Metabolic biotinylation of recombinant antibody by biotin ligase retained in the endoplasmic reticulum

Due to its strength and specificity, the interaction between avidin and biotin has been used in a variety of scientific and medical applications ranging from immunohistochemistry to drug targeting. The present study describes two methods for biotinylation of proteins secreted from eukaryotic cells using the Escherichia coli biotin protein ligase. In one system the biotin ligase was co-secreted from the cells along with substrate protein enabling extracellular biotinylation of the tagged protein. In the other system, biotin ligase was engineered to be retained in the endoplasmic reticulum (ER) and metabolically biotinylates the secretory protein as it passes through the ER. An engineered antibody fragment, a diabody with specificity for carcinoembryonic antigen (CEA) was fused to the biotin acceptor domain (123 amino acid) of Propionibacterium shermanii. Coexpression of the fusion protein with ER retained biotin ligase showed higher biotinylation efficiency than biotinylation by co-secreted ligase. Biotinylation of the anti-CEA diabody tagged with a short (15 amino acid, Biotin Avitag) biotin acceptor peptide was also successful. Utilization of ER retained biotin ligase for biotinylation of protein is an attractive alternative for efficiently producing uniformly biotinylated recombinant proteins for a variety of avidin-biotin technologies.     

In Vivo Biotinylation of Bacterial Magnetic Particles by a Truncated Form of Escherichia coli Biotin Ligase and Biotin Acceptor Peptide

