Ivana Nikić

Minimal Tags for Rapid Dual‐Color Live‐Cell Labeling and Super‐Resolution Microscopy

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.

Near-infrared branding efficiently correlates light and electron microscopy

The correlation of light and electron microscopy of complex tissues remains a major challenge. Here we report near-infrared branding (NIRB), which facilitates such correlation by using a pulsed, near-infrared laser to create defined fiducial marks in three dimensions in fixed tissue. As these marks are fluorescent and can be photo-oxidized to generate electron contrast, they can guide re-identification of previously imaged structures as small as dendritic spines by electron microscopy.

Labeling proteins on live mammalian cells using click chemistry

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 hosts 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.

In vivo imaging of single axons in the mouse spinal cord

We provide a protocol that describes imaging of single fluorescently labeled axons in the spinal cord of living mice. This method takes advantage of transgenic mouse lines in which the thy1-promoter drives the expression of variants of the green fluorescent protein in a small percentage (less than 1%) of sensory neurons. As a consequence, single axons can be resolved in the surgically exposed dorsal column using wide-field epifluorescence microscopy. This approach allows direct observation of axonal degeneration and regeneration in mouse models of spinal cord pathology for several hours or repetitively over the course of several days.

Cellular, subcellular and functional in vivo labeling of the spinal cord using vital dyes.

Here we provide a protocol for rapidly labeling different cell types, distinct subcellular compartments and key injury mediators in the spinal cord of living mice. This method is based on the application of synthetic vital dyes to the surgically exposed spinal cord. Suitable vital dyes applied in appropriate concentrations lead to reliable in vivo labeling, which can be combined with genetic tags and in many cases preserved for postfixation analysis. In combination with in vivo imaging, this approach allows the direct observation of central nervous system physiology and pathophysiology at the cellular, subcellular and functional level. Surgical exposure and preparation of the spinal cord can be achieved in less than 1 h, and then dyes need to be applied for 30–60 min before the labeled spinal cord can be imaged for several hours.

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

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.

Highly Stable trans‐Cyclooctene Amino Acids for Live‐Cell Labeling

trans-Cyclooctene groups incorporated into proteins via non-canonical amino acids (ncAAs) are emerging as specific handles for bioorthogonal chemistry. Here, we present a highly improved synthetic access to the axially and the equatorially linked trans-cyclooct-2-ene isomers (1 a,b). We further show that the axially connected isomer has a half-life about 10 times higher than the equatorial isomer and reacts with tetrazines much faster, as determined by stopped-flow experiments. The improved properties resulted in different labeling performance of the insulin receptor on the surface of intact cells.

New Generation of Bioorthogonally Applicable Fluorogenic Dyes with Visible Excitations and Large Stokes Shifts

Synthesis of a set of new, azide bearing, biorthogonally applicable fluorogenic dyes with large Stokes shifts is presented herein. To assess the fluorogenic performance of these new dyes we have labeled a genetically modulated, cyclooctyne-bearing protein in lysate medium. Studies showed that the labels produce specific signal with minimal background fluorescence. We also provide theoretical insights into the design of such fluorogenic labels.

Origin of Orthogonality of Strain‐Promoted Click Reactions

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.

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

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.