Site-specific Protein Labeling Research Articles

3D structure determination of a protein in living cells using paramagnetic NMR spectroscopy.

Determining the three-dimensional structure of a protein in living cells remains particularly challenging. We demonstrated that the integration of site-specific tagging proteins and GPS-Rosetta calculations provides a fast and effective way of determining the structures of proteins in living cells, and in principle the interactions and dynamics of protein-ligand complexes.

Peptide-tags for site-specific protein labelling in vitro and in vivo.

Peptide-tag based labelling can be achieved by (i) enzymes (ii) recognition of metal ions or small molecules and (iii) peptide-peptide interactions and enables site-specific protein visualization to investigate protein localization and trafficking.

Selective Coupling of Click Anchors to Proteins via Trypsiligase.

The combination of pure chemical methods with enzymatic approaches offers a kit system with maximum flexibility for site-specifically tagging proteins with a broad variety of artificial structures. Trypsiligase, a recently introduced designer enzyme for both N- and C-terminal site-specific labeling of peptides and proteins, has been used to introduce click anchors into the human protein cyclophilin 18 and the antibody Fab fragments anti-TNFα and anti-Her2. The subsequent click reactions with tetrazine or norbornene moieties lead to quantitative conversions to the corresponding dihydropyridazine products, thereby forming a stable covalent linkage between the label and the protein of interest. With this technology, cyclophilin 18 has been efficiently modified with the fluorescent dansyl moiety and the pharmaceutically relevant polymer PEG exclusively at its N-terminus. With the same methodology, the Fab fragments of anti-TNFα and anti-Her2 were derivatized exclusively at their C-terminal ends with PEG and the fluorescent dye carboxyfluorescein in the case of anti-TNFα or with the cytotoxic payload DM1 in the case of anti-Her2, to form a homogeneous antibody-drug conjugate (ADC).

Simultaneous Site-Specific Dual Protein Labeling Using Protein Prenyltransferases.

Site-specific protein labeling is an important technique in protein chemistry and is used for diverse applications ranging from creating protein conjugates to protein immobilization. Enzymatic reactions, including protein prenylation, have been widely exploited as methods to accomplish site-specific labeling. Enzymatic prenylation is catalyzed by prenyltransferases, including protein farnesyltransferase (PFTase) and geranylgeranyltransferase type I (GGTase-I), both of which recognize C-terminal CaaX motifs with different specificities and transfer prenyl groups from isoprenoid diphosphates to their respective target proteins. A number of isoprenoid analogues containing bioorthogonal functional groups have been used to label proteins of interest via PFTase-catalyzed reaction. In this study, we sought to expand the scope of prenyltransferase-mediated protein labeling by exploring the utility of rat GGTase-I (rGGTase-I). First, the isoprenoid specificity of rGGTase-I was evaluated by screening eight different analogues and it was found that those with bulky moieties and longer backbone length were recognized by rGGTase-I more efficiently. Taking advantage of the different substrate specificities of rat PFTase (rPFTase) and rGGTase-I, we then developed a simultaneous dual labeling method to selectively label two different proteins by using isoprenoid analogue and CaaX substrate pairs that were specific to only one of the prenyltransferases. Using two model proteins, green fluorescent protein with a C-terminal CVLL sequence (GFP-CVLL) and red fluorescent protein with a C-terminal CVIA sequence (RFP-CVIA), we demonstrated that when incubated together with both prenyltransferases and the selected isoprenoid analogues, GFP-CVLL was specifically modified with a ketone-functionalized analogue by rGGTase-I and RFP-CVIA was selectively labeled with an alkyne-containing analogue by rPFTase. By switching the ketone-containing analogue to an azide-containing analogue, it was possible to create protein tail-to-tail dimers in a one-pot procedure through the copper(I)-catalyzed alkyne-azide cycloaddition (CuAAC) reaction. Overall, with the flexibility of using different isoprenoid analogues, this system greatly extends the utility of protein labeling using prenyltransferases.

Site-specific labeling of proteins for electron microscopy.

Electron microscopy is commonly employed to determine the subunit organization of large macromolecular assemblies. However, the field lacks a robust molecular labeling methodology for unambiguous identification of constituent subunits. We present a strategy that exploits the unique properties of an unnatural amino acid in order to enable site-specific attachment of a single, readily identifiable protein label at any solvent-exposed position on the macromolecular surface. Using this method, we show clear labeling of a subunit within the 26S proteasome lid subcomplex that has not been amenable to labeling by traditional approaches.

Versatile and Efficient Site-Specific Protein Functionalization by Tubulin Tyrosine Ligase.

