Efficient Enrichment Of Phosphopeptides Research Articles

Magnetically Responsive Fe3O4@C@SnO2 Core−Shell Microspheres: Synthesis, Characterization and Application in Phosphoproteomics

In this work, we synthesized core−shell magnetic tin dioxide (Fe3O4@C@SnO2) microspheres. The Fe3O4@C@SnO2 microspheres were applied to enrich phosphopeptides for mass spectrometry analysis. Different from titanium and zirconium,the regular sol−gel process is not effective in generating tin dioxide on the magnetite particles because the tin oxide tends to crystallize during the reaction. Herein, we reported a simple but effective method combining solvothermal and hydrothermal reactions to synthesize Fe3O4@C@SnO2 microspheres. The obtained Fe3O4@C@SnO2 microspheres have a mean diameter of 340 nm, well-crystallized SnO2 shell (∼30 in thickness), and high magnetization (63.8 emu/g). We have also demonstrated that Fe3O4@C@SnO2 microspheres are the promising materials for convenient, efficient enrichment of phosphopeptides by the analysis of phosphopeptides in standard protein digestion and real samples using MALDI MS and LC-ESI MS.

Phosphopeptide Enrichment Using MALDI Plates Modified with High-Capacity Polymer Brushes

Matrix-assisted laser desorption/ionization plates coated with poly(2-hydroxyethyl methacrylate) (PHEMA) brushes that are derivatized with Fe(III)-nitrilotriacetate (NTA) complexes allow selective, efficient phosphopeptide enrichment prior to analysis by mass spectrometry (MS). Fe(III)-NTA-PHEMA brushes (60 nm thick) have a phosphopeptide binding capacity of 0.6 microg/cm(2) and exhibit phosphopeptide recoveries of over 70%, whereas much thinner polymer films containing Fe(III)-NTA afford a recovery of only 20%, and a monolayer of Fe(III)-NTA shows a recovery of just 10%. Recoveries are determined by comparing signals from enriched unlabeled phosphopeptides with those of their deuterium-labeled analogues that were added to the plate just prior to addition of matrix. Mass spectra of phosphopeptide-containing samples enriched using Fe(III)-NTA-PHEMA-modified plates also demonstrate higher recoveries or fewer interfering peaks than corresponding spectra obtained with enrichment using several commercially available Fe(III)-containing films and resins or metal oxide materials. When analyzing tryptic digests of beta-casein, the Fe(III)-NTA-PHEMA brushes allow detection of as little as 15 fmol of phosphopeptide. Moreover, with both ovalbumin and beta-casein digests, phosphopeptide signals dominate the mass spectra obtained using these modified plates.

Highly efficient enrichment of phosphopeptides by magnetic nanoparticles coated with zirconium phosphonate for phosphoproteome analysis

The location of phosphorylation plays a vital role for the elucidation of biological processes. The challenge of low stoichiometry of phosphoproteins and signal suppression of phosphopeptides by nonphosphopeptides in mass spectrometry (MS) analysis makes the selective enrichment of phosphopeptides prior to MS analysis necessary. Besides the immobilized metal affinity chromatography (IMAC) method, some affinity methods based on nanoparticles displayed a higher enrichment efficiency for phosphopeptides such as Fe(3)O(4)/TiO2 and Fe(3)O(4)/ZrO(2) nanoparticles. To further improve the selectivity and compatibility of the affinity methods, a novel strategy based on magnetic nanoparticles coated with zirconium phosphonate for the enrichment of phosphopeptides has been developed in this study. Under optimized experimental conditions, 1 x 10(-9) M phosphopeptides in 50 microL tryptic digest of beta-casein could be enriched and identified successfully. Reliable results were also obtained for 1 x 10(-8) M phosphopeptides in 50 microL tryptic digest of beta-casein in the presence of nonphosphopeptides from a tryptic digest of bovine serum albumin (BSA) over 20 times in concentration. The performance of nanoparticles for use in a real sample was further demonstrated by employing the strong cation-exchange chromatography (SCX) fraction of a tryptic digest of a protein extract from Chang liver cells as a model sample. Experimental results show that the nanoparticles can be easily and effectively used for enrichment of phosphopeptides in low concentration. Most importantly, our approach is more compatible with commonly used SCX strategies than Fe(3+)-IMAC. The proposed method thus has great potential for future studies of large-scale phosphoproteomes.

Highly Efficient Phosphopeptide Enrichment by Calcium Phosphate Precipitation Combined with Subsequent IMAC Enrichment

A new method for enrichment of phosphopeptides in complex mixtures derived by proteolytic digestion of biological samples has been developed. The method is based on calcium phosphate precipitation of the phosphopeptides prior to further enrichment with established affinity enrichment methods. Calcium phosphate precipitation combined with phosphopeptide enrichment using Fe(III) IMAC provided highly selective enrichment of phosphopeptides. Application of the method to a complex peptide sample derived from rice embryo resulted in more than 90% phosphopeptides in the enriched sample as determined by mass spectrometry. Introduction of a two-step IMAC enrichment procedure after calcium phosphate precipitation resulted in observation of an increased number of phosphopeptides.

