Examining the Conformational Dynamics of Membrane Proteins in situ with Site-directed Fluorescence Labeling

Two electrode voltage clamp electrophysiology (TEVC) is a powerful tool to investigate the mechanism of ion transport1 for a wide variety of membrane proteins including ion channels², ion pumps³, and transporters⁴. Recent developments have combined site-specific fluorophore labeling alongside TEVC to concurrently examine the conformational dynamics at specific residues and function of these proteins on the surface of single cells.We will describe a method to study the conformational dynamics of membrane proteins by simultaneously monitoring fluorescence and current changes using voltage-clamp fluorometry. This approach can be used to examine the molecular motion of membrane proteins site-specifically following cysteine replacement and site-directed fluorophore labeling^5,6. Furthermore, this method provides an approach to determine distance constraints between specific residues^7,8. This is achieved by selectively attaching donor and acceptor fluorophores to two mutated cysteine residues of interest.In brief, these experiments are performed following functional expression of the desired protein on the surface of Xenopus leavis oocytes. The large surface area of these oocytes enables facile functional measurements and a robust fluorescence signal⁵. It is also possible to readily change the extracellular conditions such as pH, ligand or cations/anions, which can provide further information on the mechanism of membrane proteins⁴. Finally, recent developments have also enabled the manipulation of select internal ions following co-expression with a second protein⁹.Our protocol is described in multiple parts. First, cysteine scanning mutagenesis proceeded by fluorophore labeling is completed at residues located at the interface of the transmembrane and extracellular domains. Subsequent experiments are designed to identify residues which demonstrate large changes in fluorescence intensity (<5%)³ upon a conformational change of the protein. Second, these changes in fluorescence intensity are compared to the kinetic parameters of the membrane protein in order to correlate the conformational dynamics to the function of the protein¹⁰. This enables a rigorous biophysical analysis of the molecular motion of the target protein. Lastly, two residues of the holoenzyme can be labeled with a donor and acceptor fluorophore in order to determine distance constraints using donor photodestruction methods. It is also possible to monitor the relative movement of protein subunits following labeling with a donor and acceptor fluorophore.     

Cellular uptake and distribution of cobalt complexes of fluorescent ligands

The development of complexes that allow the monitoring of the release and distribution of fluorescent models of anticancer drugs initially bound to cobalt(III) moieties is reported. Strong quenching of fluorescence upon ligation to cobalt(III) was observed for both the carboxylate- and the hydroximate-bound fluorophores as was the partial return of fluorescence following addition of ascorbate and cysteine. The extent of the increase in the fluorescence intensity observed following addition of these potential reductants is indicative of the fluorophore being displaced from the complex by the action of ascorbate or cysteine, by ligand exchange. The cellular distribution of the fluorescence revealed that coordination to cobalt can dramatically alter the subcellular distribution of a bound fluorophore. This work shows that fluorescence can be an effective means of monitoring these agents in cells, and of determining their sites of activation. The results also reveal that the cytotoxicity of such agents correlates with their uptake and distribution patterns and that these are influenced by the types of ligands attached to the complex.     

Sequential ordering among multicolor fluorophores for protein labeling facility via aggregation-elimination based β-lactam probes

Development of protein labeling techniques with small molecules is enthralling because this method brings promises for triumph over the limitations of fluorescent proteins in live cell imaging. This technology deals with the functionalization of proteins with small molecules and is anticipated to facilitate the expansion of various protein assay methods. A new straightforward aggregation and elimination-based technique for a protein labeling system has been developed with a versatile emissive range of fluorophores. These fluorophores have been applied to show their efficiency for protein labeling by exploiting the same basic principle. A genetically modified version of class A type β-lactamase has been used as the tag protein (BL-tag). The strength of the aggregation interaction between a fluorophore and a quencher plays a governing role in the elimination step of the quencher from the probes, which ultimately controls the swiftness of the protein labeling strategy. Modulation in the elimination process can be accomplished by the variation in the nature of the fluorophore. This diversity facilitates the study of the competitive binding order among the synthesized probes toward the BL-tag labeling method. An aggregation and elimination-based BL-tag technique has been explored to develop an order of color labeling from the equimolar mixture of the labeling probe in solutions. The qualitative and quantitative determination of ordering within the probes toward labeling studies has been executed through SDS-PAGE and time-dependent fluorescence intensity enhancement measurements, respectively. The desirable multiple-wavelength fluorescence labeling probes for the BL-tag technology have been developed and demonstrate broad applicability of this labeling technology to live cell imaging with coumarin and fluorescein derivatives by using confocal microscopy.     

