Promiscuous protein biotinylation by Escherichia coli biotin protein ligase

doi:10.1110/ps.04911804

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Promiscuous protein biotinylation by Escherichia coli biotin protein ligase

Eunjoo Choi-Rhee¹, Howard Schulman³ and John E. Cronan¹^,2

¹ Departments of Microbiology and ² Biochemistry, University of Illinois, Urbana, Illinois 61801, USA
³ SurroMed, Inc., Menlo Park, California 94025, USA

Reprint requests to: John E. Cronan, Departments of Microbiology and Biochemistry, University of Illinois, Urbana, IL 61801, USA; e-mail: j-cronan{at}life.uiuc.edu; fax: (217) 244-6697.

(RECEIVED June 7, 2004; FINAL REVISION July 15, 2004; ACCEPTED July 15, 2004)

Abstract

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Biotin protein ligases (BPLs) are enzymes of extraordinary specificity.BirA, the BPL of Escherichia coli biotinylates only a singlecellular protein. We report a mutant BirA that attaches biotinto a large number of cellular proteins in vivo and to bovineserum albumin, chloramphenicol acetyltransferase, immunoglobinheavy and light chains, and RNAse A in vitro. The mutant BirAalso self biotinylates in vivo and in vitro. The wild type BirAprotein is much less active in these reactions. The biotinylationreaction is proximity-dependent in that a greater extent ofbiotinylation was seen when the mutant ligase was coupled tothe acceptor proteins than when the acceptors were free in solution.This approach may permit facile detection and recovery of interactingproteins by existing avidin/streptavidin technology.

Keywords: biotin protein ligase; protein modification; biotinylation; acyl adenylate; BirA

Introduction

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Biotinylation of proteins has routinely been done by chemicalmeans, usually by modification of protein amino groups withbiotin-N-hydroxysuccinimide or similar acylating agents. Incontrast, enzymatic biotinylation has been limited to the fewproteins that normally carry this modification, which are largelybiotin-dependent carboxylases and decarboxylases of centralmetabolism (Chapman-Smith and Cronan Jr. 1999). We supposedthat if enzymatic biotinylation could be made less specific,it might provide a means to detect weak (i.e., having dissociationconstants >10^–7 M) protein–protein interactions.In this scenario the biotinylating enzyme physically coupledto one of the interacting proteins (the target protein) wouldbe used to biotinylate and thereby tag proteins that interactwith the target protein. The biotinylation reaction should tagonly those protein molecules that are close in space to thetarget protein. That is, unlike chemical acylation, enzymaticbiotinylation should be proximity-dependent. The specific andextremely tight binding of biotin (K_D 10^–13 to 10^–15M) to streptavidin and avidin would then allow very sensitivedetection of biotinylated proteins by a wide variety of robustprotocols and low affinity forms of streptavidin and avidinallow efficient purification of biotinylated proteins undermild conditions. However, the biotin protein ligases (BPLs)catalyzing protein biotinylation have exceptional specificitiesfor their protein substrates and thus are not general proteinmodification enzymes. For example, in vivo, BirA, the BPL ofEscherichia coli, biotinylates only a single protein, the BCCP(AccB) subunit of acetyl-CoA carboxylase and other organismscontain less than five biotinylated protein species, indicatingthese BPLs are similarly specific (McAllister and Coon 1966;Samols et al. 1988; Chapman-Smith and Cronan Jr. 1999). Therefore,in order to use a BPL as a general biotinylating enzyme, thisextraordinary specificity must somehow be overcome. A possibleroute to this end is based upon the mechanism of the BPL reaction,which proceeds in two steps:

Biotin + ATP ${rightleftharpoons}$ Bio-5'-AMP + PPi
Bio-5'-AMP + apo-Protein $->$ Biotinoyl-Protein+ AMP

In the first partial reaction, BPLs catalyze the synthesis ofbiotinoyl-AMP (bio-5'-AMP, which is also called biotinyl-adenylate)from ATP and biotin (McAllister and Coon 1966; Chapman-Smith and Cronan Jr. 1999).The enzyme then sequesters bio-5'-AMPin the active site until the second partial reaction proceeds.In the second partial reaction, the nucleophilic ${varepsilon}$ -amino groupof the target lysine residue of a biotin-accepting domain attacksthe mixed anhydride of the bio-5'-AMP bound within the BPL activesite to form an amide bond between biotin and the lysine sidechain that remains intact for the life of the protein (McAllister and Coon 1966;Chapman-Smith and Cronan Jr. 1999).