Development of a titanium dioxide nanoparticle pipette-tip for the selective enrichment of phosphorylated peptides

The selective enrichment of specific proteins or peptides on micropipette tips prior to mass spectrometry analysis, which can minimize non-specific interferences as well as sample loss, has been an important issue in current proteomics field. In this paper, we have developed an easy-to-use phosphopeptide-selective pipette tip in which titanium dioxide nanoparticles were embedded in monolithic structure photopolymerized from ethylene glycol dimethacrylate. The simple and convenient fabrication was feasible in a commercial polypropylene pipette tip. Phosphorylated peptides were isolated from non-phosphopeptides by TiO 2 nanoparticle and eluted by 100 mM ammonium phosphate (pH 8.5), which was compatible with 2,5-dihydroxybenzoic acid (DHB)/1% phosphoric acid matrix and allowed for direct analysis of the elution fraction by matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) without the necessity of desalting pretreatment. Tryptic digested α-casein and β-casein spiked into bovine serum albumin (BSA) nonphosphorylated peptides (molar ratio 1:1:10) were used to assess the selectivity of TiO 2 tips. The effect of 50 mM ammonium hydrogencarbonate, pH 8 in 50% acetonitrile used as a wash buffer in reduction of nonspecific bound peptide to TiO 2 tip was dramatic. Almost all non-phosphopeptides were not detected by MALDI-MS analysis. The lowest detectable amount of phosphopeptide was estimated at low femtomole level. The easy-to-use TiO 2-embeded tips operated in combination with the modified wash and elution conditions enable an efficient phosphopeptide enrichment for mass spectrometric analysis.

PI‐based phosphopeptide enrichment combined with nanoESI‐MS

IEF is introduced as a new principle for enrichment and separation of phosphopeptides as obtained after digestion of phosphoproteins by trypsin. Tryptic peptides and phosphopeptides exhibit pI values, which overlap in the range of about 4-6. However, after methyl esterification of all carboxyl functions, the pI values of tryptic peptides and phosphopeptides regroup in discrete clusters. In addition, mono- and diphosphorylated peptides show different but very homogeneous pI values, with variations when internal Arg, Lys, or His residues are present. Experimentally, this new concept was applied for separation of model peptides on IPG strips pH 3-10 as used in the first dimension of 2-DE. After IEF of methyl-esterified peptides, the IPG strip was cut into pieces followed by peptide extraction, desalting and MS analysis by nanoESI-MS. Phosphopeptides were found to focus in good agreement with their calculated pI values. This analytical strategy showed a resolution of about 0.2 pI units, and thus turned out to be capable of detecting minor differences in pI values, such as those occurring between pSer, pThr and pTyr residues. Using IPG strips with a pI range of 3-10, methyl esterified nonphosphorylated tryptic peptides are concentrated in the basic part of the IPG strip or even leave the strip. Thus, efficient enrichment of phosphopeptides and their subfractionation according to pI is obtained in one step. Minor hydrolytic side reactions including deamidation of Asn and partial hydrolysis of methyl esters are observed. The results show that IEF opens attractive avenues for the further advancement of analytical phosphoproteomics.

Enhancement of the Efficiency of Phosphoproteomic Identification by Removing Phosphates after Phosphopeptide Enrichment

Immobilized metal affinity chromatography (IMAC) and titanium oxide (TiO2) chromatography are simple, widely used, and cost-effective methods to enrich phosphopeptides, but the sample loading buffer composition, desalting procedure, and control of loading amount are critical to avoid nonspecific interactions and to achieve efficient phosphopeptide enrichment. Although the combination of MS3 analysis and high-resolution mass spectrometry (MS) is helpful to identify phosphopeptides, the quality of many MS/MS spectra having a neutral loss peak of phosphate is still too poor to allow sequence identification, and this results in many false-negative as well as false-positive identifications. Here, we present a novel strategy, which is based on the use of alkaline phosphatase to remove phosphates and analysis of phospho/dephosphopeptide retention times to increase the reliability of identification. The use of phospho/dephosphopeptide retention time ratios allows the identification of phosphopeptides with high confidence with the aid of a focused database of dephosphopeptides. This approach was very effective to identify multiple phophorylations in tryptic peptides. A 'true' phosphorylation data set should contain about 90% phospho-Ser and a few percent phospho-Tyr, and this ratio can be used as a quality criterion for evaluation of data sets. By applying this efficient approach, we were able to identify more than one thousand phosphopeptides.