A novel chemoenzymatic approach for simple and fast site-specific protein labeling is reported. Recombinant tubulin tyrosine ligase (TTL) was repurposed to attach various unnatural tyrosine derivatives as small bioorthogonal handles to proteins containing a short tubulin-derived recognition sequence (Tub-tag). This novel strategy enables a broad range of high-yielding and fast chemoselective C-terminal protein modifications on isolated proteins or in cell lysates for applications in biochemistry, cell biology, and beyond, as demonstrated by the site-specific labeling of nanobodies, GFP, and ubiquitin.

Cysteine-free non-canonical C-intein for versatile protein C-terminal labeling through trans-splicing.

Site-specific protein labeling are powerful means of protein research and engineering; however, new and improved labeling methods are greatly needed. Split inteins catalyze a protein trans-splicing reaction that can be used for enzymatic and nearly seamless protein labeling. Non-canonical S11 split intein has been used in an earlier method of protein C-terminal labeling; however, its relatively large (~150 aa) N-intein fused to the target protein often hindered protein expression, folding, and solubility. To solve this problem, here, we have designed and demonstrated a new method of protein C-terminal labeling, by first engineering a functional non-canonical S1 split intein that has an extremely small (12 aa) N-intein and a cysteine-free C-intein. An engineered Rma DnaB S1 split intein was modified to have a cysteine-free C-intein, while still retaining its robust trans-splicing function, which permitted the C-extein in a C-precursor to have a single cysteine for easy and specific linkage with desired labeling groups. The resulting new and generally useful method has two unique advantages: (1) The extremely small (12 aa) N-intein, which must be fused to the C terminus of the target protein, is less likely to hinder the protein expression, folding, and solubility; and (2) the single cysteine in the C-extein may be readily linked to a variety of labeling or modification groups using commercially available reagents.

Nonorthogonal tRNA(cys)(Amber) for protein and nascent chain labeling.

In vitro-transcribed suppressor tRNAs are commonly used in site-specific fluorescence labeling for protein and ribosome-bound nascent chains (RNCs) studies. Here, we describe the production of nonorthogonal Bacillus subtilis tRNAcysAmber from Escherichia coli, a process that is superior to in vitro transcription in terms of yield, ease of manipulation, and tRNA stability. As cysteinyl-tRNA synthetase was previously shown to aminoacylate tRNAcysAmber with lower efficiency, multiple tRNA synthetase mutants were designed to optimize aminoacylation. Aminoacylated tRNA was conjugated to a fluorophore to produce BODIPY FL-cysteinyl-tRNAcysAmber, which was used to generate ribosome-bound nascent chains of different lengths with the fluorophore incorporated at various predetermined sites. This tRNA tool may be beneficial in the site-specific labeling of full-length proteins as well as RNCs for biophysical and biological research.

Molecular architecture of native fibronectin fibrils.

Fibronectin fibrils within the extracellular matrix play central roles in physiological and pathological processes, yet many structural details about their hierarchical and molecular assembly remain unknown. Here we combine site-specific protein labelling with single-molecule localization by stepwise photobleaching or direct stochastic optical reconstruction microscopy (dSTORM), and determine the relative positions of various labelled sites within native matrix fibrils. Single end-labelled fibronectin molecules in fibrils display an average end-to-end distance of ∼133 nm. Sampling of site-specific antibody epitopes along the thinnest fibrils (protofibrils) shows periodic punctate label patterns with ∼95 nm repeats and alternating N- and C-terminal regions. These measurements suggest an antiparallel 30–40 nm overlap between N-termini, suggesting that the first five type I modules bind type III modules of the adjacent molecule. Thicker fibres show random bundling of protofibrils without a well-defined line-up. This super-resolution microscopy approach can be applied to other fibrillar protein assemblies of unknown structure.

ChemInform Abstract: Recent Advances in Bioorthogonal Reactions for Site‐Specific Protein Labeling and Engineering

AbstractReview: [54 refs.

Two-step protein labeling by using lipoic acid ligase with norbornene substrates and subsequent inverse-electron demand Diels-Alder reaction.

Inverse-electron-demand Diels-Alder cycloaddition (DAinv ) between strained alkenes and tetrazines is a highly bio-orthogonal reaction that has been applied in the specific labeling of biomolecules. In this work we present a two-step labeling protocol for the site-specific labeling of proteins based on attachment of a highly stable norbornene derivative to a specific peptide sequence by using a mutant of the enzyme lipoic acid ligase A (LplA(W37V) ), followed by the covalent attachment of tetrazine-modified fluorophores to the norbornene moiety through the bio-orthogonal DAinv . We investigated 15 different norbornene derivatives for their selective enzymatic attachment to a 13-residue lipoic acid acceptor peptide (LAP) by using a standardized HPLC protocol. Finally, we used this two-step labeling strategy to label proteins in cell lysates in a site-specific manner and performed cell-surface labeling on living cells.

