Selective dye-labeling of newly synthesized proteins in bacterial cells

We describe fluorescence labeling of newly synthesized proteins in Escherichia coli cells by means of Cu(I)-catalyzed cycloaddition between alkynyl amino acid side chains and the fluorogenic dye 3-azido-7-hydroxycoumarin. The method involves co-translational labeling of proteins by the non-natural amino acids homopropargylglycine (Hpg) or ethynylphenylalanine (Eth) followed by treatment with the dye. As a demonstration, the model protein barstar was expressed and treated overnight with Cu(I) and 3-azido-7-hydroxycoumarin. Examination of treated cells by confocal microscopy revealed that strong fluorescence enhancement was observed only for alkynyl-barstar treated with Cu(I) and the reactive dye. The cellular fluorescence was punctate, and gel electrophoresis confirmed that labeled barstar was localized in inclusion bodies. Other proteins showed little fluorescence. Examination of treated cells by fluorimetry demonstrated that cultures supplemented with Eth or Hpg showed an 8- to 14-fold enhancement in fluorescence intensity after labeling. Addition of a protein synthesis inhibitor reduced the emission intensity to levels slightly above background, confirming selective labeling of newly synthesized proteins in the bacterial cell.     

Determination of dye/protein ratios in a labeling reaction between a cyanine dye and bovine serum albumin by micellar electrokinetic chromatography using a diode laser-induced fluorescence detection

The degree of labeling, i.e., dye/protein ratio (D/P) is important for characterizing properties of dye labeling with proteins. A method for the determination of this ratio between a fluorescent cyanine dye and bovine serum albumin (BSA), based on the separation of the labeling mixture using micellar electrokinetic chromatography with diode laser-induced fluorescence detection, is described. Two methods for the determination of D/P were examined in this study. In these methods, a hydrolysis product and impurities, which are usually unfavorable compounds that are best excluded for protein analysis, were utilized to determine the amounts of dye bound to BSA. One is a direct method in which a ratio of the peak area of BSA to the total peak area of all the products produced in the labeling reaction was used for determining the average number of dye molecules bound to a single BSA molecule. The other is an indirect determination, which is based on diminution of all peak areas related to the products except for the labeled BSA. These methods were directly compared by means of a spectrophotometric method. The experimental results show that the indirect method is both reliable and sensitive. Therefore, D/P values can be determined at trace levels using the indirect method.     

Specific and stable fluorescence labeling of histidine-tagged proteins for dissecting multi-protein complex formation

Labeling of proteins with fluorescent dyes offers powerful means for monitoring protein interactions in vitro and in live cells. Only a few techniques for noncovalent fluorescence labeling with well-defined localization of the attached dye are currently available. Here, we present an efficient method for site-specific and stable noncovalent fluorescence labeling of histidine-tagged proteins. Different fluorophores were conjugated to a chemical recognition unit bearing three NTA moieties (tris-NTA). In contrast to the transient binding of conventional mono-NTA, the multivalent interaction of tris-NTA conjugated fluorophores with oligohistidine-tagged proteins resulted in complex lifetimes of more than an hour. The high selectivity of tris-NTA toward cumulated histidines enabled selective labeling of proteins in cell lysates and on the surface of live cells. Fluorescence labeling by tris-NTA conjugates was applied for the analysis of a ternary protein complex in solution and on surfaces. Formation of the complex and its stoichiometry was studied by analytical size exclusion chromatography and fluorescence quenching. The individual interactions were dissected on solid supports by using simultaneous mass-sensitive and multicolor fluorescence detection. Using these techniques, formation of a 1:1:1 stoichiometry by independent interactions of the receptor subunits with the ligand was shown. The incorporation of transition metal ions into the labeled proteins upon labeling with tris-NTA fluorophore conjugates provided an additional sensitive spectroscopic reporter for detecting and monitoring protein-protein interactions in real time. A broad application of these fluorescence conjugates for protein interaction analysis can be envisaged.     