Escherichia coli biotin ligase can attach biotin molecules to a lysine residue of biotin acceptor peptide (BAP), and biotinylation of particular BAP-fused proteins in cells was carried out by coexpression of E. coli biotin ligase (in vivo biotinylation). This in vivo biotinylation technology has been applied for protein purification, analysis of protein localization, and protein-protein interaction in eukaryotic cells, while such studies have not been reported in bacterial cells. In this study, in vivo biotinylation of bacterial magnetic particles (BacMPs) synthesized by Magnetospirillum magneticum AMB-1 was attempted by heterologous expression of E. coli biotin ligase. To biotinylate BacMPs in vivo, BAP was fused to a BacMP surface protein, Mms13, and E. coli biotin ligase was simultaneously expressed in the truncated form lacking the DNA-binding domain. This truncation-based approach permitted the growth of AMB-1 transformants when biotin ligase was heterologously expressed. In vivo biotinylation of BAP on BacMPs was confirmed using an alkaline phosphatase-conjugated antibiotin antibody. The biotinylated BAP-displaying BacMPs were then exposed to streptavidin by simple mixing. The streptavidin-binding capacity of BacMPs biotinylated in vivo was 35-fold greater than that of BacMPs biotinylated in vitro, where BAP-displaying BacMPs purified from bacterial cells were biotinylated by being mixed with E. coli biotin ligase. This study describes not only a simple method to produce biotinylated nanomagnetic particles but also a possible expansion of in vivo biotinylation technology for bacterial investigation.Biotin/streptavidin binding is the strongest noncovalent interaction known in nature (K_d [dissociation constant], ∼10⁻¹⁵ M) (10), and this tight binding is one of the most general tools for biological research and has been widely used for biomolecular detection (11, 12), immobilization (14, 19), and recovery (15). Therefore, it is of great significance to biotinylate biomolecules, in particular, proteins without functional inhibition. For this purpose, the method for site-selective biotinylation of proteins had been developed using biotin ligase. Biotin ligase catalyzes the posttranslational biotinylation of biotin enzymes, such as acetyl coenzyme A (acetyl-CoA) carboxylase, and introduces biotin into a specific lysine residue of a biotin carboxyl carrier protein (BCCP), a subunit of biotin enzymes (13). In early studies, BCCP (∼100 amino acid residues) had been fused with the proteins of interest for biotinylation by biotin ligase (7); however, there was a concern that fused BCCP might disrupt the function of target proteins. Recently, biotin acceptor peptides (BAPs) had replaced BCCP due to the advantage of small size. BAPs, with 15 to 23 amino acid residues, were screened from a peptide library as peptide tags biotinylated by Escherichia coli biotin ligase (4, 25). BAP-fused proteins can be biotinylated outside the cells by adding biotin and purified E. coli biotin ligase with Mg²⁺ and ATP (in vitro biotinylation). Furthermore, it is also possible to biotinylate BAP-fused proteins inside the cells with coexpression of E. coli biotin ligase (in vivo biotinylation) because BAP is specifically recognized only by E. coli biotin ligase. This in vivo biotinylation technology has been applied in eukaryotic cells to purify the proteins by using streptavidin-immobilized resin (8, 24, 28), because biotin/streptavidin interaction permits stringent washing to eliminate the nonspecific binding. Specific biotinylation can be applied also for protein localization analysis. Using fluorophore- or gold nanoparticle-labeled streptavidin, biotinylated proteins were clearly observed in a previous study (27). Recently, a novel technique to detect protein-protein interaction by fusing BAP and biotin ligase was developed by Ting''s group. BAP and biotin ligase were fused to different two proteins, and then the interaction of these proteins was successfully evaluated via biotinylation of BAP (9). In vivo biotinylation technology using heterologously expressed E. coli biotin ligase should be equally useful for prokaryotes; however, such studies have not been reported for bacterial cells.Magnetospirillum magneticum AMB-1, a magnetotactic bacterium, synthesizes intracellular nanosized bacterial magnetic particles (BacMPs) of 50 to 100 nm; these are surrounded by a lipid bilayer membrane, possess a single magnetic domain of magnetite, and exhibit strong ferrimagnetism (18). Furthermore, functional proteins have been displayed on BacMP surfaces through gene fusion techniques (21, 30, 31). BacMP membrane proteins, including Mms13, were used as anchor proteins; this approach permits functional proteins to be localized efficiently and oriented appropriately on BacMPs (31). We recently reported a novel method for the simple production of biotin-labeled magnetic particles through protein display techniques, where introduction of the biotin moiety onto BacMPs was carried out by the endogenous biotin ligase (17). For the biotinylation of BacMPs, we screened the gene encoding BCCP in the AMB-1 genome and displayed it on the surface of BacMPs using an anchor protein, Mms13. BCCP-displaying BacMPs were biotinylated by endogenous AMB-1 biotin ligase in the cells with high efficiency. This in vivo modification approach could be applied for construction of BacMP-quantum dot nanocomposites toward multicolor labeling of cancer cells, where BCCP and antibody carrier protein (protein G) were simultaneously displayed in tandem (16). However, the size of BCCP, with 149 amino acid residues and a mass of 15.6 kDa, makes it rather large for use as a labeling tag. Although it would be preferable to use a smaller peptide, BAP, for the tag to minimize effects on the flanking proteins for future applications, BAP was not recognized and biotinylated by endogenous AMB-1 biotin ligase (17).In this study, in vivo biotinylation of BacMPs was attempted by heterologous expression of E. coli biotin ligase and Mms13-BAP fusion protein in AMB-1 cells. First, the method for effective expression of E. coli biotin ligase in bacterial cells was optimized. Then site-selective biotinylation of BAP on BacMPs was confirmed. Finally, the obvious advantage of in vivo biotinylation of BAP-displaying BacMPs compared with the in vitro biotinylation method was demonstrated.     

Efficient and versatile one-step affinity purification of in vivo biotinylated proteins: expression, characterization and structure analysis of recombinant human glutamate carboxypeptidase II

Affinity purification is a useful approach for purification of recombinant proteins. Eukaryotic expression systems have become more frequently used at the expense of prokaryotic systems since they afford recombinant eukaryotic proteins with post-translational modifications similar or identical to the native ones. Here, we present a one-step affinity purification set-up suitable for the purification of secreted proteins. The set-up is based on the interaction between biotin and mutated streptavidin. Drosophila Schneider 2 cells are chosen as the expression host, and a biotin acceptor peptide is used as an affinity tag. This tag is biotinylated by Escherichia coli biotin-protein ligase in vivo. We determined that localization of the ligase within the ER led to the most effective in vivo biotinylation of the secreted proteins. We optimized a protocol for large-scale expression and purification of AviTEV-tagged recombinant human glutamate carboxypeptidase II (Avi-GCPII) with milligram yields per liter of culture. We also determined the 3D structure of Avi-GCPII by X-ray crystallography and compared the enzymatic characteristics of the protein to those of its non-tagged variant. These experiments confirmed that AviTEV tag does not affect the biophysical properties of its fused partner. Purification approach, developed here, provides not only a sufficient amount of highly homogenous protein but also specifically and effectively biotinylates a target protein and thus enables its subsequent visualization or immobilization.     