Genetic code expansion enables live-cell and super-resolution imaging of site-specifically labeled cellular proteins.

Methods to site-specifically and densely label proteins in cellular ultrastructures with small, bright, and photostable fluorophores would substantially advance super-resolution imaging. Recent advances in genetic code expansion and bioorthogonal chemistry have enabled the site-specific labeling of proteins. However, the efficient incorporation of unnatural amino acids into proteins and the specific, fluorescent labeling of the intracellular ultrastructures they form for subdiffraction imaging has not been accomplished. Two challenges have limited progress in this area: (i) the low efficiency of unnatural amino acid incorporation that limits labeling density and therefore spatial resolution and (ii) the uncharacterized specificity of intracellular labeling that will define signal-to-noise, and ultimately resolution, in imaging. Here we demonstrate the efficient production of cystoskeletal proteins (β-actin and vimentin) containing bicyclo[6.1.0]nonyne-lysine at genetically defined sites. We demonstrate their selective fluorescent labeling with respect to the proteome of living cells using tetrazine-fluorophore conjugates, creating densely labeled cytoskeletal ultrastructures. STORM imaging of these densely labeled ultrastructures reveals subdiffraction features, including nuclear actin filaments. This work enables the site-specific, live-cell, fluorescent labeling of intracellular proteins at high density for super-resolution imaging of ultrastructural features within cells.

How to pick a single amine?

Single-step site-specific labeling of native proteins is one of the holy grails in the chemical biology field. 2-Pyridinecarboxyaldehyde derivatives are shown to react selectively at the N terminus of proteins to form stable conjugates, irrespective of the nature of the N-terminal amino acid, enabling the straightforward introduction of useful functional groups into a wide array of proteins.

Quantum Chemical Calculations and Experimental Validation of the Photoclick Reaction for Fluorescent Labeling of the 5' cap of Eukaryotic mRNAs.

Bioorthogonal click reactions are powerful tools to specifically label biomolecules in living cells. Considerable progress has been made in site-specific labeling of proteins and glycans in complex biological systems, but equivalent methods for mRNAs are rare. We present a chemo-enzymatic approach to label the 5’ cap of eukaryotic mRNAs using a bioorthogonal photoclick reaction. Herein, the N7-methylated guanosine of the 5’ cap is enzymatically equipped with an allyl group using a variant of the trimethylguanosine synthase 2 from Giardia lamblia (GlaTgs2). To elucidate whether the resulting N2-modified 5’ cap is a suitable dipolarophile for photoclick reactions, we used Kohn–Sham density functional theory (KS-DFT) and calculated the HOMO and LUMO energies of this molecule and nitrile imines. Our in silico studies suggested that combining enzymatic allylation of the cap with subsequent labeling in a photoclick reaction was feasible. This could be experimentally validated. Our approach generates a turn-on fluorophore site-specifically at the 5’ cap and therefore presents an important step towards labeling of eukaryotic mRNAs in a bioorthogonal manner.

Illuminating biological processes through site-specific protein labeling.

Coupling genetically encoded peptide tags or unnatural amino acids (UAAs) with bioorthogonal reactions allows for precise control over the protein-labeling sites as well as the wide choice of labeling dyes. However, the value of these site-specific protein labeling strategies in a real biology setting, particularly their advantages over conventional labeling methods including fluorescent proteins (FPs), remains to be fully demonstrated. In this tutorial review, we first introduce various strategies for site-specific protein labeling that utilize artificial peptide sequences or genetically encoded UAAs as the labeling handle. Emphasis will be placed on introducing the advantages of protein site-specific labeling techniques as well as their applications in solving biological problems, particularly as to why a site-specific protein labeling approach is needed. Finally, beyond the widely used single site-specific labeling methods, the recently emerged dual site-specific protein labeling strategies will be introduced together with their fast-growing potential in illustrating biological processes.

