Your search keyword '"Lemke, Edward A."' showing total 13 results

1. Orthogonal spin labeling using click chemistry for in vitro and in vivo applications.

Author

Kucher S, Korneev S, Tyagi S, Apfelbaum R, Grohmann D, Lemke EA, Klare JP, Steinhoff HJ, and Klose D

Subjects

Alkynes chemistry, Azides chemistry, Catalysis, Copper chemistry, Cycloaddition Reaction, Cysteine chemistry, Kinetics, Magnetic Resonance Spectroscopy, Models, Molecular, Molecular Conformation, Nitrogen Oxides chemistry, Click Chemistry methods, Electron Spin Resonance Spectroscopy methods, Spin Labels chemical synthesis

Abstract

Site-directed spin labeling for EPR- and NMR spectroscopy has mainly been achieved exploiting the specific reactivity of cysteines. For proteins with native cysteines or for in vivo applications, an alternative coupling strategy is required. In these cases click chemistry offers major benefits by providing a fast and highly selective, biocompatible reaction between azide and alkyne groups. Here, we establish click chemistry as a tool to target unnatural amino acids in vitro and in vivo using azide- and alkyne-functionalized spin labels. The approach is compatible with a variety of labels including reduction-sensitive nitroxides. Comparing spin labeling efficiencies from the copper-free with the strongly reducing copper(I)-catalyzed azide-alkyne click reaction, we find that the faster kinetics for the catalyzed reaction outrun reduction of the labile nitroxide spin labels and allow quantitative labeling yields within short reaction times. Inter-spin distance measurements demonstrate that the novel side chain is suitable for paramagnetic NMR- or EPR-based conformational studies of macromolecular complexes., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2017

2. Super-resolution Microscopy of Clickable Amino Acids Reveals the Effects of Fluorescent Protein Tagging on Protein Assemblies.

Author

Vreja IC, Nikić I, Göttfert F, Bates M, Kröhnert K, Outeiro TF, Hell SW, Lemke EA, and Rizzoli SO

Subjects

Transfection, Amino Acids chemistry, Click Chemistry methods, Fluorescent Dyes chemistry, Luminescent Proteins chemistry, Microscopy, Fluorescence methods

Abstract

The advent of super-resolution microscopy (nanoscopy) has set high standards for fluorescence tagging. Fluorescent proteins (FPs) are convenient tags in conventional imaging, but their use in nanoscopy has been questioned due to their relatively large size and propensity to form multimers. Here, we compared the nanoscale organization of proteins with or without FP tags by introducing the unnatural amino acid propargyl-L-lysine (PRK) in 26 proteins known to form multimolecular arrangements and into their FP-tagged variants. We revealed the proteins by coupling synthetic fluorophores to PRK via click chemistry and visualized them using ground-state depletion microscopy followed by individual molecule return, as well as stimulated emission depletion microscopy. The arrangements formed by the FP-tagged and nontagged proteins were similar. Mild, but statistically significant differences were observed for only six proteins (23% of all proteins tested). This suggests that FP-based nanoscopy is generally reliable. Unnatural amino acids should be a reliable alternative for the few proteins that are sensitive to FP tagging.

Published

2015

3. Genetic code expansion enabled site-specific dual-color protein labeling: superresolution microscopy and beyond.

Author

Nikić I and Lemke EA

Subjects

Amino Acids genetics, Animals, Genetic Code, Humans, Immunoconjugates analysis, Immunoconjugates genetics, Models, Molecular, Proteins genetics, Viral Proteins analysis, Viral Proteins genetics, Viruses genetics, Viruses isolation & purification, Amino Acids chemistry, Click Chemistry methods, Fluorescent Dyes chemistry, Microscopy, Fluorescence methods, Protein Engineering methods, Proteins analysis

Abstract

Genetic code expansion is emerging as an important tool for manipulation and labeling of proteins in vitro and in vivo. In combination with click-chemistry it allows site-specific labeling of target proteins with small organic fluorophores. This is achieved by cotranslational incorporation of noncanonical amino acids (ncAAs) in target proteins via orthogonal tRNA/amino-acyl tRNA synthetase pairs. In a subsequent step, ncAAs are labeled with small dyes via click-chemistry. Small labeling tags and free choice of which fluorophore to use and where to put it into the protein are of particular importance for single molecule science and superresolution microscopy. Such genetically encoded click chemistry tools facilitate high resolution studies of protein function in live cells, viral imaging, as well as the improved design of antibody-drug conjugates., (Copyright © 2015 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2015