Polymeric fluorescent dyes for labeling of proteins and nucleic acids

In order to increase the sensitivity of fluorescence labeling in biochemical reactions and diagnostic procedures a labeling technique with polymeric fluorescence dyes was established and tested for its applicability. The fluorescence dye is based on the fluorophor coumarine and was covalently linked to the model proteins strepavidine and IgG. The dye was synthesized by radical polymerization of three different types of functional monomers to ensure water solubility, covalent coupling to proteins, and fluorescence. The molecular weight range was between 20 and 200 kDa. Fractions of narrow molecular weight distribution were prepared by gel filtration on Superdex 200. The relationship between size and charge of the different fractions was analyzed by gel electrophoresis. Covalent conjugation to proteins was carried out by formation of a peptide bond between a carboxylic group of the functional monomers and an amino group of the protein mediated by 1-ethyl-3-(3-dimethylamino-propyl)-carbodiimide (EDC). A novel type of gel electrophoresis was developed in order to analyze and optimize the conjugation reaction; the results were in agreement with those from analytical ultracentrifugation with fluorescence detection. Hydrodynamic studies of the uncoupled dye and the protein-dye conjugates exhibited a drastic decrease of Stokes radius of the dye due to the coupling to the protein. Under optimum conditions the fluorescence intensity of a protein-polymeric dye conjugate was enhanced 40-fold compared to a monomeric dye. Biotin binding to the protein streptavidin was not affected significantly by the conjugation with the polymeric dye. At present, the applicability of the polymeric dye in biochemical and diagnostic reactions seems to be limited due to strong but unspecific hydrophobic interactions which might be overcome by using fluoresceine as monomeric dye.     

Pyrylium‐based dye and charge tagging in proteomics

The pyrylium group is a selective reagent for ε‐amino groups in proteins. In particular, for fluorescence labeling, a number of advantages over traditional N‐hydroxysuccinimidyl ester chemistry were recognized such as the rapid prestaining procedure. Here, we have investigated the labeling reaction for the fluorogenic pyrylium dye Py‐1 using liquid chromatography coupled to MS with the aim of determining its specificity and possible side products. Peptides containing no, one, and two lysine residue and a choice of no or one cysteine residue were labeled with Py‐1 at yields > 30%. Gas phase fragmentation proved both labeling of lysine residues as well as that of the N‐terminus also in peptides that contained a lysine residue. Evidence for cysteine labeling was not found, but several other products were detected such as the results of rearrangements with adjacent acidic amino acids. Apart from the use as a fluorogenic label, Py‐1 recommends itself for N‐terminal charge tagging as alternative to the commonly used quaternary ammonium salts. Predominantly a‐ and b‐type ion series were observed for N‐terminally labeled peptides. Further applications include chromophore tagging since the labeled product is not only fluorescent but also colored red.     

Fluorimetric studies and noncovalent labeling of protein with the near-infrared dye HITCI for analysis by CE-LIF

1,1',3,3,3',3'-Hexamethylindotricarbocyanine iodide (HITCI) is a commercially available, positively charged, indocarbocyanine dye used typically as a laser dye in the near infrared (NIR). The absorbance and fluorescence properties of HITCI in a variety of solvent systems were determined. Results indicate that the fluorescence of HITCI is not significantly affected by the pH. Titration of HITCI with human serum albumin (HSA) and trypsinogen was carried out to investigate the interactions between this dye and proteins. These studies revealed that the absorbance and fluorescence properties of the dye change upon binding to protein in a wide range of solution pH's. The potential use of HITCI as a noncovalent protein labeling probe, therefore, was explored. Determination and separation of HITCI and HITCI-protein complexes was performed by capillary electrophoresis with diode-laser induced fluorescence detection (CE-LIF). Both pre-column and on-column noncovalent labeling methods are demonstrated.     

