Blot overlays with 32P-labeled fusion proteins

Proteins labeled with 32P can be used as sensitive "prime" in blot overlays to detect binding proteins or domains. Small G-protein Ras can bind GTP with extremely high affinity (Kd approximately 10(-11)-10(-12) M) in the presence of Mg2+. We have taken advantage of this property of Ras to develop a vector that expresses proteins of interest such as glutathione S-transferase (GST)/Ras fusion proteins for noncovalent labeling with [gamma-32P]GTP. The labeling efficiency of this method is >60% and involves a single short incubation step. We have previously identified several binding proteins for the second SH3 domain of the adaptor Nck using this method. Here we illustrate the overlay method using the GST/Ras system and compare results with the SH3 domain labeled by phosphorylation with [gamma-32P]ATP. Both methods are similarly specific and sensitive; however, we show that signals are dependent primarily on GST-mediated probe dimerization. These dimeric probes allow a more stable probe-target complex similar to immunoglobulin interactions, thus significantly improving the sensitivity of the technique.     

Quantitative fluorescence labeling of aldehyde-tagged proteins for single-molecule imaging

A major hurdle for molecular mechanistic studies of many proteins is the lack of a general method for fluorescence labeling with high efficiency, specificity and speed. By incorporating an aldehyde motif genetically into a protein and improving the labeling kinetics substantially under mild conditions, we achieved fast, site-specific labeling of a protein with ～100% efficiency while maintaining the biological function. We show that an aldehyde-tagged protein can be specifically labeled in cell extracts without protein purification and then can be used in single-molecule pull-down analysis. We also show the unique power of our method in single-molecule studies on the transient interactions and switching between two quantitatively labeled DNA polymerases on their processivity factor.     

Antibody microarray-based profiling of complex specimens: systematic evaluation of labeling strategies

Antibody microarrays have often had limited success in detection of low abundant proteins in complex specimens. Signal amplification systems improve this situation, but still are quite laborious and expensive. However, the issue of sensitivity is more likely a matter of kinetically appropriate microarray design as demonstrated previously. Hence, we re-examined in this study the suitability of simple and inexpensive detection approaches for highly sensitive antibody microarray analysis. N-hydroxysuccinimidyl ester (NHS)- and Universal Linkage System (ULS)-based fluorescein and biotin labels used as tags for subsequent detection with anti-fluorescein and extravidin, respectively, as well as fluorescent dyes were applied for analysis of blood plasma. Parameters modifying strongly the performance of microarray detection such as labeling conditions, incubation time, concentrations of anti-fluorescein and extravidin and extent of protein labeling were analyzed and optimized in this study. Indirect detection strategies whether based on NHS- or ULS-chemistries strongly outperformed direct fluorescent labeling and enabled detection of low abundant cytokines with many dozen-fold signal-to-noise ratios. Finally, particularly sensitive detection chemistry was applied to monitoring cytokine production of stimulated peripheral T cells. Microarray data were in accord with quantitative cytokine levels measured by ELISA and Luminex, demonstrating comparable reliability and femtomolar range sensitivity of the established microarray approach.     

基于TurboID的植物蛋白邻近标记实验方法

邻近标记作为近些年发展起来的一项检测活细胞内蛋白互作关系和亚细胞结构蛋白组的新型技术,已成功应用于多种动植物体系的研究。该技术通过给诱饵蛋白融合一个具有特定催化连接活性的酶,在酶的催化作用下将小分子底物(如生物素)共价连接到酶邻近的内源蛋白,通过富集和分析被标记的蛋白可获得与诱饵互作的蛋白组。经定向进化产生的生物素连接...     

Differential protein labeling with thiol-reactive infrared DY-680 and DY-780 maleimides and analysis by two-dimensional gel electrophoresis

Differential protein labeling with 2-DE separation is an effective method for distinguishing differences in the protein composition of two or more protein samples. Here, we report on a sensitive infrared-based labeling procedure, adding a novel tool to the many labeling possibilities. Defined amounts of newborn and adult mouse brain proteins and tubulin were exposed to maleimide-conjugated infrared dyes DY-680 and DY-780 followed by 1- and 2-DE. The procedure allows amounts of less than 5 microg of cysteine-labeled protein mixtures to be detected (together with unlabeled proteins) in a single 2-DE step with an LOD of individual proteins in the femtogram range; however, co-migration of unlabeled proteins and subsequent general protein stains are necessary for a precise comparison. Nevertheless, the most abundant thiol-labeled proteins, such as tubulin, were identified by MS, with cysteine-containing peptides influencing the accuracy of the identification score. Unfortunately, some infrared-labeled proteins were no longer detectable by Western blots. In conclusion, differential thiol labeling with infrared dyes provides an additional tool for detection of low-abundant cysteine-containing proteins and for rapid identification of differences in the protein composition of two sets of protein samples.     