A possible means to convert a BPL to a promiscuous protein biotinylationenzyme would be to alter the protein such that the mutant enzymereleases bio-5'-AMP from the active site. Bio-5'-AMP is a mixedanhydride and therefore should act as a nonspecific chemicalprotein biotinylation reagent. A precedent for this scenariois the nonenzymatic acylation with serine of noncogate acceptorproteins by seryl-AMP released from an adenylation domain derivedfrom EntF (Ehmann et al. 2000). Moreover, the instability ofacyl-adenylates such as bio-5'-AMP should result in proximity-dependentbiotinylation. This is because any acyl-adenylate moleculesthat diffuse far from the enzyme should be inefficient proteinacylation reagents due to their low concentration and the highrate of acyl-adenylate hydrolysis.

The best studied BPL is E. coli BirA, a monomeric protein of35.3 kDa. BirA is a multifunctional protein that catalyzes biotinylationof apo-BCCP and also acts as the transcriptional repressor thatregulates biotin biosynthesis (Cronan Jr. 1989; Beckett and Matthews 1997).The X-ray crystallographic structure of BirAhas been determined (Wilson et al. 1992; Weaver et al. 2001b)and mutations that affect biotinligase activity are locatedin a disordered loop that becomes more ordered when biotin occupiesthe active site (Weaver et al. 2001b). Two mutant proteins,G115S and R118G, having alterations within the loop, are defectivein binding of both biotin and bio-5'AMP whereas ATP is boundnormally. The dissociation constants of the G115S and R118Gproteins for bio-5'-AMP binding are, respectively, 3000- and400-fold greater than that of wild type BirA whereas the reportedchanges in the biotin binding constants are less dramatic (250-and 100-fold greater than wild type, respectively; Kwon and Beckett 2000).BirA ${Delta}$ 1–34, a protein lacking the N-terminalDNA-binding domain, also binds biotin and bio-5'-AMP weakly(dissociation constants 100- and 1000-fold greater than thoseof the wild type protein, respectively; Xu and Beckett 1996).These data suggested that these mutant proteins might leak bio-5'-AMPinto the solvent where it would act as a promiscuous chemicalbiotinylation reagent in a proximity-dependent manner.

We report that a mutant BirA protein, R118G, acts as a promiscuousbiotinylation reagent that shows proximity-dependence in a modelsystem. Indeed, the R118G protein was found to efficiently biotinylateitself as well as a variety of proteins that normally lack thismodification.

Results

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Promiscuous in vivo biotinylation by R118G BirA
We first tested the possibility of obtaining a mutant BirA thatgave promiscuous biotinylation by examining the patterns ofbiotinylation during expression of the mutant proteins in E.coli. We reasoned that any mutant enzyme that had gained promiscuousbiotinylation ability would biotinylate E. coli proteins otherthan BCCP. The wild type and three mutant BirA proteins (R118G,G115S, and ${Delta}$ 1–34) were expressed from a plasmid-basedtac promoter (Kwon et al. 2002). High-level expression of eachprotein was confirmed by SDS-PAGE (data not shown). To assayfor the ability to biotinylate proteins in a promiscuous manner,the extracted proteins of each strain were analyzed for biotinattachment by SDS-PAGE separation followed by Western blottingwith a streptavidin-AP conjugate (Fig. 1). The extracts of allfour strains showed the expected biotinylated BCCP band plusa band that corresponded to biotinylated BirA (see below). However,many additional biotinylated protein bands were seen in extractsof the cells in which the R118G mutant protein had been expressed.In contrast, the wild type and N-terminal deletion protein extractsshowed weak labeling of noncognate proteins with the mutantprotein giving stronger signals. Surprisingly, the G115S proteinshowed no labeling of noncognate proteins. The labeled bandsseen in the R118G extract were strong evidence for promiscuousprotein biotinylation and thus we proceeded to purify and studythis mutant protein.

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Figure 1. Streptavidin Western blot analyses of crude cell extracts. Wild type and mutant BirA proteins were expressed in wild type strain JM109 as described in Materials and Methods. The crude extracts were separated by 12% SDS-PAGE, and analyzed by Western blotting with streptavidin-AP. Lanes 5–8 contained 10-fold more extract protein than lanes 1–4. (Lanes 1,5) Wild type BirA; (lanes 2,6) G115S BirA; (lanes 3,7) R118G BirA; and (lanes 4,8) ${Delta}$ 1–34 BirA (the N-terminal deletion mutant). The arrows indicate the bands corresponding to BirA and BCCP.