RABA (Reductive Alkylation By Acetone): A novel stable isotope labeling approach for quantitative proteomics

Quantitative proteomics is challenging and various stable isotope based approaches have been developed to meet the challenge. Hereby we describe a simple, efficient, reliable, and inexpensive method named reductive alkylation by acetone (RABA) to introduce stable isotopes to peptides for quantitative analysis. The RABA method leads to alkylation of N-terminal and lysine amino groups with isopropyl moiety. Using unlabeled (d₀) and deuterium labeled (d₆) acetone, a 6 Da mass split is introduced to each isopropyl modification between the light and heavy isotope labeled peptides, which is ideally suited for quantitative analysis. The reaction specificity, stoichiometry, labeling efficiency, and linear range of the RABA method have been thoroughly evaluated in this study using standard peptides, tryptic digest of proteins, as well as human cell lysate. Reliable quantitative results have been consistently obtained in all experiments. We also applied the RABA method to quantitative analysis of proteins in spinal cords of transgenic mouse models of amyotrophic lateral sclerosis. Highly homologous proteins (transgenic human SOD1 and endogenous mouse SOD1) were distinguished and quantified using the method developed in this study. In addition, the quantitative results using the RABA approach were independently validated by Western blot.     

基于Endo-M N175Q糖链转移反应与丙酮富集糖肽的LC-MS分析糖蛋白N-糖链

基于化学酶标记和丙酮富集糖肽方法,建立了一种可靠、有效、简单的糖蛋白N-糖链分析方法。以唾液酸糖肽(SGP)为模型糖肽,比较了样品中丙酮加入量对SGP的富集效果,最终选择加入样品体积5倍量的丙酮。用丙酮富集经胰蛋白处理的核糖核酸酶B(RNase B)酶解液中的糖肽,以富集分离得到的糖肽(糖基供体)和PDPZ-Boc-Asn-GlcNAc(糖基受体)作为酶反应底物,进行Endo-M N175Q的转糖基反应,得到PDPZBoc-Asn-GlcNAc-N-糖链标记物。采用YMC C18色谱柱为分析柱,10 mmol/L甲酸铵-乙腈为流动相梯度洗脱,经液相色谱-串联质谱(LC-MS)检测得到5种高甘露糖型糖链。结果表明,丙酮可有效地富集大量肽和少量糖肽混合溶液中的糖肽,Endo-M N175Q可将天然糖肽的糖链转移到PDPZ-Boc-Asn-GlcNAc受体上。将该方法应用于胎球蛋白N-糖链分析,检测到5种复杂型N-糖链。该研究为各种糖蛋白N-糖链检测提供了新的分析方法。     

A fluorogenic dye activated by the staudinger ligation

Specific labeling of biomolecules with biochemical and biophysical probes is a central element of proteomics research. Here we describe a coumarin-phosphine dye that undergoes activation of coumarin fluorescence upon Staudinger ligation with azides. Since azides can be metabolically incorporated into cellular proteins and oligosaccharides, this dye may be a useful tool for profiling proteins and their posttranslational modifications.     

新型水溶性不对称五甲川菁染料的合成、光稳定性及蛋白质的荧光标记

合成并表征了系列水溶性五甲川菁染料, 研究了其在不同溶剂中的光谱性能. 结果表明, 染料在水中的最大吸收和荧光光谱在647~665 nm波长范围内, 荧光量子产率达到0.1左右. 考察了N位取代基对染料水溶液光稳定性的影响, 结果表明, 在N原子上引入带有苯环结构和大体积的磺酸基, 可以提高染料的光稳定性. 高效液相色谱(HPLC)分析结果表明, 染料4a的N-羟基琥珀酰亚胺(NHS)活性酯标记牛血清白蛋白(BSA)的检测限为1.2×10^-8 mol/L, 与紫外检测相比, 检测灵敏度提高了近2个数量级.     

Reversible labeling of tyrosine residue in peptide using 4-fluoro-7-nitro-2,1,3-benzoxadiazole and N-acetyl-L-cysteine.