Quantitative Super-Resolution Microscopy using Novel Meditope Reagents

Pointillistic super-resolution microscopy techniques are excellent tools for quantitative interrogation of protein distribution and dynamics on a nanoscale level. To efficiently detect single molecules, proteins of interest need to be genetically tagged with optical highlighter proteins or affinity tagged with antibodies labeled with fluorescent (or caged) dyes. We leveraged advantages of both approaches by utilizing a unique peptide-binding site in the Fab framework of monoclonal antibody: the meditope [1]. In this manner we can achieve stoichiometric and site-specific labeling of endogenous proteins using meditope-enabled antibodies.We coupled a high-affinity meditope to a series of optical highlighter proteins to perform advanced photo-activated localization microscopy (PALM) imaging of human epidermal growth factor receptor 2 (Her2) on the membrane of breast cancer cell lines SK-BR-3 and BT-474. We first characterized binding and we typically obtain 10 nm resolution. Next, we used pair-correlation analysis [2] to quantitatively investigate distribution of Her2. While imaging with Fab complexes (one fluorophore/Fab) results in random distribution of Her2, imaging with Ab complexes (two fluorophores/Ab), results in mostly dimeric distribution of Her2. We anticipate that in the future our approach will provide invaluable insights on molecular dynamics and nanoscale spatial organization of growth factor receptors.[1] Donaldson, J. M., Zer, C., Avery, K. N., Bzymek, K. P., Horne, D. A., and Williams, J. C. (2013) Identification and grafting of a unique peptide-binding site in the Fab framework of monoclonal antibodies, Proc Natl Acad Sci U S A 110, 17456-17461.[2] Sengupta, P., Jovanovic-Talisman, T., Skoko, D., Renz, M., Veatch, S. L., and Lippincott-Schwartz, J. (2011) Probing protein heterogeneity in the plasma membrane using PALM and pair correlation analysis, Nat. Methods 8, 969-975.

Toward Adding Complexity in Single Molecule FRET Studies of DNA Mismatch Repair

Mistakes made during DNA replication are targeted for post-replicative repair by the DNA mismatch repair system. Purified reconstitutions of DNA mismatch repair require multiple protein interactions, and in vivo studies of DNA mismatch repair function have identified layers of spatial and temporal regulation. We have previously developed single molecule FRET experiments for studies of purified in vitro studies of DNA mismatch interactions from Thermus Aquaticus MutS and MutL. In this poster we present our recent progress developing single molecule FRET assays for more complex studies of DNA repair. In particular, we highlight our work using unnatural amino acid engineering and other methods for site-specific labeling of yeast repair proteins, detailed analysis of kinetics to reveal nucleotide regulation of protein conformations, and steps toward studies in live cells.

GFP for EM: Site-Specific Labeling of Proteins for Electron Microscopy

Structural analysis of macromolecules by electron microscopy (EM) has been facilitated by a recent technological revolution in instrumentation and data processing, which has led to the achievement of their visualization at atomic resolution. However, moderate resolution electron density maps of protein complexes can be misleading, resulting in ambiguity when ascribing subunits to particular locations within the architecture of complexes. To this end, investigators have traditionally performed subunit mapping by N- or C-terminal fusions with tags, such as maltose binding protein (MBP), with mixed success. Toward the accurate determination of the location and orientation of protein subunits, as well as large scale movements of protein complexes, the establishment of a highly specific labeling technique would be a major breakthrough. Here we present a site-specific labeling strategy that exploits a unique chemical handle introduced by the incorporation of the unnatural amino acid (UAA). The UAA permits a site-specific copper-free click reaction for labeling with a modified label, such as MBP or Nanogold. We use this method to label a subunit within the recombinant yeast proteasome lid complex that was previously not amenable to labeling by MBP fusion. This technique is extremely versatile and precise; it can be readily expanded to other organisms and to other labels, and will be useful for a wide range of structural analyses.

Identifying reactive peptides from phage-displayed libraries.

Phage display enables the synthesis, selection, and screening of large, polypeptide libraries (>1 × 10(10) different members). Selections from such libraries can identify binding partners to essentially any desired target (Sarikaya et al., Annu Rev Mater Res 34:373-408, 2004; Deutscher, Chem Rev 110:3196-3211, 2010). Peptides with affinity or reactivity to small molecule probes are attractive for numerous uses including the targeted, site-specific labeling of proteins. Here, we describe selection and screening protocols for the identification of short peptides that can selectively bind to and/or react with small molecules.

Site-specific labeling of proteins via sortase: protocols for the molecular biologist.

Creation of site-specifically labeled protein bioconjugates is an important tool for the molecular biologist and cell biologist. Chemical labeling methods, while versatile with respect to the types of moieties that can be attached, suffer from lack of specificity, often targeting multiple positions within a protein. Here we describe protocols for the chemoenzymatic labeling of proteins at the C-terminus using the bacterial transpeptidase, sortase A. We detail a protocol for the purification of an improved pentamutant variant of the Staphylococcus aureus enzyme (SrtA 5(o)) that exhibits vastly improved kinetics relative to the wild-type enzyme. Importantly, a protocol for the construction of peptide probes compatible with sortase labeling using techniques that can be adapted to any cellular/molecular biology lab with no existing infrastructure for synthetic chemistry is described. Finally, we provide an example of how to optimize the labeling reaction using the improved SrtA 5(o) variant.