Promiscuous in vitro biotinylation by R118G
C-terminal hexahistidine-tagged (Histagged) wild type and R118GBirA proteins were purified by nickel-nitrilotriacetic acid(Ni-NTA) agarose chromatography. About 600 µg of eachprotein was obtained from 100 mL cultures with a purity of >95%.It should be noted that BirA is a robust protein that retainsactivity even when stored at room temperature. We performedin vitro biotinylation reactions using purified apo BCCP asa specific substrate and commercial BSA and/or RNAse A as promiscuousbiotin acceptors. Western blotting with streptavidin-AP showedthat both BSA and RNAse A became biotinylated with the R118Gprotein giving much greater modification than the wild typeprotein (Fig. 2

). In contrast, both BirA proteins efficientlybiotinylated the specific substrate, apo BCCP. The time coursesof R118G-dependent biotinylation of apo BCCP and RNAse A weredetermined (Fig. 3

). Biotinylation of the promiscuous acceptorprotein increased throughout the 24 h incubation whereas biotinylationof apo BCCP reached a maximal level within 30 min.

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Figure 2. In vitro biotinylation with purified wild type and R118G proteins. In vitro biotinylation reactions were initiated by addition of purified wild type or R118G mutant BirA proteins (to a final concentration of 20 nM) to a reaction mixture containing a 2 µM final concentration of a specific substrate (apo BCCP) or a promiscuous acceptor (BSA or RNAse A) followed by incubation for 1 h at 37°C as described in Materials and Methods, followed by SDS-PAGE. Biotinylation of each protein was then analyzed by Western blotting with streptavidin-AP. (Lane 1) apo BCCP lacking BirA (note that this apo BCCP preparation was slightly contaminated with holo BCCP accounting for the bands in lanes 1 and 5); (lane 2) apo BCCP with wild type BirA; (lane 3) BSA with wild type BirA; (lane 4) RNAse A with wild type BirA; (lane 5) apo BCCP lacking R118G BirA; (lane 6) apo BCCP with R118G BirA; (lane 7) BSA with R118G BirA; (lane 8) RNAse A with R118G BirA. The arrows show the migration positions of BSA, BCCP, and RNase A.

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Figure 3. Time course of in vitro biotinylation of apo BCCP and RNAse A with the wild type and R118G proteins. The experiment was done as described in Figure 2

and in Materials and Methods. Lanes 1–5 contained the specific substrate apo-BCCP whereas lanes 6–10 contained a promiscuous acceptor, RNAse A. Samples were taken after various time intervals. These were 30 min (lanes 1,6), 1 h (lanes 2,7), 2 h (lanes 3,8), 6 h (lanes 4,9), and 24 h (lanes 5,10). Biotinylation was analyzed by Western blotting with streptavidin-AP. The arrows indicate the bands corresponding to BCCP and RNase A.

BirA self-biotinylation activity
The crude extract of the bacterial strain (JM109, a strain thathas a normal biotin synthetic pathway) that expressed high levelsof the R118G protein showed many biotinylated protein bands(Fig. 1

). One of the stronger bands had the molecular weightof BirA suggesting that R118G had become biotinylated. A lessintense band was found at the same migration position for theother enzymes. We therefore tested the possibility that thepurified wild type and R118G proteins had become biotinylatedin vivo and found that only the R118G protein was highly modified(Fig. 4A

). When the R118G protein was expressed in an E. colibiotin auxotroph in the presence of ¹⁴C-labeled biotin, themolar ratio of covalently attached biotin to BirA was 0.4. Therefore,appreciable protein modification occurred during expressionunder biotin-sufficient conditions.

