Covalent attachment of proteins to solid supports and surfaces via Sortase-mediated ligation

Background

There is growing interest in the attachment of proteins to solid supports for the development of supported catalysts, affinity matrices, and micro devices as well as for the development of planar and bead based protein arrays for multiplexed assays of protein concentration, interactions, and activity. A critical requirement for these applications is the generation of a stable linkage between the solid support and the immobilized, but still functional, protein.

Methodology

Solid supports including crosslinked polymer beads, beaded agarose, and planar glass surfaces, were modified to present an oligoglycine motif to solution. A range of proteins were ligated to the various surfaces using the Sortase A enzyme of S. aureus. Reactions were carried out in aqueous buffer conditions at room temperature for times between one and twelve hours.

Conclusions

The Sortase A transpeptidase of S. aureus provides a general, robust, and gentle approach to the selective covalent immobilization of proteins on three very different solid supports. The proteins remain functional and accessible to solution. Sortase mediated ligation is therefore a straightforward methodology for the preparation of solid supported enzymes and bead based assays, as well as the modification of planar surfaces for microanalytical devices and protein arrays.     

RNA labeling, conjugation and ligation

Advances in RNA nanotechnology will depend on the ability to manipulate, probe the structure and engineer the function of RNA with high precision. This article reviews current abilities to incorporate site-specific labels or to conjugate other useful molecules to RNA either directly or indirectly through post-synthetic labeling methodologies that have enabled a broader understanding of RNA structure and function. Readily applicable modifications to RNA can range from isotopic labels and fluorescent or other molecular probes to protein, lipid, glycoside or nucleic acid conjugates that can be introduced using combinations of synthetic chemistry, enzymatic incorporation and various conjugation chemistries. These labels, conjugations and ligations to RNA are quintessential for further investigation and applications of RNA as they enable the visualization, structural elucidation, localization, and biodistribution of modified RNA.     

Site-specific immobilization of proteins in a microarray using intein-mediated protein splicing

One of the critical issues in the generation of a protein microarray lies in the choice of immobilization strategies, which ensure proteins are adhered to the glass surface while properly retaining their native biological activities. Herein, we report a bacterium-based, intein-mediated strategy to generate N-terminal cysteine-containing proteins which are then chemoselectively immobilized to a thioester-functionalized glass slide to generate the corresponding protein microarray. We also showed preliminary data of the strategy in a yeast host system.     

Human uridine-cytidine kinase phosphorylation of ribavirin: a convenient method for activation of ribavirin for conjugation to proteins

Ribavirin is a synthetic nucleoside analog that is used for the treatment of hepatitis C virus (HCV) infection. Its primary toxicity is hemolytic anemia, which sometimes necessitates dose reduction or discontinuation of therapy. Selective delivery of ribavirin into liver cells would be desirable to enhance its antiviral activity and avoid systemic side effects. One approach to liver-specific targeting is conjugation of the ribavirin with asialoglycoprotein that is taken up specifically by liver cells. Human uridine-cytidine kinase-1 (UCK-1) was used for ribavirin phosphorylation to its monophosphate form. 1-Ethyl-3-diisopropylaminocarbodiimide (EDC) was used as a coupling agent. The best results were obtained using direct conjugation protocol with a molar ratio of 6.5 ribavirin monophosphate (RMP) molecules per one asialoorosomucoid (AsOR) molecule. Our findings show that ribavirin is a potential substrate of UCK-1, and RMP formed could be chemically coupled to AsOR to form a conjugate for liver specific targeting.     

Engineering a high-affinity scaffold for non-chromatographic protein purification via intein-mediated cleavage

While protein purification has long been dominated by standard chromatography, the relatively high cost and complex scale‐up have promoted the development of alternative non‐chromatographic separation methods. Here we developed a new non‐chromatographic affinity method for the purification of proteins expressed in Escherichia coli. The approach is to genetically fuse the target proteins with an affinity tag. Direct purification and recovery can be achieved using a thermo‐responsive elastin‐like protein (ELP) scaffold containing the capturing domain. Naturally occurring cohesin–dockerin pairs, which are high‐affinity protein complex responsible for the formation of cellulosome in anaerobic bacteria, were used as the model. By exploiting the highly specific interaction between the dockerin and cohesin domain from Clostridium thermocellum and the reversible aggregation property of ELP, highly purified and active dockerin‐tagged proteins, such as the endoglucanase CelA, chloramphenicol acetyl transferase (CAT), and enhanced green fluorescence protein (EGFP), were recovered directly from crude cell extracts in a single thermal precipitation step with yields achieving over 90%. Incorporation of a self‐cleaving intein domain enabled rapid removal of the affinity tag from the target proteins, which was subsequently removed by another cycle of thermal precipitation. This method offers great flexibility as a wide range of affinity tags and ligands can be used. Biotechnol. Bioeng. 2012; 109: 2829–2835. © 2012 Wiley Periodicals, Inc.     