4. Labeling proteins on live mammalian cells using click chemistry.

Author

Nikić I, Kang JH, Girona GE, Aramburu IV, and Lemke EA

Subjects

Alkynes chemistry, Amino Acyl-tRNA Synthetases genetics, Amino Acyl-tRNA Synthetases metabolism, Animals, Azides chemistry, Carbocyanines chemistry, Click Chemistry instrumentation, Codon, Terminator, Cycloaddition Reaction, Green Fluorescent Proteins genetics, HEK293 Cells, Humans, Mammals, Mutagenesis, Site-Directed, Proteins genetics, Receptor, Insulin chemistry, Receptor, Insulin genetics, Amino Acids chemistry, Click Chemistry methods, Fluorescent Dyes chemistry, Proteins chemistry

Abstract

We describe a protocol for the rapid labeling of cell-surface proteins in living mammalian cells using click chemistry. The labeling method is based on strain-promoted alkyne-azide cycloaddition (SPAAC) and strain-promoted inverse-electron-demand Diels-Alder cycloaddition (SPIEDAC) reactions, in which noncanonical amino acids (ncAAs) bearing ring-strained alkynes or alkenes react, respectively, with dyes containing azide or tetrazine groups. To introduce ncAAs site specifically into a protein of interest (POI), we use genetic code expansion technology. The protocol can be described as comprising two steps. In the first step, an Amber stop codon is introduced--by site-directed mutagenesis--at the desired site on the gene encoding the POI. This plasmid is then transfected into mammalian cells, along with another plasmid that encodes an aminoacyl-tRNA synthetase/tRNA (RS/tRNA) pair that is orthogonal to the host's translational machinery. In the presence of the ncAA, the orthogonal RS/tRNA pair specifically suppresses the Amber codon by incorporating the ncAA into the polypeptide chain of the POI. In the second step, the expressed POI is labeled with a suitably reactive dye derivative that is directly supplied to the growth medium. We provide a detailed protocol for using commercially available ncAAs and dyes for labeling the insulin receptor, and we discuss the optimal surface-labeling conditions and the limitations of labeling living mammalian cells. The protocol involves an initial cloning step that can take 4-7 d, followed by the described transfections and labeling reaction steps, which can take 3-4 d.

Published

2015

5. Genetically encoded click chemistry for single-molecule FRET of proteins.

Author

Tyagi S and Lemke EA

Subjects

Amino Acid Substitution, Escherichia coli, Fenofibrate, Fluorescent Dyes chemistry, Genetic Vectors, Lysine chemistry, Maleimides chemistry, Muramidase biosynthesis, Muramidase chemistry, Muramidase genetics, Mutagenesis, Site-Directed, Recombinant Proteins biosynthesis, Recombinant Proteins chemistry, Recombinant Proteins genetics, Staining and Labeling, Viral Proteins biosynthesis, Viral Proteins chemistry, Viral Proteins genetics, Click Chemistry, Fluorescence Resonance Energy Transfer, Lysine analogs & derivatives, Lysine chemical synthesis, Proteins chemistry

Abstract

Single molecule Fluorescence Resonance Energy Transfer (FRET) has been widely applied to study structure, function and dynamics of complex biological systems. Labeling of proteins at specific positions with fluorescent dyes is a challenging and key step for any single molecule FRET measurement. Genetic code expansion has facilitated site specific incorporation of unnatural amino acids into proteins. These unnatural amino acid bears bioorthognal functional groups that provide opportunity to install a unique chemical handle into proteins. Propargyllysine is an unnatural amino acid which, when incorporated into a protein, can be exploited to attach commercially available fluorescent azide dyes through copper-catalyzed alkyne-azide cycloaddition click reaction (also known as click reaction). We describe here an optimized strategy to combine synthesis of propargyllysine, its genetic incorporation in the protein and click reaction to site-specifically label the protein with azide derivative of Alexa® 488. Later the protein is labeled at unique cysteine residue via maleimide coupling chemistry with acceptor Alexa® 594 dye to yield double labeled protein as required for any single molecule FRET experiments., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

6. Potential vs Challenges of Expanding the Protein Universe With Genetic Code Expansion in Eukaryotic Cells.

Author

Bhattacharjee, Rajanya and Lemke, Edward A.