Fluorescence labeling, purification, and immobilization of a double cysteine mutant calmodulin fusion protein for single-molecule experiments

We present a method of labeling and immobilizing a low-molecular-weight protein, calmodulin (CaM), by fusion to a larger protein, maltose binding protein (MBP), for single-molecule fluorescence experiments. Immobilization in an agarose gel matrix eliminates potential interactions of the protein and the fluorophore(s) with a glass surface and allows prolonged monitoring of protein dynamics. The small size of CaM hinders its immobilization in low-weight-percentage agarose gels; however, fusion of CaM to MBP via a flexible linker provides sufficient restriction of translational mobility in 1% agarose gels. Cysteine residues were engineered into MBP.CaM (MBP-T34C,T110C-CaM) and labeled with donor and acceptor fluorescent probes yielding a construct (MBP.CaM-DA) which can be used for single-molecule single-pair fluorescence resonance energy transfer (spFRET) experiments. Mass spectrometry was used to verify the mass of MBP.CaM-DA. Assays measuring the activity of CaM reveal minimal activity differences between wild-type CaM and MBP.CaM-DA. Single-molecule fluorescence images of the donor and acceptor dyes were fit to a two-dimensional Gaussian function to demonstrate colocalization of donor and acceptor dyes. FRET is demonstrated both in bulk fluorescence spectra and in fluorescence trajectories of single MBP.CaM-DA molecules. The extension of this method to other biomolecules is also proposed.     

Detection of local polarity of alpha-lactalbumin by N-terminal specific labeling with a new tailor-made fluorescent probe

To detect the local polarity such as the N-terminal domain of a protein molecule, 3-(4-chloro-6-hydrazino-1,3,5-triazinylamino)-7-(dimethylamino)-2-methylphenazine has been designed and synthesized as a polarity-sensitive fluorescent probe by using an s-triazine ring as a backbone, neutral red and hydrazine as a polarity-sensitive fluorophore, and a labeling group, respectively. The fluorescence properties of the probe have been characterized. The probe has the following features: (1) stable in various solvents; (2) the long-wavelength emission of >550 nm that can avoid the interferences of the background fluorescence shorter than 500 nm from common biomacromolecules; and (3) the maximum emission wavelength (lambda(em)) sensitive to solvent polarity only but not to pH and temperature. The hydrazino group in such a probe reacts readily with an active carbonyl produced by transamination of a protein molecule, leading to N-terminal specific attachment of the fluorophore and thereby allowing the monitoring of local polarity. With this probe, the polarity of the N-terminal domain in both native and heat-denatured alpha-lactalbumin has been first determined, which corresponds to that with a dielectric constant of about 16, and the hydrophobic core near the N-terminus is found to be conservative for heating. The present strategy may provide a general method to study the local environmental changes of a protein molecule under different denaturation conditions.     

A fluorescence-microscopic and cytofluorometric system for monitoring the turnover of the autophagic substrate p62/SQSTM1

Autophagic flux can be measured by determining the declining abundance of autophagic substrates such as sequestosome 1 (SQSTM1, better known as p62), which is sequestered in autophagosomes upon its direct interaction with LC3. However, the total amount of p62 results from two opposed processes, namely its synthesis (which can be modulated by some cellular stressors including autophagy inducers) and its degradation. To avoid this problem, we generated a stable cell line expressing a chimeric protein composed by p62 and the HaloTag (?) protein, which serves as a receptor for fluorescent HaloTag (?) ligands. Upon labeling with HaloTag (?) ligands (which form covalent, near-to-undissociable bonds with the Halotag (?) receptor) and washing, the resulting fluorescent labeling is not influenced by de novo protein synthesis, therefore allowing for the specific monitoring of the fusion protein decline without any interference by protein synthesis. We demonstrate that a HaloTag (?) -p62 fusion protein stably expressed in suitable cell lines can be used to monitor autophagy by flow cytometry and automated fluorescence microscopy. We surmise that this system could be adapted to high-throughput applications.     