Optimization of the isotope-coded affinity tag-labeling procedure for quantitative proteome analysis

The combination of isotope coded affinity tag (ICAT) reagents and tandem mass spectrometry constitutes a new method for quantitative proteomics. It involves the site-specific, covalent labeling of proteins with isotopically normal or heavy ICAT reagents, proteolysis of the combined, labeled protein mixture, followed by the isolation and mass spectrometric analysis of the labeled peptides. The method critically depends on labeling protocols that are specific, quantitative, general, robust, and reproducible. Here we describe the systematic evaluation of important parameters of the labeling protocol and describe optimized labeling conditions. The tested factors include the ICAT reagent concentration, the influence of the protein, SDS, and urea concentrations on the labeling reaction, and the reaction time. We demonstrate that using the optimized conditions specific and quantitative labeling was achieved on standard proteins as well as in complex protein mixtures such as a yeast cell lysate.     

Studies on peptide acetylation for stable-isotope labeling after 1-D PAGE separation in quantitative proteomics

Acetylation is a single labeling process to label peptides in control and experimental samples universally, and is independent of amino acid composition or post-translational modification. Here, we propose a new strategy especially useful to quantify either hydrophobic or extremely acidic and basic proteins involved in acetylation of tryptic peptides after sodium dodecyl sulfate polyarcylamide gel electrophoresis (SDS-PAGE) separation. We studied some essential parameters of acetylation labeling reactions in either in-solution tryptic peptides or in-gel digested extracts systematically. We have found that the acetylation efficiency varies markedly on account of different reactive systems, and demonstrated that stable isotope labeling can be steadily obtained with in-gel digested peptides under optimized conditions. We use this protocol to quantify some proteins of two kinds of hepatocellular carcinoma cell line, non-metastatic hepatocellular carcinoma cells, Hep3B, and metastatic hepatocellular carcinoma cells, MHCC97-H. The experimental results provide positive evidence for the potential application of an acetylation labeling strategy in quantitative proteomics, and an efficient way for global proteome quantification.     

15N-metabolic labeling for comparative plasma membrane proteomics in Arabidopsis cells

An important goal for proteomic studies is the global comparison of proteomes from different genotypes, tissues, or physiological conditions. This has so far been mostly achieved by densitometric comparison of spot intensities after protein separation by 2-DE. However, the physicochemical properties of membrane proteins preclude the use of 2-DE. Here, we describe the use of in vivo labeling by the stable isotope 15N as an alternative approach for comparative membrane proteomic studies in plant cells. We confirm that 15N-metabolic labeling of proteins is possible and efficient in Arabidopsis suspension cells. Quantification of 14N versus 15N MS signals reflects the relative abundance of 14N and 15N proteins in the sample analyzed. We describe the use of 15N-metabolic labeling to perform a partial comparative analysis of Arabidopsis cells following cadmium exposure. By focusing our attention on plasma membrane proteins, we were able to confidently identify proteins showing up to 5-fold regulation compared to unexposed cells. This study provides a proof of principle that 15N-metabolic labeling is a useful technique for comparative membrane proteome studies.     

An optimized strategy for ICAT quantification of membrane proteins

The work presented here focuses on the development of a method adapting isotope labeling of proteins with ICAT to the study of highly hydrophobic proteins. Conditions for the labeling of proteins were first established using two standard soluble proteins and iodoacetamidyl-3,6-dioxaoctanediamine biotin (PEO-iodoacetyl biotin). Results demonstrated the efficiency of the labeling in the presence of high concentrations of both SDS and urea. These conditions were then used to label a highly hydrophobic mitochondrial membrane protein, the adenine nucleotide translocator ANT-1, with PEO-iodoacetyl biotin and then with the cleavable ICAT reagent. The results presented here show that labeling of proteins with cleavable ICAT is possible and may even be improved in strong denaturing buffers containing both SDS at a concentration higher than 0.5% (w/v) and urea. These results open the possibility of applying the ICAT strategy to complex samples containing very hydrophobic proteins solubilized in urea-SDS buffers. The adaptability of the developed method is demonstrated here with preliminary results obtained during the study of membrane-enriched fractions prepared from murine embryonic stem cells.     

