexibility in the conditions for conjugating NHS-esters to primary amines. Incubation temperatures can range from 4-37°C, pH values in the reaction range from 7-9, and incubation times range from a few minutes to 12 hours. Buffers containing amines (such as Tris or glycine) must be avoided, because they compete with the reaction.

Sulfhydryl biotinylation

An alternative to primary amine biotinylation is to label sulfhydryl groups with biotin. Because free sulfhydryl groups are less prevalent on most proteins compared to primary amines, sulfhydryl biotinylation is useful when primary amines are located in the regulatory domain(s) of the target protein or when a reduced level of biotinylation is required. Sulfhydryl-reactive groups such as maleimides, haloacetyls and pyridyl disulfides, require free sulfhydryl groups for conjugation; disulfide bonds must first be reduced to free up the sulfhydryl groups for biotinylation. If no free sulfhydryl groups are available, lysines can be modified with various thiolation reagents (Traut's reagent, SAT(PEG4), SATA and SATP), resulting in the addition of a free sulfhydryl. Sulfhydryl biotinylation is performed at a slightly lower pH (6.5-7.5) than labeling with NHS esters.

Besides whole proteins, biotinylated peptides can be synthesized by introducing a cysteine (Cys) residue during synthesis at the terminus of the amino acid chain to get a site specific and oriented biotinylation. Nucleotides can also be biotinylated by incorporation of biotinylated nucleotides.

Carboxyl biotinylation

Carboxyl groups are found on the C-terminal ends of proteins and on glutamate and aspartate amino acid side chains. Biotinylation reagents that target carboxyl groups do not have a carboxyl-reactive moiety per se but instead rely on a carbodiimide crosslinker such as EDC to bind the primary amine on the biotinylation reagents to the carboxyl group on the target protein.

Biotinylation at carboxyl groups occur at pH 4.5–5.5. To prevent crossreactivity of the crosslinker with buffer constituents, buffers should not contain primary amines (e.g., Tris, glycine) or carboxyls (e.g., acetate, citrate); MES buffer is an ideal choice.

Glycoprotein biotinylation

Glycoproteins can be biotinylated by modifying the carbohydrate residues to aldehydes, which then react with hydrazine- or alkoxyamine-based biotinylation reagents. Sodium periodate oxidizes the sialic acids on glycoproteins to aldehydes to form these stable linkages at pH 4–6.

Polyclonal antibodies are heavily glycosylated, and because glycosylation does not interfere with the antibody activity, biotinylating the glycosyl groups is an ideal strategy to generate biotinylated antibodies.

Oligonucleotide biotinylation

Oligonucleotides are readily biotinylated in the course of oligonucleotide synthesis by the phosphoramidite method using commercial biotin phosphoramidite.[6] Upon the standard deprotection, the conjugates obtained can be purified using reverse-phase or anion-exchange HPLC

Non-specific biotinylation

Photoactivatable biotinylation reagents are ideal when primary amines, sulfhydryls, carboxyls and carbohydrates are not available for labeling. These reagents rely on aryl azides, which become activated by ultraviolet light (UV; >350 nm), which then react at C-H and N-H bonds. Because these types of bonds occur independent of the type of amino acid, this type of biotinylation is termed "non-specific".

Photoactivatable biotinylation reagents can also be used to activate biotinylation at specific times in an experiment or during certain reaction conditions, by simply exposing the reaction to UV light at the specific time or condition.

Purpose

Purification

The biotin tag can be used in affinity chromatography together with a column that has avidin (also streptavidin or Neutravidin) bound to it, which is the natural ligand for biotin. However, harsh conditions (e.g., 6M GuHCl at pH 1.5) are needed to break the avidin/streptavidin - biotin interaction, which will most likely denature the protein carrying the biotin tag. If isolation of the tagged protein is needed, it is better to tag the protein with iminobiotin. This biotin analogue gives strong binding to avidin/streptavidin at alkaline pH, but the affinity is reduced upon lowering the pH. Therefore, an iminobiotin-tagged functional protein can be released from an avidin/streptavidin column by decreasing the pH (to around pH 4).[7][8]

