Isolation and sequencing of alpha-tubulin peptides from myxamoebae of the slime mould Physarum polycephalum

Starting from only 5.9 mg of alpha-tubulin from myxamoebae of the slime mould Physarum polycephalum, we have isolated and sequenced peptides that account for 96% of the complete sequence. The peptides were generated by digestion of alpha-tubulin with trypsin, Staphylococcus aureus protease and cyanogen bromide. They were then separated according to size on a TSK G2000 SW column using a 10 mM ammonium acetate buffer at pH 6.8. In addition to good peptide separations, a time-consuming desalting step with subsequent loss of material was unnecessary because the relatively small amount of ammonium acetate could be removed by lyophilization. High resolution of peptides from the TSK fractions was achieved on C4 or C18 reverse-phase columns by eluting with a gradient of acetonitrile in 50 mM ammonium acetate (pH 6.8) and in 0.1% trifluoroacetic acid, respectively. The peptides were then sequenced using a gas phase sequencer.     

Concentration and desalting of peptide and protein samples with a newly developed C18 membrane in a microspin column format.

Protein identification plays an important role in today's academic and industrial proteomic research. Commonly used methods for the separation of proteins from complex samples include liquid chromatography (e.g., ion exchange, reversed-phase, hydrophobic interaction), or types of gel electrophoresis (e.g., 1d and 2d PAGE). Relevant proteins separated in the latter way are often cut out, cleaved with trypsin "in gel," and the resulting peptide mixtures combined with matrix and spotted onto a target plate for matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-ToF-ms) analysis. Subsequently, proteins can be identified by comparison of the resulting peptide mass fingerprints against different databases.(1) since the success of protein identification can be enhanced by the desalting and concentration of the samples, an innovative C18-membrane was incorporated into a microspin column (Vivapure C18 micro spin column, Vivascience AG, Hannover, Germany) to analyze its performance for sample preparation prior to MALDI-ToF-ms. Rapid concentration of single or multiple 200-microl volumes through an available membrane only 2 mm in diameter allowed for analysis of very dilute samples. We observed the successful and rapid desalting of urea-containing protein samples at 100 fmol/mul up to a mass of approximately 70 KDA and the concentration of digest peptides from a solution of 1 fmol/microl using C18-membrane technology.     

Enrichment of Amadori products derived from the nonenzymatic glycation of proteins using microscale boronate affinity chromatography

Amadori peptides were enriched using boronate affinity tips and measured by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF/MS). As demonstrated by electrochemical measurements, the tips show the highest binding efficiency for glucose at pH 8.2 employing ammonium chloride/ammonia buffer with ionic strength of 150 mM, exceeding taurine buffer at the same concentration. The bound constituents were released by sorbitol and formic acid. It was also demonstrated that elution with sorbitol at 1.2 M is superior to acidic media. Comparison of results was based on the numbers of detected peptides and their glycated sites. Using sorbitol for elution requires desalting prior to analysis. Therefore, three different sorbents were tested: fullerene-derivatized silica, ZipTip (C18), and C18 silica. Fullerene-derivatized silica and ZipTip showed the same performance regarding the numbers of glycated peptides, and sites were better than C18 silica. The elaborated off-line method was compared with liquid chromatography-tandem mass spectrometry (LC-MS/MS) measurements, by which considerable less modified peptides were detected. Affinity tips used under optimized conditions were tested for the analysis of human serum albumin (HSA) from sera of healthy and diabetic individuals. A peptide with a mass of 1783.9 Da could be detected only in samples of diabetic patients and, therefore, could be a very interesting biomarker candidate.     