NMR observation of selected segments in a larger protein: central-segment isotope labeling through intein-mediated ligation

Peptide segments in a protein, which can include an active site of interest or be a series of parts constituting the entire structure, are now selectively observed by nuclear magnetic resonance (NMR) spectroscopy using samples prepared by the intein-mediated ligation method. Two separate inteins were used to ligate NMR-transparent segments to both the ends of an NMR-visible segment, producing a partly visible intact protein molecule. The (15)N-(1)H correlation spectrum of a 370-residue maltose binding protein labeled with (15)N at a continuous segment comprising residues Gly(101)-Ser(238) showed the essential elimination of signal overlapping, the signals being at the same positions as for the uniformly labeled sample. This method will allow structural analysis by NMR of over 50-kDa proteins in combination with contemporary NMR techniques suppressing the signal decays of larger proteins.     

Bisphosphonate conjugation to proteins as a means to impart bone affinity

Growth factors are endogenous proteins capable of stimulating new bone formation, but their clinical benefit for systemic stimulation of bone mass has not been demonstrated. The critical challenge is to deliver a significant dose of the proteins to bone after intravenous injection. This challenge may be overcome by derivatizing proteins with ligands that exhibit a high bone affinity (e.g., bisphosphonates). To demonstrate the feasibility of this approach, 1-amino-1,1-diphosphonate methane (aminoBP) was conjugated to a model protein, albumin. The conjugation was performed by (1) converting the amino group of aminoBP to a thiol group using 2-iminothiolane, (2) derivatizing the albumin amino groups with a thiol-reactive sulfosuccinimidyl-4-(N-maleimidomethyl)-1-cyclohexane carboxylate, and (3) reacting the derivatized albumin with thiolated aminoBP. Typically, 1-4 aminoBP molecules per albumin were obtained. The conjugated albumin exhibited a high affinity to hydroxyapatite that was proportional to the extent of conjugation. The conjugates were shown to exhibit a high affinity to bone matrix in vitro in a serum-containing medium. Once bound to bone matrix, the conjugates were found to desorb more slowly than the unmodified albumin, especially from bone whose organic matrix was removed by ashing. In conclusion, conjugation of bisphosphonates to albumin was shown to impart a high bone affinity to the protein, and such conjugates can be potentially targeted to bone.     

The application of quantum dots as fluorescent label to glycoarray

A sensitive, specific, and rapid method for the detection of carbohydrate-protein interactions was demonstrated using quantum dots (QDs) as a fluorescence label coupled with protein. 1,3-Dipolar cycloaddition between azide and alkyne was exploited to attach alpha-d-glucopyranoside to a C(14) hydrocarbon chain that noncovalently binds to the microtiter well surface, and the product formation was detected by both electrospray ionization-mass spectrometry (ESI-MS) and QD- (or fluorescein isothiocyanate (FITC))-conjugated lectin binding. It indicated that the peak intensity of the fluorescence emission was proportional to the initial concanavalin A (Con A) concentration in the range of 2 x 10(-3) micromol/L to 2 x 10(-2)mmol/L with a detection limit at least 100 times lower than that of the FITC-based method.     

Ssp DnaB intein大肠杆菌中介导FVIII重链和轻链的连接

研究利用intein的蛋白质反式剪接功能在大肠杆菌中对凝血VIII因子(FVIII)重链和轻链的连接作用,将B结构域大部分缺失型FVIII(BDD-FVIII)于满足剪接所需的保守性氨基酸Ser1657前断裂为重链和轻链,分别与split mini Ssp DnaB intein的106个氨基酸的N端(Int-N)和48个氨基酸的C端(Int-C)融合,构建到原核表达载体pBV220。诱导表达后SDS-PAGE分析可见预期大小的BDD-FVIII蛋白条带,Western blotting用FVIII特异性抗体证明其为剪接所产生的BDD-FVIII蛋白,表明intein可有效连接BDD-FVIII的重链和轻链。为进一步甲型血友病基因治疗研究应用intein以双腺相关病毒载体(AAV)携带FVIII基因,克服单个AAV载体的容量限制提供了依据。     

Observing selected domains in multi-domain proteins via sortase-mediated ligation and NMR spectroscopy

NMR spectroscopy has distinct advantages for providing insight into protein structures, but faces significant resolution challenges as protein size increases. To alleviate such resonance overlap issues, the ability to produce segmentally labeled proteins is beneficial. Here we show that the S. aureus transpeptidase sortase A can be used to catalyze the ligation of two separately expressed domains of the same protein, MecA (B. subtilis). The yield of purified, segmentally labeled MecA protein conjugate is ~40%. The resultant HSQC spectrum obtained from this domain-labeled conjugate demonstrates successful application of sortase A for segmental labeling of multi-domain proteins for solution NMR study.     