Subjects

*AMINO acid separation, *GENETIC code, *EUKARYOTIC cells, *CLICK chemistry, *EXPANDING universe

Abstract

[Display omitted] • Summary of immense potential of genetic code expansion in eukaryotes • Discussion of strategies for mitigating limitations of genetic code expansion • Pitfalls of genetic code expansion enabled in vivo click-labelling with fluorophores Following decades of innovation and perfecting, genetic code expansion has become a powerful tool for in vivo protein modification. Some of the major hurdles that had to be overcome include suboptimal performance of GCE-specific translational components in host systems, competing cellular processes, unspecific modification of the host proteome and limited availability of codons for reassignment. Although strategies have been developed to overcome these challenges, there is critical need for further advances. Here we discuss the current state-of-the-art in genetic code expansion technology and the issues that still need to be addressed to unleash the full potential of this method in eukaryotic cells. [ABSTRACT FROM AUTHOR]

Published

2024

7. Synthesis and Evaluation of Novel Ring‐Strained Noncanonical Amino Acids for Residue‐Specific Bioorthogonal Reactions in Living Cells.

Author

Reinkemeier, Christopher D., Koehler, Christine, Sauter, Paul F., Shymanska, Nataliia V., Echalier, Cecile, Rutkowska, Anna, Will, David W., Schultz, Carsten, and Lemke, Edward A.

Subjects

AMINO acids, GENETIC code, CHEMICAL kinetics, FLOW cytometry

Abstract

Bioorthogonal reactions are ideally suited to selectively modify proteins in complex environments, even in vivo. Kinetics and product stability of these reactions are crucial parameters to evaluate their usefulness for specific applications. Strain promoted inverse electron demand Diels–Alder cycloadditions (SPIEDAC) between tetrazines and strained alkenes or alkynes are particularly popular, as they allow ultrafast labeling inside cells. In combination with genetic code expansion (GCE)‐a method that allows to incorporate noncanonical amino acids (ncAAs) site‐specifically into proteins in vivo. These reactions enable residue‐specific fluorophore attachment to proteins in living mammalian cells. Several SPIEDAC capable ncAAs have been presented and studied under diverse conditions, revealing different instabilities ranging from educt decomposition to product loss due to β‐elimination. To identify which compounds yield the best labeling inside living mammalian cells has frequently been difficult. In this study we present a) the synthesis of four new SPIEDAC reactive ncAAs that cannot undergo β‐elimination and b) a fluorescence flow cytometry based FRET‐assay to measure reaction kinetics inside living cells. Our results, which at first sight can be seen conflicting with some other studies, capture GCE‐specific experimental conditions, such as long‐term exposure of the ring‐strained ncAA to living cells, that are not taken into account in other assays. [ABSTRACT FROM AUTHOR]

Published

2021

8. Debugging Eukaryotic Genetic Code Expansion for Site-Specific Click-PAINT Super-Resolution Microscopy.

Author

Nikić, Ivana, Estrada Girona, Gemma, Kang, Jun Hee, Paci, Giulia, Mikhaleva, Sofya, Koehler, Christine, Shymanska, Nataliia V., Ventura Santos, Camilla, Spitz, Daniel, and Lemke, Edward A.

Subjects

HIGH resolution imaging, AMINO acid analysis, DNA analysis, GENETIC code, EUKARYOTE phylogeny

Abstract

Super-resolution microscopy (SRM) greatly benefits from the ability to install small photostable fluorescent labels into proteins. Genetic code expansion (GCE) technology addresses this demand, allowing the introduction of small labeling sites, in the form of uniquely reactive noncanonical amino acids (ncAAs), at any residue in a target protein. However, low incorporation efficiency of ncAAs and high background fluorescence limit its current SRM applications. Redirecting the subcellular localization of the pyrrolysine-based GCE system for click chemistry, combined with DNA-PAINT microscopy, enables the visualization of even low-abundance proteins inside mammalian cells. This approach links a versatile, biocompatible, and potentially unbleachable labeling method with residue-specific precision. Moreover, our reengineered GCE system eliminates untargeted background fluorescence and substantially boosts the expression yield, which is of general interest for enhanced protein engineering in eukaryotes using GCE. [ABSTRACT FROM AUTHOR]