Paraffin-wax-coated plates as matrix-assisted laser desorption/ionization sample support for high-throughput identification of proteins by peptide mass fingerprinting

We compared trysin-digested protein samples desalted by ZipTip(C18) reverse-phase microcolumns with on-plate washing of peptides deposited either on paraffin-coated plates (PCP), Teflon-based AnchorChip plates, or stainless steel plates, before analysis by matrix-assisted laser desorption/ionization-time of flight-mass spectrometry (MALDI-TOF-MS). Trypsinized bovine serum albumin and ovalbumin and 16 protein spots extracted from silver-stained two-dimensional gels of murine C(2)C(12) myoblasts or human leukocytes, prepared by the above two methods, were subjected to MALDI on PCP, AnchorChip plates, or uncoated stainless steel plates. Although most peptide mass peaks were identical regardless of the method of desalting and concentrating of protein samples, samples washed and concentrated by the PCP-based method had peptide peaks that were not seen in the samples prepared using the ZipTip(C18) columns. The mass spectra of peptides desalted and washed on uncoated stainless steel MALDI plates were consistently inferior due to loss of peptides. Some peptides of large molecular masses were apparently lost from samples desalted by ZipTip(C18) microcolumns, thus diminishing the quality of the fingerprint needed for protein identification. We demonstrate that the method of washing of protein samples on paraffin-coated plates provides an easy, reproducible, inexpensive, and high-throughput alternative to ZipTip(C18)-based purification of protein prior to MALDI-TOF-MS analysis.     

Modular stop and go extraction tips with stacked disks for parallel and multidimensional Peptide fractionation in proteomics

Proteome complexity necessitates protein or peptide separation prior to analysis. We previously described a pipet-tip based peptide micropurification system named StageTips (STop and Go Extraction Tips), which consists of a very small disk of membrane-embedded separation material. Here, we extend this approach in several dimensions by stacking disks containing reversed phase (C(18)) and strong cation exchange (SCX) materials. Multidimensional fractionation as well as desalting, filtration, and concentration prior to mass spectrometry in single or tandem columns is described. C(18)-SCX-C(18) stacked disks significantly improved protein identification by LC-MS/MS for an E. coli protein digest and by MALDI-MS for a 12 standard protein digest. Sequential fractionation based on C(18)- followed by SCX material was also developed. This multidimensional fractionation approach was expanded to parallel sample preparation by incorporating C(18)-SCX-StageTips into a 96-well plate (StagePlate). Fractions were collected into other C(18)-StagePlates and desalted and eluted in parallel to sample well plates or MALDI targets. This approach is suitable for high throughput protein identification for moderately complex, low abundance samples using automated nanoelectrospray-MS/MS or MALDI-MS.     

Direct micro-sequence analysis of peptides from Escherichia coli ribosomal proteins S11, L9 and L29 after separation by reversed phase chromatography

Tryptic peptides of the ribosomal proteins S11, L9 and L29 were separated by reversed phase chromatography under conditions which enabled direct micro-sequencing with the 4-(dimethylamino)azobenzene-4'-isothiocyanate/phenylisothiocyanate double coupling method [Chang, Brauer, Wittmann-Liebold (1978) FEBS Lett. 93, 205-214]. The peptides were separated on a RP-18 column employing volatile buffers at pH 2.0, 4.1 and 7.8. Depending on the different chromatographic behaviour of the peptide mixture, the elution gradient was optimised for each hydrolysate using 20 micrograms of the hydrolysed protein. Preparative separations were made with 150-250 micrograms. At least 80% of the peptides could be isolated by these techniques and used for direct micro-sequencing without further purification or desalting. The results show that the high-performance liquid chromatographic method employed allows easy isolation and sequencing with minute amounts of peptides.     

Reaction of phosphorylated and O-glycosylated peptides by chemically targeted identification at ambient temperature.

Conditions for carrying out chemically targeted identification of peptides containing phosphorylated or glycosylated serine residues have been investigated. Ba(OH)2 was used at ambient temperature to catalyze the beta-elimination reaction at 25 degrees C. Nucleophilic addition of 2-aminoethanethiol was performed in both parallel and tandem experiments. The method was demonstrated by the reaction of beta-casein tryptic digest phosphopeptides and an O-glycosylated peptide. Contrary to an earlier report by others, the glycopeptide was found to react with essentially the same kinetics as phosphopeptides. Conversion of four phosphoserines in residues 15, 17, 18, and 19 from bovine beta-casein N-terminal tryptic phosphopeptides were followed by monitoring the time course of the addition reaction. The chemistry proceeded rapidly at room temperature with a half-reaction time of 15 min. No side-reaction products were observed; however, care was taken to minimize all counter ions that either precipitate barium or neutralize the base. Digestion of the converted peptides with lysine endopeptidase identified all five phosphoserines in the beta-casein tryptic digest. Alternatively, preincubation with base followed by nucleophilic addition of the thiol was found to work satisfactorily. The use of the water-soluble hydrochloride of 2-aminoethanethiol allowed beta-elimination, nucleophilic addition, and desalting to be carried out on a micro C18 reverse phase pipette tip.     