Detection

This tag can also be used in detection of the protein via anti-biotin antibodies or avidin/streptavidin-tagged detection strategies such as enzyme reporters (e.g., horseradish peroxidase, alkaline phosphatase) or fluorescent probes. This can be useful in localization by fluorescent or electron microscopy,[9] ELISA assays, ELISPOT assays, western blots and other immunoanalytical methods. Detection with monovalent streptavidin can avoid clustering or aggregation of the biotinylated target.[10]

Other uses

The non-covalent bond formed between biotin and avidin or streptavidin has a binding affinity that is higher than most antigen and antibody bonds and approaches the strength of a covalent bond. This very tight binding makes labeling proteins with biotin a useful tool for applications such as affinity chromatography using immobilized avidin or streptavidin to separate the biotinylated protein from a mixture of other proteins and biochemicals. Biotinylated protein such as biotinylated bovine serum albumin (BSA) is used in solid-phase assays as a coating on the well surface in multiwell assay plates. Biotinylation of red blood cells has been used as a means of determining total blood volume without the use of radiolabels such as chromium 51, allowing volume determinations in low birth weight infants and pregnant women who could not otherwise be exposed to the required doses of radioactivity. Furthermore, biotinylation of MHC molecules to create MHC multimers has become a useful tool for identifying and isolating antigen-specific T-cell populations. More recently, in vivo protein biotinylation was developed to study protein-protein interactions and proximity in living cells[11][12][13]

Determining the extent of biotinylation

Reaction conditions for biotinylation are chosen so that the target molecule (e.g., an antibody) is labeled with sufficient biotin molecules to purify or detect the molecule, but not so much that the biotin interferes with the function of the molecule.

HABA assay

The HABA (2-(4-hydroxyazobenzene) benzoic acid) assay can be used to determine the extent of biotinylation. HABA dye is bound to avidin or streptavidin and yields a characteristic absorbance. When biotinylated proteins or other molecules are introduced, the biotin displaces the dye, resulting in a change in absorbance at 500 nm. This change is directly proportional to the level of biotin in the sample. The disadvantage of the HABA assay is that it uses large amounts of sample.

Streptavidin gel-shift

Extent of biotinylation can also be measured by streptavidin gel-shift, since streptavidin remains bound to biotin during agarose gel electrophoresis or polyacrylamide gel electrophoresis. The proportion of target biotinylated can be measured via the change in band intensity of the target with or without excess streptavidin, seen quickly and quantitatively for biotinylated proteins by Coomassie Brilliant Blue staining.[14]

Further reading

  • Hermanson, G.T. Bioconjugate Techniques. Academic Press ISBN 0-12-342336-8
  • Overview of Biotinylation - Includes additional information and figures of reactive groups, biotin and linker regions.
  • Gao, Wenqing; Wu, Zengru; Bohl, Casey E.; Yang, Jun; Miller, Duane D.; Dalton, James T. (2005). "Characterization of the in Vitro Metabolism of Selective Androgen Receptor Modulator Using Human, Rat, and Dog Liver Enzyme Preparations". Drug Metabolism and Disposition 34 (2): 243–53.  