Prokaryotic BirA ligase biotinylates K4, K9, K18 and K23 in histone H3

BirA ligase is a prokaryotic ortholog of holocarboxylase synthetase (HCS) that can biotinylate proteins. This study tested the hypothesis that BirA ligase catalyzes the biotinylation of eukaryotic histones. If so, this would mean that recombinant BirA ligase is a useful surrogate for HCS in studies of histone biotinylation. The biological activity of recombinant BirA ligase was confirmed by enzymatic biotinylation of p67. In particular, it was found that BirA ligase biotinylated both calf thymus histone H1 and human bulk histone extracts. Incubation of recombinant BirA ligase with H3-based synthetic peptides showed that lysines 4, 9, 18, and 23 in histone H3 are the targets for the biotinylation by BirA ligase. Modification of the peptides (e.g., serine phosphorylation) affected the subsequent biotinylation by BirA ligase, suggesting crosstalk between modifications. In conclusion, this study suggests that prokaryotic BirA ligase is a promiscuous enzyme and biotinylates eukaryotic histones. Moreover the biotinylation of histones by BirA ligase is consistent with the proposed role of human HCS in chromatin.     

Codon optimization of the BirA enzyme gene leads to higher expression and an improved efficiency of biotinylation of target proteins in mammalian cells

Biotinylation of proteins is an attractive alternative to 'epitope-tagging', due to the strong biotin-(strept)avidin interaction and to the wide commercial availability of reagents for detection and purification of biotinylated macromolecules. Enzymatic biotinylation of target proteins in vivo using short biotin acceptor domains was described previously. Their use in mammalian cell requires expression of the bacterial biotinylation enzyme BirA. Here we describe the construction of a humanized version of BirA, with most of the rare codons replaced by codons that are more frequently used in human cells. The humanized BirA is expressed better in mammalian cells, resulting in improved efficiency of biotinylation in vivo. We anticipate that the humanized BirA gene will find use in many applications that involve in vivo biotinylation.     

In vivo biotinylated recombinant influenza A virus hemagglutinin for use in subtype-specific serodiagnostic assays

There is an urgent need for robust subtype-specific serological tests to diagnose influenza A virus infections in poultry and mammals, including humans. Such assays require reliable subtype-specific sources of soluble and authentically folded seroreactive hemagglutinin (HA), one of the integral membrane proteins that determine the serological subtype of influenza viruses. To this purpose, a bigenic pFastBacDual baculovirus transfer vector allowing efficient in vivo biotinylation of soluble HA homo-oligomers expressed via the secretory pathway was developed. An Avi-Tag allowed site-specific biotinylation by a coexpressed genetically modified BirA biotin ligase retained in the endoplasmic reticulum (ER). Highly seroreactive mono-biotinylated HA of recent H5 and H7 influenza A subtypes was secreted from recombinant baculovirus infected High-Five insect cells at levels sufficient to directly load streptavidin-coated enzyme-linked immunosorbent assay (ELISA) matrices, thereby avoiding any purification steps. The recombinant antigens retained authentic antigenicity, including conformation-dependent epitopes involved in hemagglutination inhibition as detected by monoclonal antibodies. This is the first bigenic in vivo biotinylation system established for use in insect cells with secretable recombinant membrane proteins biotinylated by an ER-retained variant of BirA biotin ligase. The proposed technique is expected to significantly increase flexibility in the design of subtype-specific assays, thereby expanding the power of influenza A virus serodiagnosis.     

Regulated expression of active biotinylated G-protein coupled receptors in mammalian cells