The structure and amount of actin in IMR-90 fibroblasts.

Double-labelling and peptide isolation have been used to examine the homology between the actin of IMR-90 human embryo fibroblasts and muscle actin. After separation of mixtures of [14C]carboxymethylated muscle actin and [3H]carboxymethylated proteins of IMR-90 cells of electrophoresis on sodium dodecyl sulphate-containing polyacrylamide gels, peptides were generated from the material co-migrating with actin by digestion with chymotrypsin. Peptides homologous with peptides accounting for Cys-217, Cys-256, Cys-284 and Cys-373 of muscle actin are present in this material, but no peptide homologous with a Cys-10-containing peptide was detected. From the amount of actin-derived peptides present, the actin content of IMR-90 fibroblasts was calculated to be 4.2% of the total protein of these cells.     

Poly(glycidyl methacrylate/divinylbenzene)-IDA-FeIII in phosphoproteomics

The study of protein phosphorylation has grown exponentially in recent years, as it became evident that important cellular functions are regulated by phosphorylation and dephosphorylation of proteins on serine, threonine and tyrosine residues. The use of immobilized metal affinity chromatography (IMAC) to enrich phosphopeptides from peptide mixtures has been shown to be useful especially prior to mass spectrometric analysis. For the selective enrichment applying solid-phase extraction (SPE) of phosphorylated peptides, we introduce poly(glycidyl methacrylate/divinylbenzene) (GMD) derivatized with imino-diacetic acid (IDA) and bound Fe(III) as a material. GMD is rapidly synthesized and the resulting free epoxy groups enable an easy access to further derivatization with, e.g., IDA. Electron microscopy showed that the synthesized GMD-IDA-Fe(III) for SPE has irregular agglomerates of spherical particles. Inductively coupled plasma (ICP) analysis resulted in a metal capacity of Fe(III) being 25.4 micromol/mL. To enable on-line preconcentration and desalting in one single step, GMD-IDA-Fe(III) and Silica C18 were united in one cartridge. Methyl esterification (ME) of free carboxyl groups was carried out to prevent binding of nonphosphorylated peptides to the IMAC function. The recovery for a standard phosphopeptide using this SPE method was determined to be 92%. The suitability of the established system for the selective enrichment and analysis of model proteins phosphorylated at different amino acid residues was evaluated stepwise. After successful enrichment of beta-casein deriving phosphopeptides, the established system was extended to the analysis of in vitro phosphorylated proteins, e.g. deriving from glutathione-S-transferase tagged extracellular signal regulated kinase 2 (GST-ERK2).     

Downsizing improves sensitivity 100-fold for hydrogen exchange-mass spectrometry

This paper describes a method that substantially improves the sensitivity of high-performance liquid chromatography hydrogen exchange-mass spectrometry (HPLC HX MS). The success of this method relies on using a capillary HPLC column (0.1mm IDx5cmL) to increase the sensitivity of electrospray ionization, while keeping analysis times short to minimize hydrogen/deuterium (H/D) exchange. A small, immobilized pepsin column and a capillary C18 trap were included in the capillary HPLC MS system to provide rapid digestion, peptide concentration, and desalting while maintaining slow H/D exchange conditions. To minimize the analysis time, dead volumes and capacities of all components were optimized. Fully deuterated cytochrome c and its fully deuterated peptic peptides were used to evaluate deuterium recovery at amide linkages. The deuterium recovery measured at low flow rates using this system spanned a range of 66-77% (average of 71%), which was similar to the range measured for a much larger system (67-80%, average 75%). Signal levels of most peptides for the downsized system increased by about 100-fold compared with the signal for the larger system. These results greatly strengthen the HPLC HX MS technique for studies where the quantity of protein is small.     

An improved protocol for coupling synthetic peptides to carrier proteins for antibody production using DMF to solubilize peptides.