References

  1. ^ Barat, Bhaswati; Wu, Anna M. (2007). "Metabolic biotinylation of recombinant antibody by biotin ligase retained in the endoplasmic reticulum". Biomolecular Engineering 24 (3): 283–91.  
  2. ^ a b Beckett, Dorothy; Kovaleva, Elena; Schatz, Peter J. (2008). "A minimal peptide substrate in biotin holoenzyme synthetase-catalyzed biotinylation". Protein Science 8 (4): 921–9.  
  3. ^ De Boer, E.; Rodriguez, P; Bonte, E; Krijgsveld, J; Katsantoni, E; Heck, A; Grosveld, F; Strouboulis, J (2003). "Efficient biotinylation and single-step purification of tagged transcription factors in mammalian cells and transgenic mice". Proceedings of the National Academy of Sciences 100 (13): 7480–5.  
  4. ^ Viens, Antoine; Mechold, Undine; Lehrmann, Heike; Harel-Bellan, Annick; Ogryzko, Vasily (2004). "Use of protein biotinylation in vivo for chromatin immunoprecipitation". Analytical Biochemistry 325 (1): 68–76.  
  5. ^ Howarth, Mark; Takao, Keizo; Hayashi, Yasunori; Ting, Alice Y. (2005). "Targeting quantum dots to surface proteins in living cells with biotin ligase". Proceedings of the National Academy of Sciences 102 (21): 7583–8.  
  6. ^ Pon, Richard T. (1991). "A long chain biotin phosphoramidite reagent for the automated synthesis of 5′-biotinylated oligonucleotides". Tetrahedron Letters 32 (14): 1715–8.  
  7. ^ Hofmann, Klaus; Wood, Sara W.; Brinton, Charles C.; Montibeller, Judith A.; Finn, Frances M. (1980). "Iminobiotin Affinity Columns and Their Application to Retrieval of Streptavidin". Proceedings of the National Academy of Sciences 77 (8): 4666–8.  
  8. ^ Sugawara, Kazuharu; Kamiya, Naoto; Hirabayashi, George; Kuramitz, Hideki (2005). "Voltammetric Homogeneous Binding Assay of Biotin without a Separation Step Using Iminobiotin Labeled with an Electroactive Compound". Analytical Sciences 21 (8): 897–900.  
  9. ^ Viens, A.; Harper, F.; Pichard, E.; Comisso, M.; Pierron, G.; Ogryzko, V. (2008). "Use of Protein Biotinylation in Vivo for Immunoelectron Microscopic Localization of a Specific Protein Isoform". Journal of Histochemistry and Cytochemistry 56 (10): 911–9.  
  10. ^ Howarth, Mark; Chinnapen, Daniel J-F; Gerrow, Kimberly; Dorrestein, Pieter C; Grandy, Melanie R; Kelleher, Neil L; El-Husseini, Alaa; Ting, Alice Y (2006). "A monovalent streptavidin with a single femtomolar biotin binding site". Nature Methods 3 (4): 267–73.  
  11. ^ FernáNdez-SuáRez, Marta; Chen, T. Scott; Ting, Alice Y. (2008). "Protein−Protein Interaction Detection in Vitro and in Cells by Proximity Biotinylation". Journal of the American Chemical Society 130 (29): 9251–3.  
  12. ^ Kulyyassov, Arman; Shoaib, Muhammad; Pichugin, Andrei; Kannouche, Patricia; Ramanculov, Erlan; Lipinski, Marc; Ogryzko, Vasily (2011). "PUB-MS: A Mass Spectrometry-based Method to Monitor Protein–Protein Proximityin vivo". Journal of Proteome Research 10 (10): 4416–27.  
  13. ^ Shoaib, M.; Kulyyassov, A.; Robin, C.; Winczura, K.; Tarlykov, P.; Despas, E.; Kannouche, P.; Ramanculov, E.; Lipinski, M.; Ogryzko, V. (2012). "PUB-NChIP--"in vivo biotinylation" approach to study chromatin in proximity to a protein of interest". Genome Research 23 (2): 331–40.  
  14. ^ Jain, J.; Veggiani, G.; Howarth, M. (2013). "Cholesterol Loading and Ultrastable Protein Interactions Determine the Level of Tumor Marker Required for Optimal Isolation of Cancer Cells". Cancer Research 73 (7): 2310–21.  
This article was sourced from Creative Commons Attribution-ShareAlike License; additional terms may apply. World Heritage Encyclopedia content is assembled from numerous content providers, Open Access Publishing, and in compliance with The Fair Access to Science and Technology Research Act (FASTR), Wikimedia Foundation, Inc., Public Library of Science, The Encyclopedia of Life, Open Book Publishers (OBP), PubMed, U.S. National Library of Medicine, National Center for Biotechnology Information, U.S. National Library of Medicine, National Institutes of Health (NIH), U.S. Department of Health & Human Services, and USA.gov, which sources content from all federal, state, local, tribal, and territorial government publication portals (.gov, .mil, .edu). Funding for USA.gov and content contributors is made possible from the U.S. Congress, E-Government Act of 2002.
 
Crowd sourced content that is contributed to World Heritage Encyclopedia is peer reviewed and edited by our editorial staff to ensure quality scholarly research articles.
 
By using this site, you agree to the Terms of Use and Privacy Policy. World Heritage Encyclopedia™ is a registered trademark of the World Public Library Association, a non-profit organization.
 


Copyright © World Library Foundation. All rights reserved. eBooks from Project Gutenberg are sponsored by the World Library Foundation,
a 501c(4) Member's Support Non-Profit Organization, and is NOT affiliated with any governmental agency or department.