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Figure 4. Preparation and self-biotinylation of unbiotinylated BirA. (A) Wild type and R118G mutant BirA proteins were over expressed in either strain JM109 or in the bio strain BM4092 and purified as described in Materials and Methods. When strain BM4092 was used, the medium was depleted of biotin by addition of avidin to the 2XYT medium prior to induction of protein expression. An SDS-PAGE gel is shown. The left panel (lanes 1–4) was stained with Coomassie blue (1.4 mg protein per lane), whereas the right panel (lanes 5–8) was submitted to streptavidin-AP Western blot analysis (100 ng protein per lane). (Lanes 1,5) Wild type BirA expressed in JM109; (lanes 2,6) R118G BirA expressed in JM109; (lanes 3,7) wild type BirA expressed in BM4092; (lanes 4,8) R118G BirA expressed in BM4092. (B) The unbiotinylated preparations of the wild type (lanes 1–4) and R118G (lanes 5–8) proteins were used for in vitro self-biotinylation reactions (Materials and Methods). The BirA concentrations were varied as given on the figure. (Lanes 1,5) 250 nM; (lanes 2,6) 500 nM; (lanes 3,7) 750 nM; (lanes 4,8) 1 µM. After 1 h at 37°C a volume of each reaction corresponding to 2 pmole of protein was taken from of the various samples, run on SDS-PAGE, and analyzed by Western blotting with streptavidin-AP.

To obtain unbiotinylated R118G for further in vitro characterizationof the self-biotinylation reaction, we expressed the proteinin a strain (BM4092) defective in biotin biosynthesis and attachment(Barker and Campbell 1981). Avidin was added prior to proteininduction to deplete the growth medium of free biotin. The absenceof biotin available for the self biotinylation resulted in preparationsof unmodified BirA proteins (Fig. 4A

). The in vitro biotinylationactivity of these preparations toward apo BCCP, BSA, and RNaseA was similar to that of the in vivo biotinylated R118G protein(data not shown). Upon incubation of the unmodified proteinswith biotin and ATP, both proteins became biotinylated, althoughthe mutant protein showed appreciably higher levels of selfmodification (Fig. 4B

BirA self biotinylation was expected to be primarily an intramolecularreaction since both the wild type and R118G proteins are monomericat the concentrations we have tested (Kwon et al. 2002). Totest the possible role of dimerization, we added a double-strandedoligonucleotide containing the bio operon regulatory regionto the biotinylation reactions because specific DNA bindingdrives BirA dimerization (Streaker and Beckett 2003) and BirAdimerization in the presence or absence of DNA is thought touse the same protein interface (Weaver et al. 2001a). No increasein self biotinylation was seen (data not shown). Also, the levelsof self biotinylation (obtained by quantitation of the dataof Fig. 4B; data not shown) were found to show a linear increasewith BirA concentration. From these data self biotinylationseems predominantly an intramolecular reaction. The extent ofR118G BirA self biotinylation in vitro was measured by assayof attachment of ¹⁴C-biotin. When incubated with ¹⁴C-biotinand ATP for 24 h, the molar ratio of covalently attached biotinto BirA was 0.2. Note that self biotinylation in vivo was alsonot caused by dimerization driven by specific DNA binding, asit occurred during expression in a host strain lacking the biooperator (data not shown).

Proximity-dependent biotinylation
As discussed above, biotinylation of promiscuous acceptor proteinsby bio-5'-AMP released by BirA R118G would be expected to modifyacceptors in a proximity-dependent manner. According to ouroriginal hypothesis this could result from the rapid hydrolysisof a mixed anhydride when in free solution at elevated pH, aproperty that should limit the ability of bio-5'-AMP to reactwith distant proteins. Another possibility is that the lysineside chains of promiscuous acceptor proteins somehow accessthe R118G active site. Our first indication of proximity-dependentbiotinylation was the finding that a 10-fold molar excess ofBSA failed to completely suppress self biotinylation of R118G(data not shown; similar data are given in Fig. 5) suggestingthat R118G was preferentially modified compared to the acceptorprotein. For a more general test system we used the His-tagpresent on the R118G C-terminus. In this case the biotin acceptorswere the heavy and light chains of an antibody that recognizesa pentahistidine tag. We compared the relative biotinylationrates of the antibody when it was either bound to the R118GC-terminus or free in solution when bound to a His-tagged derivativeof chloramphenicol acetyltransferase (CAT) (the antibody wasblocked with a His-tagged CAT protein prior to addition of theHis-tagged R118G). Hence, in the first case the acceptor proteinwould be located close to the BirA active site whereas in thesecond case the acceptor protein would be randomly distributedin solution. In some experiments we added BSA or RNAse A aspromiscuous competitor proteins. The heavy and light chainsof the antibody were found to be fair biotinylation acceptorswhen bound to the R118G C-terminus (Fig. 5), but were significantlyless modified when the antibody was first blocked with His-taggedCAT to prevent binding of the antibody to the BirA His-tag.The blocking step reduced biotinylation of the antibody heavychain to 22% of that seen in the absence of His-tagged CAT (theintensity of signal for light chain in the presence of His-taggedCAT was too weak for quantitation). The decrease in antibodybiotinylation upon blocking cannot be attributed to competitionfor biotinylation between the His-tagged CAT protein and theantibody since addition of BSA or RNAse A (both of which aremuch better biotin acceptors than CAT) or CAT lacking a His-tag(data not shown), had little or no effect on biotinylation ofthe R118G-bound antibody (Fig. 5).