Published

2016

9. Origin of Orthogonality of Strain-Promoted Click Reactions.

Author

Wagner, Johannes A., Mercadante, Davide, Nikić, Ivana, Lemke, Edward A., and Gräter, Frauke

Subjects

RING formation (Chemistry), AZIDES, TETRAZINE, OCTENE, CLICK chemistry, BIOMOLECULES, QUANTUM chemistry, BIOCHEMICAL substrates

Abstract

Site-specific labeling of biomolecules is rapidly advancing due to the discovery of novel mutually orthogonal reactions. Quantum chemistry studies have also increased our understanding of their relative rates, although these have until now been based on highly simplified reactants. Here we examine a set of strain-promoted click-type cycloaddition reactions of n-propyl azide, 3-benzyl tetrazine and 3-benzyl-6-methyl tetrazine with cyclooctenes/ynes, in which we aim to address all relevant structural details of the reactants. Our calculations have included the obligatory handles used to attach the label and biomolecule as these can critically influence the stereochemistry and electron demand of the reaction. We systematically computed orbital gaps, activation and distortion energies using density functional theory and determined experimental rates for validation. Our results challenge the current paradigm of the inverse electron demand for this class of reactions. We found that the ubiquitous handles, when next to the triple bond of cyclooctynes, can switch the Diels-Alder type ligations to normal electron demand, a class we term as SPINEDAC reactions. Electron donating substituents on tetrazine can enhance normal demand but also increase distortion penalties. The presence and isomeric configuration of handles thus determine the reaction speed and regioselectivity. Our findings can be directly utilized in engineering genuine cycloaddition click chemistries for biological labeling. [ABSTRACT FROM AUTHOR]

Published

2015

10. Minimal Tags for Rapid Dual-Color Live-Cell Labeling and Super-Resolution Microscopy.

Author

Nikić, Ivana, Plass, Tilman, Schraidt, Oliver, Szymański, Jędrzej, Briggs, John A. G., Schultz, Carsten, and Lemke, Edward A.

Subjects

AMINO acids, MAMMALIAN cell cycle, BIOCOMPATIBILITY, DIELS-Alder reaction, TETRAZINE

Abstract

The growing demands of advanced fluorescence and super-resolution microscopy benefit from the development of small and highly photostable fluorescent probes. Techniques developed to expand the genetic code permit the residue-specific encoding of unnatural amino acids (UAAs) armed with novel clickable chemical handles into proteins in living cells. Here we present the design of new UAAs bearing strained alkene side chains that have improved biocompatibility and stability for the attachment of tetrazine-functionalized organic dyes by the inverse-electron-demand Diels-Alder cycloaddition (SPIEDAC). Furthermore, we fine-tuned the SPIEDAC click reaction to obtain an orthogonal variant for rapid protein labeling which we termed selectivity enhanced (se) SPIEDAC. seSPIEDAC and SPIEDAC were combined for the rapid labeling of live mammalian cells with two different fluorescent probes. We demonstrate the strength of our method by visualizing insulin receptors (IRs) and virus-like particles (VLPs) with dual-color super-resolution microscopy. [ABSTRACT FROM AUTHOR]

Published

2014

11. Click Strategies for Single-Molecule Protein Fluorescence.

Author

Neal, Adrian P. and Lemke, Edward A.

Subjects

*SINGLE molecule research, *CLICK chemistry, *FLUORESCENCE resonance energy transfer, *MOLECULAR structure, *MOLECULAR dynamics, *BIOMIMETIC chemicals, *AMINO acids, *FLUORESCENT dyes