Simple one-pot preparation of water-soluble, cysteine-reactive cyanine and merocyanine dyes for biological imaging

A simple one-pot-procedure for preparation of protein-reactive, water-soluble merocyanine and cyanine dyes has been developed. The 1-(3-ammoniopropyl)-2,3,3-trimethyl-3H-indolium-5-sulfonate bromide (1) was used as a common starting intermediate. The method allows easy preparation of dyes with chloro- and iodoacetamide side chains for covalent attachment to cysteine. By placing a sulfonato group directly on the dye fluorophore system, dyes with high fluorescence quantum yields in water were generated. Both iodo- and chloroacetamido derivatives were shown to be useful in protein labeling. Less reactive chloroacetamides will be preferential for selective labeling of the most reactive cysteines.     

The citrate carrier CitS probed by single-molecule fluorescence spectroscopy

A prominent region of the Na(+)-dependent citrate carrier (CitS) from Klebsiella pneumoniae is the highly conserved loop X-XI, which contains a putative citrate binding site. To monitor potential conformational changes within this region by single-molecule fluorescence spectroscopy, the target cysteines C398 and C414 of the single-Cys mutants (CitS-sC398, CitS-sC414) were selectively labeled with the thiol-reactive fluorophores AlexaFluor 546/568 C(5) maleimide (AF(546), AF(568)). While both single-cysteine mutants were catalytically active citrate carriers, labeling with the fluorophore was only tolerated at C398. Upon citrate addition to the functional protein fluorophore conjugate CitS-sC398-AF(546), complete fluorescence quenching of the majority of molecules was observed, indicating a citrate-induced conformational change of the fluorophore-containing domain of CitS. This quenching was specific for the physiological substrate citrate and therefore most likely reflecting a conformational change in the citrate transport mechanism. Single-molecule studies with dual-labeled CitS-sC398-AF(546/568) and dual-color detection provided strong evidence for a homodimeric association of CitS.     

Stability, specificity and fluorescence brightness of multiply-labeled fluorescent DNA probes.

In this work, we studied the fluorescence and hybridization of multiply-labeled DNA probes which have the hydrophilic fluorophore 1-(straightepsilon-carboxypentynyl)-1'-ethyl- 3,3,3', 3'-tetramethylindocarbocyanine-5,5'-disulfonate (Cy3) attached via either a short or long linker at the C-5 position of deoxyuridine. We describe the effects of labeling density, fluorophore charge and linker length upon five properties of the probe: fluorescence intensity, the change in fluorescence upon duplex formation, the quantum yield of fluorescence (Phif), probe-target stability and specificity. For the hydrophilic dye Cy3, we have demonstrated that the fluorescence intensity andPhifare maximized when labeling every 6th base using the long linker. With a less hydrophilic dye, a labeling density this high could not be achieved without serious quenching of the fluorescence. The target specificity of multiply-labeled DNA probes was just as high as compared to the unmodified control probe, however, a less stable probe-target duplex is formed that exhibits a lower melting temperature. A mechanism that accounts for this destabilization is proposed which is consistent with our data. It involves dye-dye and dye-nucleotide interactions which appear to stabilize a single-stranded conformation of the probe.     