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Figure 5. Proximity-dependent biotinylation with R118G BirA. (A) His-tagged R118G BirA (final concentration 400 nM) was incubated in the reaction mixtures containing acceptor (Penta-HIS antibody) at a final concentration of 200 nM with or without the specific competitor (HIS-CAT, final concentration 2 µM) or with a promiscuous acceptor (either BSA or RNAse A, final concentration 2 µM) for 1 h at 37°C as described in Materials and Methods. The samples were then separated on an SDS-PAGE gel and analyzed by Western blot with streptavidin-AP. (Lane 1) His-tagged R118G BirA with omission of ATP; (lane 2) His-tagged R118G BirA plus Penta-HIS antibody; (lane 3) His-tagged R118G BirA plus Penta-HIS antibody preblocked with His-tagged CAT; (lane 4) His-tagged R118G BirA plus Penta-HIS antibody plus BSA; (lane 5) His-tagged R118G BirA plus Penta-HIS antibody plus RNAse A. (B) The reaction conditions were exactly the same as those of Figure 5A

, except that 0.25 µCi d-[carbonyl-¹⁴C]biotin was used as the biotin source. After the reaction mixtures were resolved in 12% SDS-PAGE, the gel was dried and exposed on X-ray film for one month at –80°C. The lanes are as in panel A. The arrows indicate BSA, the heavy (HC) and light (LC) chains of anti-Penta-HIS antibody, His-tagged BirA, His-tagged CAT (His-CAT), and RNase A. Note that the His-tagged CAT preparation contains a degradation product of the CAT protein in addition to the full-length protein.

We routinely assayed biotinylation by Western blots with detectionby streptavidin-AP binding of biotinylated proteins. Althoughthis is an established and very widely used technique, we haveverified our results by a more direct assay, attachment of ¹⁴C-biotin.Biotin labeled with ¹⁴C was used in place of nonradioactivebiotin in the in vitro biotinylation reaction. The reactionmixture was then loaded on an SDS-PAGE gel, which was driedand exposed to X-ray film. The results obtained by this directmethod (Fig. 5B

) confirmed those obtained by the streptavidin-APWestern blot method, although the ¹⁴C-biotin method was muchless sensitive (a 1 mo exposure was required) and the relativeintensities of some bands were somewhat different from thosegiven by streptavidin-AP staining presumably because of thesteric problems of binding more than one streptavidin conjugateto a multiply biotinylated protein.

Discussion

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Abstract
Introduction
Results
Discussion
Materials and methods
References

We tested three different mutant BirA proteins for the abilityto covalently attach biotin to proteins that normally do notcarry this modification by assaying for promiscuous proteinbiotinylation in cells producing these enzymes. Only the R118Gmutant protein showed a high level of promiscuous protein biotinylation.The N-terminal deletion mutant enzyme ( ${Delta}$ 1–34) showed alower level of promiscuous biotinylation whereas the third mutantenzyme, G115S, showed the same or a lower rate of biotinylationof noncognate proteins than did the wild type protein. Thiswas surprising since G115S has the highest reported rate ofbio-5'-AMP release of the mutant proteins (Kwon and Beckett 2000;Kwon et al. 2002). However, binding was assayed indirectlyby loss of the increase in protein intrinsic fluorescence thatoccurs upon binding of bio-5'-AMP to BirA (Kwon and Beckett 2000).Therefore, the differences in promiscuous biotinylationlevels observed for the G115S and R118G mutants could be explainedif bio-5'-AMP does not completely exit the G115S active sitebut only shifts its position within the protein thereby resultingin loss of fluorescence. That is, bio-5'-AMP could be misalignedin G115S rather than released and might block access to theactive site (note that the presence of the G115S mutation wasconfirmed in our experiments by checking for the unique restrictionsite introduced by the mutation).