Photobiotin as a sensitive probe for protein labeling

A sensitive method for the nonisotopic in vitro labeling of proteins under physiological conditions using photobiotin, a compound originally developed for labeling nucleic acids (Forster et al. (1985) Nucleic Acids Res. 13, 745), has been developed. Using sheep brain tubulin as a model protein it was shown that labeling with photobiotin resulted in detection limits below 10 pg when avidin-alkaline phosphatase was used in the final step. No significant loss of tubulin polymerization, colchicine binding, recognition by antitubulin antibodies, or changes in electrophoretic behavior were observed. In addition, photobiotinylation of antitubulin antibodies did not affect their recognition of unlabeled tubulin. The use of photobiotin labeling with avidin-alkaline phosphatase detection for electrophoretic separations of molecular weight standards, crude protein supernatants, and tubulin gave a 64 to 1024-fold increase in sensitivity over Coomassie blue staining.     

Saturation fluorescence labeling of proteins for proteomic analyses

We present here an optimized and cost-effective approach to saturation fluorescence labeling of protein thiols for proteomic analysis. We investigated a number of conditions and reagent concentrations, including the disulfide reducing agent tris(2-carboxyethyl)phosphine (TCEP), pH, incubation time, linearity of labeling, and saturating dye/protein thiol ratio with protein standards to gauge specific and nonspecific labeling. Efficacy of labeling under these conditions was quantified using specific fluorescence estimation, defined as the ratio of fluorescence pixel intensities and Coomassie-stained pixel intensities of bands after digital imaging. Factors leading to specific versus nonspecific labeling in the presence of thiourea are also discussed. We found that reproducible saturation of available Cys residues of the proteins used as labeling standards (human carbonic anhydrase I, enolase, and α-lactalbumin) is achieved at 50- to 100-fold excess of the uncharged maleimide-functionalized BODIPY dyes over Cys. We confirmed our previous findings, and those of others, that the maleimide dyes are not affected by the presence of 2 M thiourea. Moreover, we established that 2 mM TCEP used as reductant is optimal. We also established that labeling is optimal at pH 7.5 and complete after 30 min. Low nonspecific labeling was gauged by the inclusion of non-Cys-containing proteins (horse myoglobin and bovine carbonic anhydrase) to the labeling mixture. We also showed that the dye exhibits little to no effect on the two-dimensional mobilities of labeled proteins derived from cells.     

Site-selective lysine modification of native proteins and peptides via kinetically controlled labeling

The site-selective modification of the proteins RNase A, lysozyme C, and the peptide hormone somatostatin is presented via a kinetically controlled labeling approach. A single lysine residue on the surface of these biomolecules reacts with an activated biotinylation reagent at mild conditions, physiological pH, and at RT in a high yield of over 90%. In addition, fast reaction speed, quick and easy purification, as well as low reaction temperatures are particularly attractive for labeling sensitive peptides and proteins. Furthermore, the multifunctional bioorthogonal bioconjugation reagent (19) has been achieved allowing the site-selective incorporation of a single ethynyl group. The introduced ethynyl group is accessible for, e.g., click chemistry as demonstrated by the reaction of RNase A with azidocoumarin. The approach reported herein is fast, less labor-intensive and minimizes the risk for protein misfolding. Kinetically controlled labeling offers a high potential for addressing a broad range of native proteins and peptides in a site-selective fashion and complements the portfolio of recombinant techniques or chemoenzymatic approaches.     

Fluorescent monitoring of proteins during sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blotting

Fluorescent labeling of proteins was found to be a very sensitive and reliable alternative to conventional methods for monitoring proteins on Western blots. Proteins were labeled with 2-methoxy-2,4-diphenyl-3(2H)-furanone (MDPF) before SDS-PAGE. After electrophoresis and subsequent electro-blotting the fluorescent-labeled proteins were visible upon ultraviolet illumination of the nitrocellulose membranes, and could be photographed to yield an accurate record of the blots before subsequent serological analysis. The sensitivity for detecting MDPF-labeled proteins on nitrocellulose was 100-200 ng, 50 to 100 fold less sensitive than on gels. Fluorescent-labeled TMV and MStpV capsid proteins that were blotted onto nitrocellulose still reacted in serological tests and were detected when present in quantities as low as 100 pg. Fluorescent labeling allows accurate photographic records of the SDS-gel, blot and probed blot using only one sample, and no subsequent staining steps are required.     