Single-Molecule Imaging at High Fluorophore Concentrations by Local Activation of Dye

Single-molecule fluorescence microscopy is a powerful tool for observing biomolecular interactions with high spatial and temporal resolution. Detecting fluorescent signals from individual labeled proteins above high levels of background fluorescence remains challenging, however. For this reason, the concentrations of labeled proteins in in vitro assays are often kept low compared to their in vivo concentrations. Here, we present a new fluorescence imaging technique by which single fluorescent molecules can be observed in real time at high, physiologically relevant concentrations. The technique requires a protein and its macromolecular substrate to be labeled each with a different fluorophore. Making use of short-distance energy-transfer mechanisms, only the fluorescence from those proteins that bind to their substrate is activated. This approach is demonstrated by labeling a DNA substrate with an intercalating stain, exciting the stain, and using energy transfer from the stain to activate the fluorescence of only those labeled DNA-binding proteins bound to the DNA. Such an experimental design allowed us to observe the sequence-independent interaction of Cy5-labeled interferon-inducible protein 16 with DNA and the sliding via one-dimensional diffusion of Cy5-labeled adenovirus protease on DNA in the presence of a background of hundreds of nanomolar Cy5 fluorophore.     

Analysis of allosteric signal transduction mechanisms in an engineered fluorescent maltose biosensor

We previously reported the construction of a family of reagentless fluorescent biosensor proteins by the structure-based design of conjugation sites for a single, environmentally sensitive small molecule dye, thus providing a mechanism for the transduction of ligand-induced conformational changes into a macroscopic fluorescence observable. Here we investigate the microscopic mechanisms that may be responsible for the macroscopic fluorescent changes in such Fluorescent Allosteric Signal Transduction (FAST) proteins. As case studies, we selected three individual cysteine mutations (F92C, D95C, and S233C) of Escherichia coli maltose binding protein (MBP) covalently labeled with a single small molecule fluorescent probe, N-((2-iodoacetoxy)ethyl)-N-methyl)amino-7-nitrobenz-2-oxa-1,3-diazole (NBD), each giving rise to a robust FAST protein with a distinct maltose-dependent fluorescence response. The fluorescence emission intensity, anisotropy, lifetime, and iodide-dependent fluorescence quenching were determined for each conjugate in the presence and absence of maltose. Structure-derived solvent accessible surface areas of the three FAST proteins are consistent with experimentally observed quenching data. The D95C protein exhibits the largest fluorescence change upon maltose binding. This mutant was selected for further characterization, and residues surrounding the fluorophore coupling site were mutagenized. Analysis of the resulting mutant FAST proteins suggests that specific hydrogen-bonding interactions between the fluorophore molecule and two tyrosine side-chains, Tyr171 and Tyr176, in the open state but not the closed, are responsible for the dramatic fluorescence response of this construct. Taken together these results provide insights that can be used in future design cycles to construct fluorescent biosensors that optimize signaling by engineering specific hydrogen bonds between a fluorophore and protein.     

Development of a fluorogenic sensor for activated Cdc42

Cdc42, a member of the Rho GTPase family, is a fundamental regulator of the actin cytoskeleton during cell migration. To generate a sensor for Cdc42 activation, we employed a multi-pronged approach, utilizing cysteine labeling and expressed protein ligation, to incorporate the environment sensitive fluorophore 4-N,N-dimethylamino-1,8-naphthalimide (4-DMN) into the GTPase binding domain of the WASP protein. These constructs bind only the active, GTP-bound conformation of Cdc42 to produce a fluorescence signal. Studies with a panel of five sensor analogs revealed a derivative that exhibits a 32-fold increase in fluorescence intensity in the presence of activated Cdc42 compared to incubation with the inactive GDP-bound form of the protein. We demonstrate that this sensor can be exploited to monitor Cdc42 nucleotide exchange and GTPase activity in a continuous, fluorescence assay.     

Fluorescence-intensity multiplexing: simultaneous seven-marker, two-color immunophenotyping using flow cytometry.