All of the BirA proteins we studied undergo self biotinylation,although the R118G enzyme had much higher levels of self modificationthan the other proteins. The observed self modification wasnot unexpected, since two other enzymes that synthesize acyl-adenylateintermediates, the methionyl-tRNA synthetases of E. coli andBacillus stearothermophilus, have been shown to catalyze selfmethionylation (Gillet et al. 1997; Hountondji et al. 2000).In these enzymes it was reported that once methionine was activatedby ATP to form methionine-5'-AMP, the reactive lysine side chainsclosest to the acyl-adenylate were those modified (Hountondji et al. 2000).We expect that BirA self biotinylation proceedsby a similar mechanism. The low levels of self biotinylationand promiscuous protein biotinylation by wild type BirA observedin vivo seems likely to be a consequence of over expressionof the enzyme resulting in an intracellular BirA concentrationthat greatly exceeds the supply of apo-BCCP, the normal biotinacceptor. In vitro methionyl-tRNA synthetase self modificationis suppressed by addition of the tRNA acceptor (Gillet et al. 1997)and we expect the apo BCCP would have a similar effecton BirA self modification in vivo. Indeed, a wild type E. colicell contains only about ten or so molecules of BirA and BCCPis normally present in great excess. However, this ratio becomesgreatly skewed upon over expression of BirA leaving the enzymewithout its normal protein substrate.

We have considered two possible mechanisms for promiscuous proteinbiotinylation. The first possibility is that biotinylation ofsuch proteins is not a direct enzymatic activity of the R118Gprotein, but is due to chemical acylation by bio-5'-AMP releasedfrom the mutant active site. The second possibility is thatlysine side chains of promiscuous acceptor proteins somehowgain access to the BirA active site due to the R118G mutation.We favor the first possibility because it seems unlikely thatthe BirA active site could be rearranged such to allow accessby generic lysine residue side chains without losing the abilityto sequester bio-5'-AMP from the solvent. Indeed, the targetlysine residue of the naturally biotinylated proteins seemsdesigned to be extraordinarily accessible. In the biotin domainsof known structure, those of E. coli BCCP and Propionibacteriumshermanii 1.3S proteins, the target lysine is located at thevery tip of an exposed tight ${beta}$ -turn that markedly protrudes fromthe surface of the protein (Chapman-Smith and Cronan Jr. 1999;Reddy et al. 2000). Therefore, neither protein secondary structuresnor neighboring side chains sterically hinder the ability ofthis lysine side chain to enter the BirA active site. Indeed,the lysine residue must be in this precise location to productivelyinteract with the BirA active site as moving the residue oneplace in either direction abolishes biotinylation (Reche et al. 1998).Moreover, introduction of a second lysine residueadjacent to the target residue markedly inhibits biotinylation(Reche et al. 1998). For these reasons plus the precedent ofchemical acylation by acyladenylates released by other enzymes(Gillet et al. 1997; Ehmann et al. 2000; Hountondji et al. 2000)we favor bio-5'-AMP release as the mechanism of promiscuousprotein biotinylation. Indeed, Beckett and coworkers have shownthat wild type BirA releases radioactive bio-5'-AMP synthesizedfrom biotin and ATP (Xu and Beckett 1997; Kwon and Beckett 2000;Kwon et al. 2002). Further support for the involvement of bio-5'-AMPcomes from an experiment (data not shown) in which BSA trappedin a dialysis bag was found to be slowly biotinylated in anATP-dependent manner when R118G, biotin, and ATP were placedoutside the bag (which excluded molecules greater than 10 kDain size). It would seem very difficult for a lysine residueside chains to reach into the BirA active site across a dialysismembrane whereas bio-5'-AMP would diffuse across the membrane.However, further work will be required to define the mechanismof promiscuous protein biotinylation.

We envision the proximity-dependence of biotin attachment toresult from a cloud of bio-5'-AMP emanating from the R118G BirAactive site that acylates nearby protein molecules (Fig. 6).We have not attempted to optimize the proximity-dependence ofprotein biotinylation, because for unknown reasons acceptorproteins vary markedly in their efficiency of biotinylation(e.g., the antibody light and heavy chains). However, the thicknessand range of the bio-5'-AMP cloud should be readily manipulatedby choice of the experimental conditions. For example increasesin buffer pH will decrease the half-life of bio-5'-AMP (BirAhas a broad pH optimum) and small molecule nucleophiles (e.g.,amines, thiols) added to the reaction buffer will react withbio-5'-AMP and thereby block labeling of distant proteins. Acounter argument to our claim of proximity-dependent biotinylationis that all we have done is to increase the local concentrationof the acceptor proteins. However, proximity mandates localizationand localization necessarily results in increased concentration.