The reversible labeling of tyrosine (Tyr)-containing peptide, which involves detection and recovery, is described in this paper. The phenolic-OH in Tyr structure reacted with 4-fluoro-7-nitro-2,1,3-benzoxadiazole (NBD-F) under a mild condition at room temperature in alkaline medium. The resulting derivative absorbed at around 280 nm and 380 nm. However, the fluorescence was very weak. The NBD moiety in the derivative was efficiently removed by the treatment of N-acetyl-L-cysteine (N-AcCys), and the original peptide before the labeling was completely recovered. The proposed procedure was successfully applied to the reversible labeling of N-terminal amine-blocked peptides, i.e., N-AcTyr-Val-Gly, Z-Glu-Tyr, Z-Phe-Tyr, N-Formyl-Met-Leu-Tyr, and N-AcArg-Pro-Pro-Gly-Phe-Ser-Pro-Tyr-Arg. Although the proposed method could not recover the N-terminal amine-free peptides without blocking, the selective detection and the recovery of Tyr-containing peptide fragments were possible by the combination with enzyme digestion. The reversible labeling of Tyr-containing peptide was demonstrated with [Tyr8]-bradykinin as a model for high-molecular-mass peptides and proteins. The peptide fragments containing NBD-O-Tyr moiety, obtained after the digestion, were easily discriminated from various peptides with the monitoring of UV and FL, because the target peptide did not fluoresce, but absorbed at both 280 nm and 380 nm. The peptide fragment containing Tyr was finally recovered from the de-labeling reaction with N-AcCys. The proposed method hence provides a novel technique for the reversible labeling of Tyr-containing peptides, which will enable the selective detection and the recovery of the original peptide.     

Protein labeling with red squarylium dyes for analysis by capillary electrophoresis with laser-induced fluorescence detection

Two new red luminescent asymmetric squarylium dyes (designated "Red-1c and Red-3") have been shown to exhibit absorbance shifts to longer wavelengths upon the addition of protein, along with a concomitant increase in fluorescence emission. Specifically, the absorbance maxima for Red-1c and Red-3 dyes are 607 and 622 nm, respectively, in the absence of HSA, and 642 and 640 nm in the presence of HSA, making the excitation of their protein complexes feasible with inexpensive and robust diode lasers. Fluorescence emission maxima, in the presence of HSA, are 656 and 644 nm for Red-1c and Red-3, respectively. Because of the inherently low fluorescence of the dyes in their free state, Red-1c and Red-3 were used as on-column labels (that is, with the dye incorporated into the separation buffer), thus eliminating the need for sample derivatization prior to injection and separation. A comparison of precolumn and on-column labeling of proteins with these squarylium dyes revealed higher efficiencies and greater sensitivities for on-column labeling, which, when conducted with a basic, high-salt content buffer, permitted baseline resolution of a mixture of five model proteins. LOD for model proteins, such as transferrin, alpha-lactalbumin, BSA, and beta-lactoglobulin A and B, labeled with these dyes and analyzed by CE with LIF detection (CE-LIF) were found to be dependent upon dye concentration and solution pH, and are as low as 5 nM for BSA. Satisfactory linear relationships between peak height (or peak area) and protein concentration were obtained by CE-LIF for this on-column labeling method with Red-3 and Red-1c.     

Laser-induced fluorescence detection schemes for the analysis of proteins and peptides using capillary electrophoresis

Over the past few years, a large number of studies have been prepared that describe the analysis of peptides and proteins using capillary electrophoresis (CE) and laser-induced fluorescence (LIF). These studies have focused on two general goals: (i) development of automatic, selective and quick separation and detection of mixtures of peptides or proteins; (ii) generation of new methods of quantitation for very low concentrations (nm and subnanomolar) of peptides. These two goals are attained with the use of covalent labelling reactions using a variety of dyes that can be readily excited by the radiation from a commonly available laser or via the use of noncovalent labelling (immunoassay using a labelled antibody or antigen or noncovalent dye interactions). In this review article, we summarize the works which were performed for protein and peptide analysis via CE-LIF.     