BACKGROUND: Conventional immuno-based multiparameter flow cytometric analysis has been limited by the requirement of a dedicated detection channel for each antibody-fluorophore set. To address the need to resolve multiple biological targets simultaneously, flow cytometers with as many as 10-15 detection channels have been developed. In this study, a new Zenon immunolabeling technology is developed that allows for multiple antigen detection per detection channel using a single fluorophore, through a unique method of fluorescence-intensity multiplexing. By varying the Zenon labeling reagent-to-antibody molar ratio, the fluorescence intensity of the antibody-labeled cellular targets can be used as a unique identifier. Although demonstrated in the present study with lymphocyte immunophenotyping, this approach is broadly applicable for any immuno-based multiplexed flow cytomety assay. METHODS: Lymphocyte immunophenotyping of 38 clinical blood specimens using CD3, CD4, CD8, CD16, CD56, CD19, and CD20 antibodies was performed using conventional flow cytometric analysis and fluorescence-intensity multiplexing analysis. Conventional analysis measures a single antibody-fluorophore per photomultiplier tube (PMT). Fluorescence-intensity multiplex analysis simultaneously measures seven markers with two PMTs, using Zenon labeling reagent-antibody complexes in a single tube: CD19, CD4, CD8, and CD16 antibodies labeled with Zenon Alexa Fluor 488 Mouse IgG(1) labeling reagent and CD56, CD3, and CD20 antibodies labeled with Zenon R-Phycoerythrin (R-PE) Mouse IgG(1) or IgG(2b) labeling reagents. RESULTS: The lymphocyte immunophenotyping results from fluorescence-intensity multiplexing using Zenon labeling reagents in a single tube were comparable to results from conventional flow cytometric analysis. CONCLUSIONS: Simultaneous evaluation of multiple antigens using a single fluorophore can be performed using antibodies labeled with varying ratios of a Zenon labeling reagent. Labeling two sets of antibodies with different Zenon labeling reagents can generate characteristic and distinguishable multivariate patterns. Combining multiple antibodies and fluorescent labels with fluorescence intensity multiplexing enables the resolution of more cellular targets than detection-channels, allowing sophisticated multiparameter flow cytometric studies to be performed on less complex 2- or 3-detection-channel flow cytometers. For typical biological samples, approximately 2-4 cellular targets per detection channel can be resolved using this technique.     

Monitoring receptor-mediated activation of heterotrimeric G-proteins by fluorescence resonance energy transfer

Green fluorescent protein (GFP)-centered fluorescence resonance energy transfer (FRET) relies on a distance-dependent transfer of energy from a donor fluorophore to an acceptor fluorophore and can be used to examine protein interactions in living cells. Here we describe a method to monitor the association and disassociation of heterotrimeric GTP-binding (G-proteins) from one another before and after stimulation of coupled receptors in living Dictyostelium discoideum cells. The Galpha(2)and Gbetagamma proteins were tagged with cyan and yellow fluorescent proteins and used to observe the state of the G-protein heterotrimer. Data from emission spectra were used to detect the FRET fluorescence and to determine kinetics and dose-response curves of bound ligand and analogs. Extending G-protein FRET to mammalian G-proteins should enable direct in situ mechanistic studies and applications such as drug screening and identifying ligands of new G-protein-coupled receptors.     

Regioselective fluorescent labeling of N,N,N-trimethyl chitosan via oxime formation

Fluorescent labeling of chitosan and its derivatives is widely used for in vitro visualization and is accomplished by random introduction of the fluorophore to the polymer backbone, conceivably altering the bioactivity of the polymer. Here, we report for the first time the regioselective conjugation of a fluorophore to the reducing end of a fully N,N,N-trimethylated chitosan (TMC) by oxime formation. End-labeled conjugation of 5-(2-((aminooxyacetyl)amino)ethylamino)naphthalene-1-sulfonic acid (EDANS-O-NH(2)) fluorophore to TMC to form TMC-oxime-EDANS (f-TMC) was confirmed by (1)H NMR and fluorescence spectroscopy. Average molecular weight calculations of f-TMC with (1)H NMR and fluorescence spectroscopy gave similar results or ～7.7kDa. f-TMC in human bronchial epithelial cells was both cell membrane bound as well as intracellularly localized. This demonstrates the proof-of-concept for selective oxime formation at the reducing end of a chitosan derivative, which can be used for tracking chitosan in gene and drug delivery purposes and gives rise to further modifications with other functional groups.     