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Figure 6. A depiction of proximity-dependent biotinylation. (A) A conjugate (or a fusion protein) composed of a mutant BirA and a target module (TM) of interest is exposed to a mixture of target (T) molecules. Some target molecules (T-1) bind the TM whereas others (T-2) fail to bind. (B) Upon addition of biotin and ATP the mutant BirA synthesizes bio-5'-AMP, which is depicted as a solid circle (the biotin moiety) linked to AMP (the shaded hexagon). (C) The localized cloud of bio-5'-AMP chemically bio-tinylates all of the proteins in the vicinity of BirA, T-1, TM, and BirA. The T-2 molecules fail to become biotinylated because most bio-5'-AMP molecules are hydrolyzed (shown as unlinked circles and hexagons) before they can reach the distant T-2 molecules. For simplicity, the process is shown in stages, although in practice, the interaction of TM and T-1, bio-5-AMP synthesis, and chemical biotinylation would proceed simultaneously.

It remains to be seen if promiscuous enzymatic protein biotinylationwill be useful. The rates and extents of the BirA R118G-dependentreactions are modest at best. Logical design of more activeproteins is hampered by the lack of a crystal structure of BirAcomplexed with bio-5'-AMP. The only co-crystal structures presentlyavailable are BirA complexed to biotinoyl-lysine (Wilson et al. 1992)and to biotin (Weaver et al. 2001b). Neither structureaids study of the protein biotinylation reaction in that theformer structure is an enzyme–product complex and thelatter structure gives no information on the major conformationalchanges known to accompany bio-5'-AMP synthesis and binding(Xu and Beckett 1997; Kwon et al. 2000; Weaver et al. 2001b).However, two nonhydrolysable bio-5'-AMP analogs have recentlybeen found to bind BirA and one of these, biotinol-5'-AMP, boundalmost as well as bio-5'-AMP (Brown et al. 2004). The stabilityof these analogs should allow deduction of the structure ofthe BirA-bio-5'-AMP complex and perhaps design of enzymes moreuseful than R118G. Another approach to isolate more useful enzymes,that of random screening for mutant enzymes giving higher ratesand extents of promiscuous biotinylation should be facilitatedby the fact that BirA can be expressed in an active form onthe surface of phage M13 (Heinis et al. 2001). Finally, thermophilicand psychrophilic bacteria have BPLs very similar to that ofE. coli and the use of mutant forms of these enzymes shouldallow access to a very wide range of biotinylation conditions.

Materials and methods

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Chemicals and reagents
Ni-NTA agarose from Qiagen was used for column chromatographyand an anti-pentahistidine antibody (Penta-His Antibody, BSA-freefrom Qiagen) was used as an acceptor for assay of proximity-dependentbiotinylation. A streptavidin-alkaline phosphatase conjugate(Streptavidin-AP) and CDP-Star (Roche) were used for Westernblot analysis. BSA, avidin, and RNAse A (Sigma) were used aseither promiscuous acceptors or promiscuous competitors. ApoBCCP was prepared as described previously (Choi-Rhee and Cronan 2003).Amersham provided d-[carbonyl-¹⁴C]biotin that was dissolvedin 100 µL of 0.1 M sodium phosphate buffer (pH 7.0) containing0.15 M sodium chloride and stored at –20°C.