Establishment of intein-mediated protein ligation under denaturing conditions: C-terminal labeling of a single-chain antibody for biochip screening

Intein-mediated protein ligation is a recently developed method that enables the C-terminal labeling of proteins. This technique requires a correctly folded intein mutant that is fused to the C-terminus of a target protein to create a thioester, which allows the ligation of a peptide with an N-terminal cysteine (1, 2). Here we describe the establishment of this method for the labeling, under denaturing conditions, of target proteins that are expressed insolubly as intein fusion proteins. A GFPuv fusion protein with the Mycobacterium xenopi gyrA intein was expressed in inclusion bodies in Escherichia coli and initially used as a model protein to verify intein cleavage activity under different refolding conditions. The intein showed activity after refolding in nondenaturing and slightly denaturing conditions. A construct of the same intein with an anti-neutravidin single-chain antibody was also expressed in an insoluble form. The intein-mediated ligation was established for this single chain antibody-intein fusion protein under denaturing conditions in 4 M urea to prevent significant precipitation of the fusion protein during the first refolding step. Under optimized conditions, the single-chain antibody was labeled with a fluorescent peptide and used for antigen screening on a biochip after final refolding. This screening procedure allowed the determination of binding characteristics of the scFv for avidin proteins in a miniaturized format.     

Differential conjugation of polyamines to calf nuclear and nucleolar proteins

Nuclei and nucleoli isolated from calf liver contain acid-precipitable putrescine, spermidine and spermine conjugates. The polyamines are released upon peptide bond hydrolysis. All of the nuclear putrescine conjugate and a major portion of the polyamine conjugates are localized within the nucleolus. Nuclei and nucleoli also contain, in proportions consistent with the nucleolar/nuclear protein ratio, the putative conjugating enzyme, transglutaminase, as well as amine acceptor substrates to which radiolabeled putrescine can be conjugated by endogenous enzyme. Extraction of the isolated organelles with saline solutions of increasing ionic strength showed a differential distribution of the polyamine derivatives: all the covalently linked putrescine was associated with the less soluble components of the chromatin residue, while the spermidine and spermine conjugates were associated with several salt-extractable protein fractions as well as tightly bound to the chromatin pellet. Mono-gamma-glutamyl putrescine was detected after proteolytic digestion of the 600 mM NaCl fraction, further suggesting the enzymatic action of transglutaminase(s) in the conjugation process.     

Site-specific biosynthetic incorporation of a fluorescent tag into proteins via cysteine-tRNA(Cys)

Site-specific incorporation of biophysical probes into proteins during translation can permit structure/function studies on selected proteins in heterogeneous environments. We report here a procedure for incorporating a fluorescent tag into proteins via Escherichia coli Cys-tRNA(Cys) during in vitro protein synthesis. Naturally occurring Cys-tRNA(Cys) is an attractive vehicle for fluorophore incorporation since it can be readily prepared in quantity and reacted with commercially available fluorophores. Moreover, proteins can often be constructed with a single Cys so that fluorophore incorporation results in a tag at a unique site.     

Cell-to-cell transport of proteins and fluorescent tracers via plasmodesmata during plant development

Plant cells communicate with each other via channels called plasmodesmata (PD). PD are not passive channels, but critical players in gene regulation, controlling intercellular transport of macromolecules between particular cells during development.     

The sulfurtransferase activity of Uba4 presents a link between ubiquitin-like protein conjugation and activation of sulfur carrier proteins

Because of mechanistic parallels in the activation of ubiquitin and the biosynthesis of several sulfur-containing cofactors, we have characterized the human Urm1 and Saccharomyces cerevisiae Uba4 proteins, which are very similar in sequence to MOCS2A and MOCS3, respectively, two proteins essential for the biosynthesis of the molybdenum cofactor (Moco) in humans. Phylogenetic analyses of MOCS3 homologues showed that Uba4 is the MOCS3 homologue in yeast and thus the only remaining protein of the Moco biosynthetic pathway in this organism. Because of the high levels of sequence identity of human MOCS3 and yeast Uba4, we purified Uba4 and characterized the catalytic activity of the protein in detail. We demonstrate that the C-terminal domain of Uba4, like MOCS3, has rhodanese activity and is able to transfer the sulfur from thiosulfate to cyanide in vitro. In addition, we were able to copurify stable heterotetrameric complexes of Uba4 with both human Urm1 and MOCS2A. The N-terminal domain of Uba4 catalyzes the activation of either MOCS2A or Urm1 by formation of an acyl-adenylate bond. After adenylation, persulfurated Uba4 was able to form a thiocarboxylate group at the C-terminal glycine of either Urm1 or MOCS2A. The formation of a thioester intermediate between Uba4 and Urm1 or MOCS2A was not observed. The functional similarities between Uba4 and MOCS3 further demonstrate the evolutionary link between ATP-dependent protein conjugation and ATP-dependent cofactor sulfuration.