Voltage clamp fluorometry: Combining fluorescence and electrophysiological methods to examine the structure-function of the Na/K-ATPase

This paper summarizes our recent work investigating the conformational dynamics and structural arrangement of the Na⁺/K⁺-ATPase using voltage clamp fluorometry as well as the latest biochemical, biophysical and structural results from other laboratories. Our research has been focused on combining site-specific fluorophore labeling on the alpha, beta and/or gamma subunit with electrophysiological studies to investigate partial reactions of the ion pump by monitoring changes in fluorescence intensity following voltage pulses and/or solution exchange. As a consequence of these studies, we have been able to identify a residue on the beta subunit, which following labeling with tetramethylrhodamine-6-maleimide can be used as a reporter group to monitor the conformational state of the holoenzyme. Furthermore, we have been able to delineate distance constraints between the alpha, beta and gamma subunits and to examine the relative movements of these proteins during ion transport. Concurrent to this research, significant advancements have been made in understanding the molecular mechanism of the Na⁺/K⁺-ATPase. Thus, our research will be compared with the results from other groups and future experimental directions will be proposed.     

On-column tris(2-carboxyethyl)phosphine reduction and IC5-maleimide labeling during purification of a RpoC fragment on a nickel-nitrilotriacetic acid Column

Fluorescence labeling of proteins has become increasingly important since fluorescent techniques like FRET and fluorescence polarization are now commonly used in protein binding studies, proteomics, and for high-throughput screening in drug discovery. In our efforts to study the binding of the beta(')-subunit from Escherichia coli RNA polymerase (RNAP) to sigma70, we synthesized a fluorescent-labeled beta(')-fragment (residues 100-309) in a very convenient way, that could be used as a general protocol for hexahistidine-tagged proteins. By performing all the following steps, purification, reduction, derivatization with IC5-maleimide, and free dye removal while the protein was bound to the column, we were able to reduce the procedure time significantly and at the same time achieve better labeling efficiency and quality. The beta(')-fragment with a N-terminal His(6)-tag was purified from inclusion bodies and could be refolded prior to or after binding to a Ni-NTA affinity column. Reduction prior to labeling was achieved with TCEP that does not interfere with Ni-NTA chemistry. The labeled beta(')-fragment was tested with sigma70 that was labeled with an europium-based fluorophore for binding in a electrophoretic mobility-shift assay. The sigma-to-core protein interaction in bacterial RNA polymerase offers a potentially specific target for drug discovery, since it is highly conserved among the eubacteria, but differs significantly from eukaryotes.     

Molecular signaling aptamers for real-time fluorescence analysis of protein

Aptamers are a new class of nucleic acids that are selected in vitro for binding target molecules with high affinity and selectivity. They are promising protein-binding molecular probes that rival conventional antibodies for protein analysis. There have been recent advances in the development of molecular signaling aptamers that can transduce target protein binding to sensitive fluorescence signal changes. This facilitates the real time protein monitoring in homogenous solution as well as potentially in vivo. Different signaling strategies of using dual labeled aptamers based on fluorescence resonance energy transfer (FRET), one fluorophore labeled aptamers based on fluorescence anisotropy assay, or other label-free aptamers are reviewed.     

Fluorescent "Turn-on" system utilizing a quencher-conjugated peptide for specific protein labeling of living cells

A specific protein fluorescent labeling method has been used as a tool for bio-imaging in living cells. We developed a novel system of switching “fluorescent turn on” by the recognition of a fluorescent probe to a hexahistidine-tagged (His-tag) protein. The tetramethyl rhodamine bearing three nitrilotriacetic acids, which was used as a fluorescent probe to target a His-tagged protein, formed a reversible complex with the quencher, (Dabcyl)-conjugated oligohistidines, in the homogeneous solution, causing fluorescence of the fluorophore to be quenched. The complex when applied to living cells (COS-7) expressing His-tagged proteins on the cell surface caused the quencher-conjugated oligohistidines to be dissociated from the complex by specific binding of the fluorescent probe to the tagged protein, resulting in the fluorescent emission. The complex that did not participate in the binding event remained in the quenched state to maintain a low level of background fluorescence.