Preparation of Fe3O4@ZrO2 core-shell microspheres as affinity probes for selective enrichment and direct determination of phosphopeptides using matrix-assisted laser desorption ionization mass spectrometry

Fe3O4@ZrO2 microspheres with well-defined core-shell structure were prepared and applied for the highly selective enrichment of phosphopeptides from tryptic digest product of proteins. To successfully coat iron oxide microspheres with uniform zirconia shell, magnetic Fe3O4 microspheres were first synthesized via a solvothermal reaction, followed by being coated with a thin layer of carbon by polymerization and carbonization of glucose through hydrothermal reaction. Finally, with the use of the Fe3O4@C microspheres as templates, zirconium isopropoxide was prehydrolyzed and absorbed onto the microspheres and eventually converted into zirconia by calcinations. The as-prepared Fe3O4@ZrO2 core-shell microspheres were used as affinity probes to selectively concentrate phosphopeptides from tryptic digest of beta-casein, casein, and five protein mixtures to exemplify their selective enrichment ability of phosphopeptides from complex protein samples. In only 0.5 min, phosphopeptides sufficient for characterization by MALDI-MS could be enriched by the Fe3O4@ZrO2 microspheres. The results demonstrate that Fe3O4@ZrO2 microspheres have the excellent selective enrichment capacity for phosphopeptides from complex samples. The performance of the Fe3O4@ZrO2 microspheres was further compared with commercial IMAC beads for the enrichment of peptides originating from tryptic digestion of beta-casein and bovine serum albumin (BSA) with a molar ratio of 1:50, and the results proved a stronger selective ability of Fe3O4@ZrO2 microspheres over IMAC beads. Finally, the Fe3O4@ZrO2 microspheres were successfully utilized for enrichment of phosphopeptides from human blood serum without any other purification procedures.     

Cerium ion-chelated magnetic silica microspheres for enrichment and direct determination of phosphopeptides by matrix-assisted laser desorption ionization mass spectrometry

In this study, we employed, for the first time, the Ce4+-chelated magnetic silica microspheres to selectively concentrate phosphopeptides from protein digest products. Cerium ions were chelated onto magnetic silica microspheres using the strategy we established before. After enrichment, the phosphopeptide-conjugated magnetic microspheres were separated from the sample solution just by using a magnet. With the optimized enrichment conditions, the performance of the Ce4+-chelated magnetic microspheres was compared with the Fe3+-chelated microspheres using tryptic digested peptides originating from ovalbumin, a five protein mixture containing phosphoproteins and nonphosphoproteins, as well as a mixture of beta-casein and BSA with a molar ratio of 1:50. Compared to Fe3+, Ce4+-chelated magnetic microspheres exhibited more selective isolation ability for concentrating phosphopeptides from complex mixtures. Even when the amount of the tryptic digest product of BSA is 50 times higher than that of beta-casein in the sample solution, the trace phosphopeptides derived from beta-casein can still be concentrated effectively by the Ce4+-chelated magnetic microspheres in only 30 s. Furthermore, we initially utilized the Ce4+-chelated magnetic microspheres to directly enrich phosphopeptides from human serum without extra purification steps or tedious treatment, which opens up a possibility for their further application in phosphoproteomics.     

Novel Fe3O4@TiO2 core-shell microspheres for selective enrichment of phosphopeptides in phosphoproteome analysis

Due to the dynamic nature and low stoichiometry of protein phosphorylation, enrichment of phosphorylated peptides from proteolytic mixtures is often necessary prior to their characterization by mass spectrometry. Immobilized metal affinity chromatography (IMAC) is a popular way to enrich phosphopeptides; however, conventional IMAC lacks enough specificity for efficient phosphoproteome analysis. In this study, novel Fe 3O 4@TiO 2 microspheres with well-defined core-shell structure were prepared and developed for highly specific purification of phosphopeptides from complex peptide mixtures. The enrichment conditions were optimized using tryptic digests of beta-casein, and the high specificity of the Fe 3O 4@TiO 2 core-shell microspheres was demonstrated by effectively enriching phosphopeptides from the digest mixture of alpha-casein and beta-casein, as well as a five-protein mixture containing nonphosphoproteins (bovine serum albumin (BSA), myoglobin, cytochrome c) and phosphoproteins (ovalbumin and beta-casein). The Fe 3O 4@TiO 2 core-shell microspheres were further successfully applied for the nano-LC-MS/MS analysis of rat liver phosphoproteome, which resulted in identification of 56 phosphopeptides (65 phosphorylation sites) in mouse liver lysate in a single run, indicating the excellent performance of the Fe 3O 4@TiO 2 core-shell microspheres.     