Difference in mass analysis using labeled lysines (DIMAL-K): a new, efficient proteomic quantification method applied to the analysis of astrocytic secretomes

Here we describe an original strategy for unbiased quantification of protein expression called difference in mass analysis using labeled lysine (K) (DIMAL-K). DIMAL-K is based on the differential predigestion labeling of lysine residues in complex protein mixtures. The method is relevant for proteomic analysis by two-dimensional electrophoresis and MALDI-TOF mass spectrometry. Protein labeling on lysine residues uses two closely related chemical reagents, S-methyl thioacetimidate and S-methyl thiopropionimidate. Using protein standards, we demonstrated that 1) the chemical labeling was quantitative, specific, and rapid; 2) the differentially labeled proteins co-migrated on two-dimensional gels; and 3) the identification by mass fingerprinting and the relative quantification of the proteins were possible from a single MALDI-TOF mass spectrum. The power of the method was tested by comparing and quantifying the secretion of proteins in normal and proinflammatory astrocytic secretomes (20 microg). We showed that DIMAL-K was more sensitive and accurate than densitometric image analysis and allowed the detection and quantification of novel proteins.     

An automated in‐gel digestion/iTRAQ‐labeling workflow for robust quantification of gel‐separated proteins

Simple protein separation by 1DE is a widely used method to reduce sample complexity and to prepare proteins for mass spectrometric identification via in‐gel digestion. While several automated solutions are available for in‐gel digestion particularly of small cylindric gel plugs derived from 2D gels, the processing of larger 1D gel‐derived gel bands with liquid handling work stations is less well established in the field. Here, we introduce a digestion device tailored to this purpose and validate its performance in comparison to manual in‐gel digestion. For relative quantification purposes, we extend the in‐gel digestion procedure by iTRAQ labeling of the tryptic peptides and show that automation of the entire workflow results in robust quantification of proteins from samples of different complexity and dynamic range. We conclude that automation improves accuracy and reproducibility of our iTRAQ workflow as it minimizes the variability in both, digestion and labeling efficiency, the two major causes of irreproducible results in chemical labeling approaches.     

Use of the heterobifunctional cross-linker m-maleimidobenzoyl N-hydroxysuccinimide ester to affinity label cholecystokinin binding proteins on rat pancreatic plasma membranes

The binding of 125I-cholecystokinin-33 (125I-CCK-33) to its receptors on rat pancreatic membranes was decreased by modification of membrane protein sulfhydryl groups. Sulfhydryl modifying reagents also caused an accelerated release of bound 125I-CCK-33 from its receptor. Because of the presence of an essential sulfhydryl group(s) in CCK receptor binding we studied the application of the heterobifunctional (SH,NH2) cross-linker, m-maleimidobenzoyl N-hydroxysuccinimide ester (MBS), to affinity label 125I-CCK-33 binding proteins on rat pancreatic plasma membranes. Analysis of the cross-linked products by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography revealed that this heterobifunctional cross-linker affinity labeled a major Mr = 80,000-95,000 protein previously identified as part of the CCK receptor on the basis of affinity labeling using homobifunctional and heterobifunctional photoreactive cross-linkers. Additional proteins of Mr greater than 200,000, and Mr = 130,000-140,000 were affinity labeled using MBS. The efficiency of the cross-linking reaction between 125I-CCK-33 and its membrane binding proteins with MBS was significantly greater than that obtained with NH2-directed homobifunctional reagents such as disuccinimidyl suberate. The efficiency of cross-linking could be dramatically improved by reduction of membrane proteins with low-molecular weight thiols prior to binding and cross-linking. The differential labeling patterns of the CCK binding proteins obtained with chemical cross-linkers of similar length but different chemical reactivity underscores the need for caution in predicting native receptor structure from affinity labeling data alone. Using the same pancreatic plasma membrane preparation and 125I-insulin, the Mr = 125,000 alpha-subunit of the insulin receptor was affinity labeled using MBS as cross-linker, demonstrating its utility in identifying other peptide hormone receptors.     