Dimethylditetradecylammonium bromide (2C14DAB) as a self-assembled surfactant coating for detection of protein–dye complexes by CE-LIF

A self-assembled column coating for capillary electrophoresis in conjunction with laser-induced fluorescence detection (CE-LIF) has been evaluated for the separation and quantitation of protein–dye complexes. This semi-permanent coating, composed of dimethylditetradecyl-ammonium bromide (2C₁₄DAB), is inexpensive and easily assembled onto the column and it allows for better peak resolution and greater control over electroosmotic flow. The versatility of long-chained surfactant coatings was determined particularly with respect to their use with fluorescent probes, different pH buffers, and different proteins. Studies were performed to determine the stability of the coating under various pH and buffer conditions. Red-1c, a red luminescent squarylium dye, was used for on-column protein labeling concurrently with the surfactant coating and LIF detection. Protein–Red-1c complexes were excited with a 650-nm diode laser and their emission detected by a photomultiplier tube with a 664-nm filter. A comparison of pre-column labeling and on-column labeling of a two-model protein system (human serum albumin and β-lactoglobulin A) revealed higher efficiencies and greater sensitivities for both proteins using on-column labeling and coated columns. A linear relationship between peak height and protein concentration was obtained by CE-LIF for this on-column labeling method with 2C₁₄DAB-coated columns and the Red-1c probe.     

Enhancement of phosphoprotein analysis using a fluorescent affinity tag and mass spectrometry

A fluorescent affinity tag (FAT) was synthesized and was utilized to selectively modify phosphorylated serine and threonine residues via beta-elimination and Michael addition chemistries in a 'one-step' reaction. This labeling technique was used for covalent modification of both phosphoproteins and phosphopeptides, allowing identification of these molecular species by fluorescence imaging after solution- or gel-based separation methods. In addition to the strong fluorescence of the rhodamine tag, a commercially available antibody can be used to enrich low-abundance post-labeled phosphopeptides present in complex mixtures. Application of this methodology to phosphorylation-site mapping has been evaluated for a phosphoprotein standard, bovine beta-casein. Initial results demonstrated low femtomole detection limits after fluorescence image analysis of FAT-labeled proteins or peptides.     

Matrix-assisted laser desorption/ionization-MS-based relative quantification of peptides and proteins using iodoacetamide and N-methyliodoacetamide as labeling reagents

The use of iodoacetamide (IAA) and N-methyliodoacetamide (MIAA) as labeling agents for the relative measurements of proteins using MALDI-MS is described herein. These reagents, which alkylate the thiol groups of cysteine residues in proteins, were introduced during the alkylation step of a common protein denaturation and digestion process. This approach is simpler and cheaper than those involving isotope labeling agents. The labeling agents described herein displayed good dynamic ranges and correlation coefficients for protein quantification analyses when the proteins were treated through either in-solution or in-gel digestion. The best dynamic ranges (in the molar ratio) for proteins lysozyme, transferrin, and BSA (in-solution digestion) are 0.1-10, 0.1-8, and 0.1-8, respectively. The corresponding correlation coefficients are greater than 0.99. The IAA/MIAA labeling is a useful method for the relative quantification of peptides and digested proteins when the chromatographic isotope effect is not a major concern.     

Fluorescence lifetime correlation spectroscopy combined with lifetime tuning: new perspectives in supported phospholipid bilayer research

A new concept based on fluorescence lifetime correlation spectroscopy (FLCS) is presented allowing the simultaneous determination of diffusion coefficients of identical molecules located in different environments. The difference in fluorescence lifetimes, which is the main prerequisite for FLCS, is reached by locating one population of the dye close to a light-absorbing surface. Since such surfaces quench fluorescence, the fluorescence lifetime of chromophores located close to these surfaces can be tuned in a specific manner. This approach has been demonstrated for a BODIPY-tail-labeled lipid in supported phospholipid bilayers (SPBs) as well as in phospholipid multilayers adsorbed onto solid supports. In particular, the effect of the solid support type on the fluorescence lifetime as well as its dependence on the BODIPY-support distance has been characterized and verified by theoretical considerations based on precise determination of refractive indices of the used supports. While the fluorescence lifetime of BODIPY dye is 5.6 ns in small unilamellar vesicles (SUVs) composed of 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) and 1,2-dioleoyl-sn-glycero-3-[phospho-L-serine] (DOPS), the lifetime is 1.8 ns in DOPC/DOPS SPBs adsorbed onto ITO-covered glass or 3.0 ns in a DOPC/DOPS monolayer adsorbed onto seven 1,2-dipalmitoyl-sn-glycero-3-phosphate (DPPA) layers on oxidized silicon. Using these particular systems, we demonstrated that FLCS enables one to characterize simultaneously two-dimensional lipid diffusion in the planar lipid layers and three-dimensional vesicle diffusion in bulk above the lipid layers using single dye labeling. The autocorrelation functions obtained by this new approach do agree with those obtained by standard FCS on isolated SPBs or vesicles. Possible applications of this virtual two-channel measurement using single dye labeling as well as one detection channel are discussed.     