Enrichment of phosphopeptides using biphasic immobilized metal affinity-reversed phase microcolumns

Immobilized metal affinity chromatography (IMAC) based on Fe (3+) or Ga (3+) chelation is the most widely employed technique for the enrichment of phosphopeptides from biological samples prior to mass spectrometric analysis. An IMAC resin geared mainly toward phosphoprotein enrichment, Pro-Q Diamond, has been assessed for its utility in phosphopeptide isolation. Using both single phosphoprotein tryptic digests of beta-casein and ovalbumin and synthetic mixtures composed of tryptic digests of phosphorylated and nonphosphorylated protein standards, the selectivity and sensitivity of Pro-Q Diamond resin in an immobilized metal affinity-reversed phase microcolumn format were compared to an alternate titanium dioxide approach. The biphasic microcolumn method was found to be superior to metal oxide-based phosphopeptide capture in biological samples of increasing complexity. The lower limit of mass spectrometric detection for the immobilized metal affinity-reversed phase microcolumn approach was determined to be 10 pmol of beta-casein monophosphorylated peptide in 20 muL of a solution of human serum protein digest (from 200 mug total serum protein after digestion and desalting).     

Zirconium phosphonate-modified porous silicon for highly specific capture of phosphopeptides and MALDI-TOF MS analysis

Phosphorylation is one of the most important post-translational modifications of proteins, which modulates a wide range of biological functions and activity of proteins. The analysis of phosphopeptides is still one of the most challenging tasks in proteomics research by mass spectrometry. In this study, a novel phosphopeptide enrichment approach based on the strong interaction of zirconium phosphonate (ZrP) modified surface with phosphopeptides has been developed. ZrP modified porous silicon (ZrP-pSi) wafer was prepared to specifically capture the phosphopeptides from complex peptide mixtures, and then the captured phosphopeptides were analyzed by MALDI-TOF MS by directly placing the wafer on a MALDI target. The phosphopeptide enrichment and MALDI analysis were both performed on the ZrP-pSi wafer which significantly reduced the sample loss and simplified the analytical procedures. The prepared ZrP-pSi wafer has been successfully applied for the enrichment of phosphopeptides from the tryptic digest of standard phosphoproteins beta-casein and alpha-casein. The excellent selectivity of this approach was demonstrated by analyzing phosphopeptides in the digest mixture of beta-casein and bovine serum albumin with molar ratio of 1:100. High detection sensitivity has been achieved for the analysis of the phosphopeptides from tryptic digestion of 2 fmol beta-casein on the ZrP-pSi surface.     

Preparation of magnetic core-mesoporous shell microspheres with C8-modified interior pore-walls and their application in selective enrichment and analysis of mouse brain peptidome

In this paper, magnetic mesoporous silica microspheres with C8-modified interior pore-walls were prepared through a facile one-pot sol-gel coating strategy, and were successfully applied for selective enrichment of endogenous peptides in mouse brain for peptidome analysis. Through the one-pot sol-gel approach with surfactant (CTAB) as a template, tetraethyl orthosilicate (TEOS) and n-ctyltriethoxysilane (C8TEOS) as the precursors, C8-modified magnetic mesoporous microspheres (C8-Fe(3)O(4)@mSiO(2)) consisting magnetic core and mesoporous silica shell with C8-groups exposed in the mesopore channels were synthesized. The obtained microspheres possess highly open mesopores of 3.4 nm, high surface area (162.5 m(2)/g), large pore volume (0.17 cm(3)/g), excellent magnetic responsivity (56.3 emu/g) and good dispersibility in aqueous solution. Based on the abundant surface silanol groups, functional C8 groups and the strong magnetic responsivity of the core-shell C8-Fe(3) O(4) @mSiO(2) microspheres, efficient and fast enrichment of peptides was achieved. Additionally, the C8-Fe(3)O(4)@mSiO(2) microspheres exhibit excellent performance in selective enrichment of endogenous peptides from complex samples that are consist of peptides, large proteins and other compounds, including human serum and mouse brain followed by automated nano-LC-ESI-MS/MS analysis. These results indicate C8-Fe(3)O(4)@mSiO(2) microspheres would be a potential candidate for endogenous peptides enrichment and biomarkers discovery in peptidome analysis.     