We have developed a mammalian expression system suitable for the production of enzymatically biotinylated integral membrane proteins. The key feature of this system is the doxycycline (dox)-regulated co-expression of a secreted variant of Escherichia coli biotin ligase (BirA) and a target protein with a 13-residue biotin acceptor peptide (BioTag) appended to its extracellular domain. Here we describe the expression and functional analysis of three G-protein coupled receptors (GPCRs): protease-activated receptors (PARs) 1 and 2, and the platelet ADP receptor, P2Y(12). Clonal Chinese hamster ovary (CHO) Tet-On cell lines that express biotinylated GPCRs were rapidly isolated by fluorescence-activated cell sorting following streptavidin-FITC staining, thereby circumventing the need for manual colony picking. Analysis by Western blotting with streptavidin-HRP following endoglycosidase treatment revealed that all three GPCRs undergo N-linked glycosylation. The expression of biotinylated GPCRs on the cell surface was regulated by the concentration of dox in the medium, reaching a maximum at approximately 1 microg/mL dox. Similarly, the extent of GPCR biotinylation was dependent on biotin concentration, with maximum and complete biotinylation achieved upon supplementation with 50 microM biotin. Biotinylated PAR1 and PAR2 were readily and specifically cleaved on the surface of intact cells by their cognate proteases, and were capable of transducing extracellular stimuli, resulting in the downstream phosphorylation of extracellular signal-regulated kinase (ERK) 1/2. Notably, P2Y(12) mediated agonist-induced ERK phosphorylation only when it was expressed at low levels on the cell surface, highlighting the utility of regulated expression for the production of functionally active GPCRs in mammalian cells.     

Development of an enzymatic method for site-specific incorporation of desthiobiotin to recombinant proteins in vitro

To extend the (strept)avidin-biotin technology for affinity purification of proteins, development of reusable biochips and immobilized enzyme bioreactors, selective immobilization of a protein of interest from a crude sample to a protein array without protein purification and many other possible applications, the (strept)avidin-biotin interaction is better when reversible. A gentle enzymatic method to introduce a biotin analog, desthiobiotin, in a site-specific manner to recombinant proteins carrying a biotinylation tag has been developed. The optimal condition for efficient in vitro desthiobiotinylation catalyzed by Escherichia coli biotin ligase (BirA) in 1-4h has been established by systematically varying the substrate concentrations, reaction time, and pH. Real desthiobiotinylation in the absence of any significant biotinylation using this enzymatic method was confirmed by mass spectrometric analysis of the desthiobiotinylated tag. This approach was applied to affinity purify desthiobiotinylated staphylokinase secreted by recombinant Bacillus subtilis to high purity and with good recovery using streptavidin-agarose. The matrix can be regenerated for reuse. This study represents the first successful application of E. coli BirA to incorporate biotin analog to recombinant proteins in a site-specific manner.     

Targeted and proximity-dependent promiscuous protein biotinylation by a mutant Escherichia coli biotin protein ligase

A method for general protein biotinylation by enzymatic means has been developed. A mutant form (R118G) of the biotin protein ligase (BirA) of Escherichia coli is used and biotinylation is thought to proceed by chemical acylation of protein lysine side chains by biotinoyl-5'-AMP released from the mutant protein. Bovine serum albumin, chloramphenicol acetyltransferase, immunoglobulin chains and RNAse A as well as a large number of E. coli proteins have been biotinylated. The biotinylation reaction is proximity dependent in that the extent of biotinylation is much greater when the ligase is coupled to the acceptor protein than when the acceptor is free in solution. This is presumably due to rapid hydrolysis of the acylation agent, biotinoyl-5'-AMP. Therefore, when the mutant ligase is attached to one partner involved in a protein-protein interaction, it can be used to specifically tag the other partner with biotin, thereby permitting facile detection and recovery of the proteins by existing avidin/streptavidin technology.     

Expression and purification of E. coli BirA biotin ligase for in vitro biotinylation

The extremely tight binding between biotin and avidin or streptavidin makes labeling proteins with biotin a useful tool for many applications. BirA is the Escherichia coli biotin ligase that site-specifically biotinylates a lysine side chain within a 15-amino acid acceptor peptide (also known as Avi-tag). As a complementary approach to in vivo biotinylation of Avi-tag-bearing proteins, we developed a protocol for producing recombinant BirA ligase for in vitro biotinylation. The target protein was expressed as both thioredoxin and MBP fusions, and was released from the corresponding fusion by TEV protease. The liberated ligase was separated from its carrier using HisTrap HP column. We obtained 24.7 and 27.6 mg BirA ligase per liter of culture from thioredoxin and MBP fusion constructs, respectively. The recombinant enzyme was shown to be highly active in catalyzing in vitro biotinylation. The described protocol provides an effective means for making BirA ligase that can be used for biotinylation of different Avi-tag-bearing substrates.     