Expression and purification of the BirA proteins
Plasmids (Xu and Beckett 1996; Kwon and Beckett 2000) carryingwild type and two mutant (G115S and R118G) birA genes each havingan extension encoding a C-terminal hexa-histidine sequence (His-tag)plus an untagged ${Delta}$ N1–34 gene (the kind gifts of Dr. DorothyBeckett) were introduced into E. coli strain JM109. E. colistrain BM4092 (Barker and Campbell 1981) was used as a hoststrain for isolation of unbiotinylated BirA protein. Cultureswere grown in 2XYT medium containing 100 mg/L sodium ampicillin,and 5 µM biotin. Protein expression was induced at anoptical density of 0.5 at 600 nm by addition of isopropyl- ${beta}$ -galactoside(IPTG) to 1 mM and allowed to proceed for 4 h. For biotin depletionof 2XYT medium, cells were harvested at an optical density of0.5 at 600 nm and resuspended in 2XYT medium lacking added biotinand containing avidin at a final concentration of 2U/mL. IPTG(1 mM) was added to induce protein expression, and inductionwas allowed to proceed for 4 h. The cells were then collectedby centrifugation and either resuspended in SDS sample bufferand analyzed by streptavidin-AP blotting or resuspended in lysisbuffer (50 mM sodium phosphate at pH 8.0, 300 mM NaCl, 0.1 mMDTT) for protein purification. Cells were lysed by sonicationand extracts were incubated with Ni-NTA agarose for 1 h at 4°Cwith gentle agitation. After washing the resin with 10 volumesof 25 mM imidazole in lysis buffer, the protein was eluted with250 mM imidazole in lysis buffer. The eluate was dialyzed againststorage buffer (40 mM Tris-HCl at pH 8.0, 100 mM KCl, 10% glycerol)overnight. The concentrations of the purified proteins wereadjusted to 2 µM and kept at –80°C until use.

Expression and purification of the His-tagged form of chloramphenicol acetyltransferase (His-CAT)
Plasmid pER50 was constructed by cutting pCY572 (Cronan 2003)with SalI plus XhoI to obtain a 1.2 Kb fragment containing theCAT gene, and ligating this fragment into pET28b (Novagen) thathas been cut with XhoI, and screening for an insert having theproper orientation by restriction mapping. Plasmid pER50 wasintroduced into E. coli strain BL21 (DE3) and cultures weregrown in Luria Bertani (LB) medium containing 50 mg/L of kanamycinsulfate and 30 mg/L of chloramphenicol to an optical densityof 0.5 at 600 nm. CAT expression was induced by addition ofITPG to 1 mM and allowed to proceed for 30 min at 30°C.The cells were harvested and the protein was purified by Ni-NTAagarose chromatography as described above.

In vitro biotinylation
In vitro biotinylation was done as described previously (Chapman-Smith et al. 1999)with some modifications. Unless otherwise stated,the assays contained 40 mM Tris-HCl (pH 8.0), 3 mM ATP, 5.5mM MgCl₂, 5 µM biotin, 100 mM KCl, 1.4 mM ${beta}$ -mercap-toethanol,plus the indicated concentrations of substrate or acceptor ina final volume of 20 µL. The reaction was initiated byaddition of purified BirA protein to a final concentration of20 nM followed by incubation for up to 24 h at 37°C. Allof the BirA proteins were saturated with substrates at theseconcentrations. For the self-biotinylation reaction, purifiedBirA proteins were used as both enzyme and substrate. For assayof proximity-dependent bio-tinylation, Penta-HIS antibody (finalconcentration 200 nM) was incubated with 2 µM (final concentration)of competitor protein (His-tagged-CAT, BSA, or RNAse A) for30 min at room temperature. The reaction was initiated by additionof purified BirA protein to a final concentration of 400 nMand incubated for 1 h at 37°C. For biotinylation reactionswith ¹⁴C-biotin, the biotin was replaced with 0.25 µCiof ¹⁴C-biotin in a final volume of 20 µL.

Western blot analysis with streptavidin
Crude extracts or purified proteins were loaded on 12% SDS-PAGEgels (Choi-Rhee and Cronan 2003). The separated proteins weretransferred to a membrane (Immobilon-P from Millipore) and themembrane was briefly rinsed with maleic buffer (100 mM maleicacid plus 150 mM NaCl adjusted to pH 7.5 with NaOH). The membranewas incubated first with blocking buffer consisting of 1% WesternBlocking Reagent (Roche) in maleic acid buffer for 30 min andthen with streptavidin-AP-conjugate in maleic acid buffer foranother 30 min at room temperature. After rinsing twice withwashing buffer (0.3% Tween 20 in maleic acid buffer) for 15min, the membrane was incubated with CDP-Star in detection buffer(100 mM Tris-HCl at pH 9.5, 100 mM NaCl) for 5 min. The membranewas then exposed to X-ray film.

Footnotes

Article published online ahead of print. Article and publicationdate are at http://www.proteinscience.org/cgi/doi/10.1110/ps.04911804.

Acknowledgments

This work was supported by SurroMed, Inc., and NIH grant AI15650.

References

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

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