We present an improved protocol for coupling synthetic peptides to carrier proteins. In this protocol, dimethyl-formamide is used as the solvent to solubilize peptides instead of phosphate-buffered saline (PBS) or 6 M guanidine-HCl/0.01 M phosphate buffer (pH 7). Additionally, the last desalting or dialyzing step to remove uncoupled peptides as in the traditional method is eliminated. Finally, 3 ml of 0.1 M ammonium bicarbonate is added to the carrier protein conjugated peptide solution to help the lyophilization process. Coupling of Cys-containing synthetic peptides to keyhole limpet hemocyanin or bovine serum albumin using m-maleimidobenzoyl-N-hydroxysuccinimide ester are used as the test cases. This method produces high-quality antipeptide antibodies. Also, compared to the traditional method, this procedure is simpler and useful for peptides with solubility problems in PBS or 6 M guanidine-HCl.     

Concerted experimental approach for sequential mapping of peptides and phosphopeptides using C18-functionalized magnetic nanoparticles

An integrated analytical approach for the enrichment, detection, and sequencing of phosphopeptides using matrix-assisted laser desorption/ionization (MALDI) tandem mass spectrometry (MS) was developed. On the basis of C18-functionalized Fe3O4 nanoparticles, the enrichment method was designed not only to specifically trap phosphopeptides, but also nonphosphorylated peptides, both of which can be subsequently desorbed selectively and directly for MALDI-MS analysis without an elution step. Peptide binding is afforded by the C18-derivatization, whereas the highly selective capture of phosphopeptides is based on higher binding affinity afforded by additional metal chelating interaction between the Fe3O4 nanoparticles and the phosphate groups. Upon binding, the initial aqueous wash allows desalting, while a second and a third wash with high acetonitrile content coupled with diluted sulfuric acid and ammonia removes most of the bound nonphosphorylated peptides. Selective or sequential mapping of the peptides and phosphopeptides can, thus, be effected by spotting the washed nanoparticles onto the MALDI target plate along with judicious choice of matrices. The inclusion of phosphoric acid in a 2,5-dihydroxybenzoic acid matrix allows the desorption and detection of phosphopeptides, whereas an alpha-cyano-4-hydroxy-cinnamic acid matrix with formic acid allows only the desorption of nonphosphorylated peptides. The method used to enrich phosphopeptides prior to MS applications is more sensitive and tolerable to sodium dodecyl sulfate than IMAC. We have demonstrated the applicability of C18-functionalized Fe3O4 nanoparticles in the detection of in vitro phosphorylation sites on the myelin basic protein, and at least 17 phosphopeptides were identified, including one previously uncharacterized site.     

Targeting peptides and positron emission tomography

Biologically active peptides have during the last decades made their way into conventional nuclear medicine diagnosis using single photon emission computed tomography (SPECT) and gamma-camera. Several clinical trails are also investigating the role of radiolabeled peptides for targeting radionuclide therapy. This has raised the question as to whether positron emission tomography (PET) can be used in order to obtain better quantitative information of the peptide distribution in tumor and healthy organs, i.e., to get a better dosimetry. Positron emitting analogs of the therapeutic radionuclides used have been produced and successfully applied in peptide pharmacokinetic measurements with PET. But the recent boom in (18)FDG-PET ((18)FDG = [(18)F]2-deoxy-2-fluoro-D-glucose), and with this a worldwide increasing number of PET systems, has also inspired several research groups to hunt for alternative labels to be used for peptide diagnostics and PET. The rapid kinetic of short peptides agrees well with the short half-lives of standard PET nuclides like (11)C and (18)F. Especially, (18)F appears to be excellent for labeling bioactive peptides due to its favorable physical and nuclear characteristics. However, with present techniques labeling peptides with (18)F is laborious and time-consuming, and is not yet a clinical alternative. Other halogens like (75, 76)Br and (124)I are, from the chemical point of view, easier to apply. But an even better labeling alternative may be positron emitting metal ions like (55)Co, (68)Ga, and (110m)In since they tend to give better intracellular retention and thus a better signal-to-background ratio than the halogen labels. The main drawback with these radionuclides is that they are not readily available. Some of these radionuclides also emit gamma in their decay that may affect the measuring properties of the PET equipment. This article reviews mainly the present situation of production and use of nonconventional positron emitters for peptide labeling.     