RepTAGs: universal tags for isolation and labeling of proteins, for labeling live mammalian cells and for drug discovery

Methods for specific immobilization, isolation and labeling of proteins are central to the elucidation of cellular functions. Based on bacterial repressor proteins, which bind to specific target sequences in response to small molecules (macrolide and tetracycline antibiotics) or environmental parameters (temperature), we have developed a set of protein tags (RepTAGs), which enable reversible immobilization of the protein of interest on a solid support for the isolation and quantification as well as for the specific labeling of target proteins with fluorescent dyes for tracking them within a complex protein mixture. Similarly, live mammalian cells were specifically labeled with a fluorescent operator sequence bound to RepTAGs, which were directed towards the cell surface for easy discrimination between transfected and untransfected cell populations. Based on the drug-responsive RepTAG-DNA interactions, it was also possible to quantify or discover antibiotics in environmental samples or compound libraries by means of rapid, sensitive detection methods involving fluorescence polarization and bioluminescence. We believe that the universally applicable RepTAGs will become essential for the analysis and manipulation of proteins in the most diverse areas of protein chemistry and cell biology.     

N-Terminal Amino Acid Sequence Determination of Proteins by N-Terminal Dimethyl Labeling: Pitfalls and Advantages When Compared with Edman Degradation Sequence Analysis

In recent history, alternative approaches to Edman sequencing have been investigated, and to this end, the Association of Biomolecular Resource Facilities (ABRF) Protein Sequencing Research Group (PSRG) initiated studies in 2014 and 2015, looking into bottom-up and top-down N-terminal (Nt) dimethyl derivatization of standard quantities of intact proteins with the aim to determine Nt sequence information. We have expanded this initiative and used low picomole amounts of myoglobin to determine the efficiency of Nt-dimethylation. Application of this approach on protein domains, generated by limited proteolysis of overexpressed proteins, confirms that it is a universal labeling technique and is very sensitive when compared with Edman sequencing. Finally, we compared Edman sequencing and Nt-dimethylation of the same polypeptide fragments; results confirm that there is agreement in the identity of the Nt amino acid sequence between these 2 methods.     

Reduction and fluorescent labeling of cyst(e)ine-containing proteins for subsequent structural analyses

Procedures which allow rapid, quantitative, and selective fluorescent labeling of protein cyst(e)ine residues prior to electrophoresis by reaction with 4-(aminosulfonyl)-7-fluoro-2,1,3-benzoxadiazole (ABD-F) under mild conditions are described. After labeling, the protein(s) of interest is easily monitored throughout electrophoresis and subsequent electroblotting or electroelution procedures. The stoichiometry of labeling and therefore the number of cysteine and/or half-cystine residues can be measured spectrophotometrically or fluorometrically and the derived cyst(e)ine adduct can also be quantitated by amino acid analysis and identified in protein sequencing. N-terminal blockage is not observed under the conditions utilized, nor are any other amino acid side chains modified. The procedures described allow complete, rapid, and facile reduction and alkylation of proteins with simultaneous incorporation of a fluorophore, permitting sensitive detection in subsequent manipulation of the proteins. Quantitative fluorescence prelabeling also allows the generation, purification, and sequencing of peptide fragments containing cyst(e)ine residues for determination of internal sequences and residues involved in disulfide bonds.     

A label-free quantification method by MS/MS TIC compared to SILAC and spectral counting in a proteomics screen

In order to assess the biological function of proteins and their modifications for understanding signaling mechanisms within cells as well as specific biomarkers to disease, it is important that quantitative information be obtained under different experimental conditions. Stable isotope labeling is a powerful method for accurately determining changes in the levels of proteins and PTMs; however, isotope labeling experiments suffer from limited dynamic range resulting in signal change ratios of less than approximately 20:1 using most commercial mass spectrometers. Label-free approaches to relative quantification in proteomics such as spectral counting have gained popularity since no additional chemistries are needed. Here, we show a label-free method for relative quantification based on the TIC from peptide MS/MS spectra collected from data-dependent runs can be used effectively as a quantitative measure and expands the dynamic range over isotope labeling experiments allowing for abundance differences up to approximately 60:1 in a screen for proteins that bind to phosphotyrosine residues.