Band broadening caused by the multiple labeling of proteins in micellar electrokinetic chromatography with diode laser-induced fluorescence detection

When a labeling reagent is used, in the determination of proteins by capillary electrophoresis with laser-induced fluorescence detection, the multiple labeling of proteins frequently occurs, which can degrade the separation efficiency. In order to understand the influence of the multiple labeling of proteins on separation efficiency, the band broadening caused by a labeling reaction between bovine serum albumin (BSA) and a cyanine fluorescent dye (Cy5) was investigated using micellar electrokinetic chromatography in conjunction with diode laser-induced fluorometry. With the aid of an internal standard, methylene blue, the height equivalent to the theoretical plate (HETP) ratio of BSA to methylene blue was used as an indicator for band broadening under optimum separation conditions. Labeling conditions, including reaction buffer pH, reaction time, and initial concentration of Cy5 to bovine serum albumin, were found to influence the HETP ratio. The separation efficiency for the labeled protein was degraded by experimental conditions employed in the labeling, which indicates an increase in the heterogeneity of the final products.     

Assessment of acetone as an alternative to acetonitrile in peptide analysis by liquid chromatography/mass spectrometry

Acetonitrile as a solvent used in liquid chromatography/mass spectrometry (LC/MS) of peptides and proteins is a relatively toxic solvent (LD₅₀ oral; rat; 2,460 mg/kg) compared to alternatives like methanol (LD₅₀ oral; rat; 5,628 mg/kg) and acetone (LD₅₀ oral; rat; 5,800 mg/kg). Strategies to minimize its consumption in LC are either to reduce the inner diameter of the column or replace acetonitrile with a suitable alternative. Methanol is often recommended to replace acetonitrile in peptide analysis. In this study however, the main focus lies on another alternative solvent for LC/MS of peptides; acetone. A number of model proteins were tryptically digested and the peptide solutions were analyzed on a linear trap quadrupole (LTQ) mass spectrometer. The performances of acetonitrile, methanol and acetone were compared according to the quality of the chromatograms obtained and identification of the peptides using the BioWorks? software developed by Thermo Scientific. In accordance to the elutropic series, acetone was found to significantly reduce the retention times of peptides separated by C18 column material with regard to acetonitrile while methanol led to increased retention times. Acetone was the superior solvent to methanol for most of the tested model proteins reaching similar sequence coverage and numbers of identified peptides as acetonitrile. We therefore propose acetone as an alternative to acetonitrile in LC/MS of peptides. Copyright © 2009 John Wiley & Sons, Ltd.     

Supramolecular Translation of Enzymatically Triggered Disassembly of Micelles into Tunable Fluorescent Responses

The need for advanced fluorescent imaging and delivery platforms has motivated the development of smart probes that change their fluorescence in response to external stimuli. Here a new molecular design of fluorescently labeled PEG–dendron hybrids that self‐assemble into enzyme‐responsive micelles with tunable fluorescent responses is reported. In the assembled state, the fluorescence of the dyes is quenched or shifted due to intermolecular interactions. Upon enzymatic cleavage of the hydrophobic end‐groups, the labeled polymeric hybrids become hydrophilic, and the micelles disassemble. This supramolecular change is translated into a spectral response as the dye–dye interactions are eliminated and the intrinsic fluorescence is regained. We demonstrate the utilization of this molecular design to generate both Turn‐On and spectral shift responses by adjusting the type of the labeling dye. This approach enables transformation of non‐responsive labeling dyes into smart fluorescent probes.