A physicochemical approach for predicting the effectiveness of peptide-based gene delivery systems for use in plasmid-based gene therapy.

Novel synthetic peptides, based on carrier peptide analogs (YKAKnWK) and an amphipathic peptide (GLFEALLELLESLWELLLEA), have been formulated with DNA plasmids to create peptide-based gene delivery systems. The carrier peptides are used to condense plasmids into nanoparticles with a hydrodynamic diameter (DH) ranging from 40 to 200 nm, which are sterically stable for over 100 h. Size and morphology of the carrier peptide/plasmid complex have been determined by photon correlation spectroscopy (PCS) and transmission electron microscopy (TEM), respectively. The amphipathic peptide is used as a pH-sensitive lytic agent to facilitate release of the plasmid from endosomes after endocytosis of the peptide/plasmid complex. Hemolysis assays have shown that the amphipathic peptide destabilizes lipid bilayers at low pH, mimicking the properties of viral fusogenic peptides. However, circular dichroism studies show that unlike the viral fusion peptides, this amphipathic peptide loses some of its alpha-helical structure at low pH in the presence of liposomes. The peptide-based gene delivery systems were tested for transfection efficiency in a variety of cell lines, including 14-day C2C12 mouse myotubes, using gene expression systems containing the beta-galactosidase reporter gene. Transfection data demonstrate a correlation between in vitro transfection efficiency and the combination of several physical properties of the peptide/plasmid complexes, including 1) DNA dose, 2) the zeta potential of the particle, 3) the requirement of both lytic and carrier peptides, and 4) the number of lysine residues associated with the carrier peptide. Transfection data on 14-day C2C12 myotubes utilizing the therapeutic human growth hormone gene formulated in an optimal peptide gene delivery system show an increase in gene expression over time, with a maximum in protein levels at 96 h (approximately 18 ng/ml).     

An in-gel digestion procedure that facilitates the identification of highly hydrophobic proteins by electrospray ionization-mass spectrometry analysis

A procedure is described for in-gel tryptic digestion of proteins that allows the direct analysis of eluted peptides in electrospray ionization (ESI) mass spectrometers without the need of a postdigestion desalting step. It is based on the following principles: (a) a thorough desalting of the protein in-gel before digestion that takes advantage of the excellent properties of acrylamide polymers for size exclusion separations, (b) exploiting the activity of trypsin in water, in the absence of inorganic buffers, and (c) a procedure for peptide extraction using solvents of proven efficacy with highly hydrophobic peptides. Quality of spectra and sequence coverage are equivalent to those obtained after digestion in ammonium bicarbonate for hydrophilic proteins detected with Coomassie blue, mass spectrometry-compatible silver or imidazole-zinc but are significantly superior for highly hydrophobic proteins, such as membrane proteins with several transmembrane domains. ATPase subunit 9 (GRAVY 1.446) is a membrane protein channel, lipid-binding protein for which both the conventional in-gel digestion protocol and in solution digestion failed. It was identified with very high sequence coverage. Sample handling after digestion is notably simplified as peptides are directly loaded into the ESI source without postdigestion processing, increasing the chances for the identification of hydrophobic peptides.     

Membrane thickening by the antimicrobial peptide PGLa

Using x-ray diffraction, solid-state ²H-NMR, differential scanning calorimetry, and dilatometry, we have observed a perturbation of saturated acyl chain phosphatidylglycerol bilayers by the antimicrobial peptide peptidyl-glycylleucine-carboxyamide (PGLa) that is dependent on the length of the hydrocarbon chain. In the gel phase, PGLa induces a quasi-interdigitated phase, previously reported also for other peptides, which is most pronounced for C18 phosphatidylglycerol. In the fluid phase, we found an increase of the membrane thickness and NMR order parameter for C14 and C16 phosphatidylglycerol bilayers, though not for C18. The data is best understood in terms of a close hydrophobic match between the C18 bilayer core and the peptide length when PGLa is inserted with its helical axis normal to the bilayer surface. The C16 acyl chains appear to stretch to accommodate PGLa, whereas tilting within the bilayer seems to be energetically favorable for the peptide when inserted into bilayers of C14 phosphatidylglycerol. In contrast to the commonly accepted membrane thinning effect of antimicrobial peptides, the data demonstrate that pore formation does not necessarily relate to changes in the overall bilayer structure.     