An efficient vector system to modify cells genetically

The transfer of foreign genes into mammalian cells has been essential for understanding the functions of genes and mechanisms of genetic diseases, for the production of coding proteins and for gene therapy applications. Currently, the identification and selection of cells that have received transferred genetic material can be accomplished by methods, including drug selection, reporter enzyme detection and GFP imaging. These methods may confer antibiotic resistance, or be disruptive, or require special equipment. In this study, we labeled genetically modified cells with a cell surface biotinylation tag by co-transfecting cells with BirA, a biotin ligase. The modified cells can be quickly isolated for downstream applications using a simple streptavidin bead method. This system can also be used to screen cells expressing two sets of genes from separate vectors.     

Design, production, and characterization of an engineered biotin ligase (BirA) and its application for affinity purification of staphylokinase produced from Bacillus subtilis via secretion

A major attraction in using Bacillus subtilis as an expression host for heterologous protein production is its ability to secrete extracellular proteins into the culture medium. To take full advantage of this system, an efficient method for recovering the target protein is crucial. For secretory proteins which cannot be purified by a simple scheme, in vitro biotinylation using biotin ligase (BirA) offers an effective alternative for their purification. The availability of large amounts of quality BirA can be critical for in vitro biotinylation. We report here the engineering and production of an Escherichia coli BirA and its application in the purification of staphylokinase, a fibrin-specific plasminogen activator, from the culture supernatant of Bacillus subtilis via in vitro biotinylation. BirA was tagged with both a chitin-binding domain and a hexahistidine tail to facilitate both its purification and its removal from the biotinylated sample. We show in this paper how, in a unique way, we solved the problem of protein aggregation in the E. coli BirA production system to achieve a yield of soluble functional BirA hitherto unreported in the literature. Application of this novel BirA to protein purification via in vitro biotinylation in general will also be discussed. Biotinylated staphylokinase produced in the study not only can act as an intermediate for easy purification, it can also serve as an important element in the creation of a blood clot targeting and dissolving agent.     

Identification of the tRNA-binding protein Arc1p as a novel target of in vivo biotinylation in Saccharomyces cerevisiae

Biotin is an essential cofactor of cell metabolism serving as a protein-bound coenzyme in ATP-dependent carboxylation, in transcarboxylation, and certain decarboxylation reactions. The involvement of biotinylated proteins in other cellular functions has been suggested occasionally, but available data on this are limited. In the present study, a Saccharomyces cerevisiae protein was identified that reacts with streptavidin on Western blots and is not identical to one of the known biotinylated yeast proteins. After affinity purification on monomeric avidin, the biotinylated protein was identified as Arc1p. Using 14C-labeled biotin, the cofactor was shown to be incorporated into Arc1p by covalent and alkali-stable linkage. Similar to the known carboxylases, Arc1p biotinylation is mediated by the yeast biotin:protein ligase, Bpl1p. Mutational studies revealed that biotinylation occurs at lysine 86 within the N-terminal domain of Arc1p. In contrast to the known carboxylases, however, in vitro biotinylation of Arc1p is incomplete and increases with BPL1 overexpression. In accordance to this fact, Arc1p lacks the canonical consensus sequence of known biotin binding domains, and the bacterial biotin:protein ligase, BirA, is unable to use Arc1p as a substrate. Arc1p was shown previously to organize the association of MetRS and GluRS tRNA synthetases with their cognate tRNAs thereby increasing the substrate affinity and catalytic efficiency of these enzymes. Remarkably, not only biotinylated but also the biotin-free Arc1p obtained by replacement of lysine 86 with arginine were capable of restoring Arc1p function in both arc1Delta and arc1Deltalos1Delta mutants, indicating that biotinylation of Arc1p is not essential for activity.     

Imaging proteins in live mammalian cells with biotin ligase and monovalent streptavidin

This protocol describes a simple and efficient way to label specific cell surface proteins with biophysical probes on mammalian cells. Cell surface proteins tagged with a 15-amino acid peptide are biotinylated by Escherichia coli biotin ligase (BirA), whereas endogenous proteins are not modified. The biotin group then allows sensitive and stable binding by streptavidin conjugates. This protocol describes the optimal use of BirA and streptavidin for site-specific labeling and also how to produce BirA and monovalent streptavidin. Streptavidin is tetravalent and the cross-linking of biotinylated targets disrupts many of streptavidin's applications. Monovalent streptavidin has only a single functional biotin-binding site, but retains the femtomolar affinity, low off-rate and high thermostability of wild-type streptavidin. Site-specific biotinylation and streptavidin staining take only a few minutes, while expression of BirA takes 4 d and expression of monovalent streptavidin takes 8 d.     