Abstract

Single-molecule methods have matured into central tools for studies in biology. Foerster resonance energy transfer (FRET) techniques, in particular, have been widely applied to study biomolecular structure and dynamics. The major bottleneck for a facile and general application of these studies arises from the need to label biological samples site-specifically with suitable fluorescent dyes. In this work, we present an optimized strategy combining click chemistry and the genetic encoding of unnatural amino acids (UAAs) to overcome this limitation for proteins. We performed a systematic study with a variety of clickable UAAs and explored their potential for high-resolution single-molecule FRET (smFRET). We determined all parameters that are essential for successful single-molecule studies, such as accessibility of the probes, expression yield of proteins, and quantitative labeling. Our multiparameter fluorescence analysis allowed us to gain new insights into the effects and photophysical properties of fluorescent dyes linked to various UAAs for smFRET measurements. This led us to determine that, from the extended tool set that we now present, genetically encoding propargyllysine has major advantages for state-of-the-art measurements compared to other UAAs. Using this optimized system, we present a biocompatible one-step dual-labeling strategy of the regulatory protein RanBP3 with full labeling position freedom. Our technique allowed us then to determine that the region encompassing two FxFG repeat sequences adopts a disordered but collapsed state. RanBP3 serves here as a prototypical protein that, due to its multiple cysteines, size, and partially disordered structure, is not readily accessible to any of the typical structure determination techniques such as smFRET, NMR, and X-ray crystallography. [ABSTRACT FROM AUTHOR]

Published

2012

12. Cover Picture: Debugging Eukaryotic Genetic Code Expansion for Site-Specific Click-PAINT Super-Resolution Microscopy (Angew. Chem. Int. Ed. 52/2016).

Author

Nikić, Ivana, Estrada Girona, Gemma, Kang, Jun Hee, Paci, Giulia, Mikhaleva, Sofya, Koehler, Christine, Shymanska, Nataliia V., Ventura Santos, Camilla, Spitz, Daniel, and Lemke, Edward A.

Subjects

CHEMISTRY periodicals, GENETIC code, MAGAZINE covers

Abstract

The cover page of the journal "Angewandte Chemie" is presented.

Published

2016

13. Bioorthogonal click labeling of an amber-free HIV-1 provirus for in-virus single molecule imaging.

Author

Ao, Yuanyun, Grover, Jonathan R., Gifford, Levi, Han, Yang, Zhong, Guohua, Katte, Revansiddha, Li, Wenwei, Bhattacharjee, Rajanya, Zhang, Baoshan, Sauve, Stephanie, Qin, Wenyi, Ghimire, Dibya, Haque, Md Anzarul, Arthos, James, Moradi, Mahmoud, Mothes, Walther, Lemke, Edward A., Kwong, Peter D., Melikyan, Gregory B., and Lu, Maolin

Subjects

*SINGLE molecules, *FLUORESCENCE resonance energy transfer, *SPIN labels, *HIV, *GENETIC code, *STRUCTURAL dynamics, *CLICK chemistry

Abstract

Structural dynamics of human immunodeficiency virus 1 (HIV-1) envelope (Env) glycoprotein mediate cell entry and facilitate immune evasion. Single-molecule FRET using peptides for Env labeling revealed structural dynamics of Env, but peptide use risks potential effects on structural integrity/dynamics. While incorporating noncanonical amino acids (ncAAs) into Env by amber stop-codon suppression, followed by click chemistry, offers a minimally invasive approach, this has proved to be technically challenging for HIV-1. Here, we develope an intact amber-free HIV-1 system that overcomes hurdles of preexisting viral amber codons. We achieved dual-ncAA incorporation into Env on amber-free virions, enabling single-molecule Förster resonance energy transfer (smFRET) studies of click-labeled Env that validated the previous peptide-based labeling approaches by confirming the intrinsic propensity of Env to dynamically sample multiple conformational states. Amber-free click-labeled Env also enabled real-time tracking of single virion internalization and trafficking in cells. Our system thus permits in-virus bioorthogonal labeling of proteins, compatible with studies of virus entry, trafficking, and egress from cells. [Display omitted] • We constructed an intact amber-free HIV-1 provirus for in-virus click labeling • System enables dual-ncAA insertion for biorthogonal click labeling on intact virions • smFRET of Env reinforced its structural dynamics observed via conventional labeling • Live cell imaging tracked amber-free click-labeled Env virions in cells Ao et al. developed an intact amber-free HIV-1 system that enables minimally invasive Env tagging by genetic code expansion and in-virus bioorthogonal click labeling for single-molecule FRET structural dynamics and advanced microscopy studies of virus entry, trafficking, and egress in living cells. [ABSTRACT FROM AUTHOR]

Published

2024