Facile analysis and purification of deblocked N-terminal pyroglutamyl peptides with a strong cation-exchange sulfoethyl aspartamide column

A high-performance strong cation-exchange Sulfoethyl Aspartamide column was used to analyze and purify five N-terminal pyroglutamyl peptides after treatment with Pyroglutamate Aminopeptidase. The resulting deblocked N-1 peptides possess an increased positive charge and are therefore retained to a greater extent by the column. Salt gradient elution in a pH 3 mobile phase was then used to recover the desired peptides and the purified deblocked peptides were directly subjected to N-terminal sequence analysis. The same digests were also chromatographed on a C18 reversed-phase column using standard trifluoroacetic acid-acetonitrile gradient elution. The elution order for the parent peptide and the N-1 peptide on the reversed-phase column was reversed from that on the Sulfoethyl Aspartamide column and the resolution of the two peptides obtained on the reversed-phase column was less than that observed on the cation-exchange column. In addition, the Sulfoethyl Aspartamide column was shown to be useful to monitor the extent of N-terminal glutamine cyclization formed during peptide purification and storage.     

A computational method for selecting short peptide sequences for inorganic material binding

Discovering or designing biofunctionalized materials with improved quality highly depends on the ability to manipulate and control the peptide‐inorganic interaction. Various peptides can be used as assemblers, synthesizers, and linkers in the material syntheses. In another context, specific and selective material‐binding peptides can be used as recognition blocks in mining applications. In this study, we propose a new in silico method to select short 4‐mer peptides with high affinity and selectivity for a given target material. This method is illustrated with the calcite (104) surface as an example, which has been experimentally validated. A calcite binding peptide can play an important role in our understanding of biomineralization. A practical aspect of calcite is a need for it to be selectively depressed in mining sites.     

Quantitation of binding, recovery and desalting efficiency of peptides and proteins in solid phase extraction micropipette tips

Micropipette-tip solid phase extraction (SPE) systems are common in proteomic analyses for desalting and concentrating samples for mass spectrometry, removing interferences, and increasing sensitivity. These systems are inexpensive, disposable, and highly efficient. Here, we show micropipette-tip solid phase extraction is a direct sample preparation method for (14)C-accelerator mass spectrometry (AMS), removing salts or reagent from labeled macromolecules. We compared loading, recovery and desalting efficiency in commercially available SPE micro-tips using (14)C-labeled peptides and proteins, AMS, and alpha spectrometry ion energy loss quantitation. The polypropylene in the tips was nearly (14)C-free and simultaneously provided low-background carrier for AMS. The silica material did not interfere with the analysis. Alpha spectrometry provided an absolute measurement of desalting efficiency.     

Graphite powder as an alternative or supplement to reversed-phase material for desalting and concentration of peptide mixtures prior to matrix-assisted laser desorption/ionization-mass spectrometry

The success attributed to identification and characterization of gel separated proteins by mass spectrometry (MS) is highly dependent on the percentage of an entire sequence covered by matching peptides derived from enzymatic digestion. Desalting and concentration of peptide mixtures on reversed-phase (RP) microcolumns prior to mass spectrometric analysis have resulted in increased signal-to-noise ratio and sensitivity, and consequently higher sequence coverage. A large proportion of peptides, however, remains undetected by MS presumably because they are lost during sample preparation on microcolumns, or are suppressed in the ionization process. We report here the use of graphite powder packed in constricted GELoader tips as an alternative to RP microcolumns for desalting and concentration of peptide mixtures prior to MS. Such columns are able to retain small and/or hydrophilic peptides that can be lost when using RP microcolumns. In addition, we show that samples contaminated with small biological polymers can readily be analyzed using graphite powder rather than RP microcolumns, since the polymer molecules bind strongly to graphite and are not eluted with the peptides.