A promiscuous biotin ligase fusion protein identifies proximal and interacting proteins in mammalian cells

We have developed a new technique for proximity-dependent labeling of proteins in eukaryotic cells. Named BioID for proximity-dependent biotin identification, this approach is based on fusion of a promiscuous Escherichia coli biotin protein ligase to a targeting protein. BioID features proximity-dependent biotinylation of proteins that are near-neighbors of the fusion protein. Biotinylated proteins may be isolated by affinity capture and identified by mass spectrometry. We apply BioID to lamin-A (LaA), a well-characterized intermediate filament protein that is a constituent of the nuclear lamina, an important structural element of the nuclear envelope (NE). We identify multiple proteins that associate with and/or are proximate to LaA in vivo. The most abundant of these include known interactors of LaA that are localized to the NE, as well as a new NE-associated protein named SLAP75. Our results suggest BioID is a useful and generally applicable method to screen for both interacting and neighboring proteins in their native cellular environment.     

Molecular methods to study protein trafficking between organs

Interorgan communication networks are key regulators of organismal homeostasis, and their dysregulation is associated with a variety of pathologies. While mass spectrometry proteomics identifies circulating proteins and can correlate their abundance with disease phenotypes, the tissues of origin and destinations of these secreted proteins remain largely unknown. In vitro approaches to study protein secretion are valuable, however, they may not mimic the complexity of in vivo environments. More recently, the development of engineered promiscuous BirA* biotin ligase derivatives has enabled tissue-specific tagging of cellular secreted proteomes in vivo. The use of biotin as a molecular tag provides information on the tissue of origin and destination, and enables the enrichment of low-abundance hormone proteins. Therefore, promiscuous protein biotinylation is a valuable tool to study protein secretion in vivo.     

Biotin-ubiquitin tagging of mammalian proteins in Escherichia coli

Ubiquitin has been used in protein expression for enhancing yields and biological activities of recombinant proteins. Biotin binds tightly and specifically to avidin and has been widely utilized as a tag for protein purification and monitoring. Here, we report a versatile system that takes the advantages of both biotin and ubiquitin for protein expression, purification, and monitoring. The tripartite system contained coding sequences for a leader biotinylation peptide, ubiquitin, and biotin holoenzyme synthetase in two reading frames under the control of T7 promoter. The expression and purification of several large mammalian enzymes as biotin-ubiquitin fusions were accomplished including human ubiquitin activating enzyme, SUMO activating enzymes, and aspartyl-tRNA synthetase. Expressed proteins were purified by one-step affinity column chromatography on monomeric avidin columns and purified proteins exhibited active function. Additionally, the ubiquitin protein hydrolase UBP41, expressed and purified as biotin-UBP41, efficiently and specifically cleaved off the biotin-ubiquitin tag from biotin-ubiquitin fusions to produce unmodified proteins. The present expression system should be useful for the expression, purification, and functional characterization of mammalian proteins and the construction of protein microarrays.     

Redirecting lipoic acid ligase for cell surface protein labeling with small-molecule probes

Live cell imaging is a powerful method to study protein dynamics at the cell surface, but conventional imaging probes are bulky, or interfere with protein function, or dissociate from proteins after internalization. Here, we report technology for covalent, specific tagging of cellular proteins with chemical probes. Through rational design, we redirected a microbial lipoic acid ligase (LplA) to specifically attach an alkyl azide onto an engineered LplA acceptor peptide (LAP). The alkyl azide was then selectively derivatized with cyclo-octyne conjugates to various probes. We labeled LAP fusion proteins expressed in living mammalian cells with Cy3, Alexa Fluor 568 and biotin. We also combined LplA labeling with our previous biotin ligase labeling, to simultaneously image the dynamics of two different receptors, coexpressed in the same cell. Our methodology should provide general access to biochemical and imaging studies of cell surface proteins, using small fluorophores introduced via a short peptide tag.