Rapid enrichment of phosphopeptides from tryptic digests of proteins using iron oxide nanocomposites of magnetic particles coated with zirconia as the concentrating probes

Iron oxide nanocomposites of magnetic particles coated with zirconia were used as affinity probes to selectively concentrate phosphopeptides from tryptic digests of alpha- and beta-caseins, milk, and egg white to exemplify the enrichment of phosphopeptides from complex samples. Phosphopeptides, in quantities sufficient for characterization by matrix-assisted laser desorption/ionization mass spectrometry (MALDI MS), were enriched by the affinity probes within only 30 s. The affinity probe-target species conjugates were separated from the sample solution simply by applying an external magnetic field. The detection limit for tryptic digest of beta-casein using this approach is approximately 45 fmol. Furthermore, we combined this enrichment method with a rapid enzymatic digestion method, that is, microwave-assisted enzymatic digestion using magnetic particles as the microwave absorbers, to speed up the tryptic digest reactions. Thus, we alternatively enriched phosphoproteins on the zirconia-coated particles followed by mixing with trypsin and heated the mixture in a microwave oven for 1 min. The particles remaining in the mixture were used as affinity probes to selectively enrich phosphopeptides from the tryptic digestion product by pipetting, followed by characterization using MALDI MS. Using the bifunctional zirconia-coated magnetic particles as both the affinity probes and the microwave absorbers could greatly reduce the time for the purification and characterization of phosphopeptides from complex samples.     

Designed synthesis of fluorous‐functionalized magnetic mesoporous microspheres for specific enrichment of phosphopeptides with fluorous derivatization

In this work, for the first time, perfluorinated magnetic mesoporous microspheres were designed and synthesized for the highly specific enrichment of fluorous‐derivatized phosphopeptides through the unique fluorine–fluorine interactions. The perfluorinated magnetic mesoporous microspheres were prepared through a surfactant‐mediated one‐pot approach and successfully applied to the selective extraction of fluorous‐derivatized phosphopeptides from β‐casein tryptic digest, protein mixtures, and human serum. Thanks to the hydrophilic silanol groups exposed on the surface, perfluorinated groups modified in the pore channels and the magnetic cores, the flourous‐functionalized magnetic microspheres exhibited excellent dispersibility, specificity toward fluorous‐derivatized phosphopeptides while facilitated separation procedures. The novel composites achieved a high selectivity of 1:1000 toward nonphosphorylated peptides and proved to be practicable in the enrichment of endogenous phosphopeptides in the human serum sample.     

Specific phosphopeptide enrichment with immobilized titanium ion affinity chromatography adsorbent for phosphoproteome analysis

The elucidation of protein post-translational modifications, such as phosphorylation, remains a challenging analytical task for proteomic studies. Since many of the proteins targeted for phosphorylation are low in abundance and phosphorylation is typically substoichiometric, a prerequisite for their identification is the specific enrichment of phosphopeptide prior to mass spectrometric analysis. Here, we presented a new method termed as immobilized titanium ion affinity chromatography (Ti (4+)-IMAC) for enriching phosphopeptides. A phosphate polymer, which was prepared by direct polymerization of monomers containing phosphate groups, was applied to immobilize Ti (4+) through the chelating interaction between phosphate groups on the polymer and Ti (4+). The resulting Ti (4+)-IMAC resin specifically isolates phosphopeptides from a digest mixture of standard phosphoproteins and nonphosphoprotein (BSA) in a ratio as low as 1:500. Ti (4+)-IMAC was further applied for phosphoproteome analysis of mouse liver. We also compared Ti (4+)-IMAC to other enrichment methods including Fe (3+)-IMAC, Zr (4+)-IMAC, TiO 2 and ZrO 2, and demonstrate superior selectivity and efficiency of Ti (4+)-IMAC for the isolation and enrichment of phosphopeptides. The high specificity and efficiency of phosphopeptide enrichment by Ti (4+)-IMAC mainly resulted from the flexibility of immobilized titanium ion with spacer arm linked to polymer beads as well as the specific interaction between immobilized titanium ion and phosphate group on phosphopeptides.     

Immobilized zirconium ion affinity chromatography for specific enrichment of phosphopeptides in phosphoproteome analysis

Large scale characterization of phosphoproteins requires highly specific methods for purification of phosphopeptides because of the low abundance of phosphoproteins and substoichiometry of phosphorylation. Enrichment of phosphopeptides from complex peptide mixtures by IMAC is a popular way to perform phosphoproteome analysis. However, conventional IMAC adsorbents with iminodiacetic acid as the chelating group to immobilize Fe(3+) lack enough specificity for efficient phosphoproteome analysis. Here we report a novel IMAC adsorbent through Zr(4+) chelation to the phosphonate-modified poly(glycidyl methacrylate-co-ethylene dimethacrylate) polymer beads. The high specificity of Zr(4+)-IMAC adsorbent was demonstrated by effectively enriching phosphopeptides from the digest mixture of phosphoprotein (alpha- or beta-casein) and bovine serum albumin with molar ratio at 1:100. Zr(4+)-IMAC adsorbent was also successfully applied for the analysis of mouse liver phosphoproteome, resulting in the identification of 153 phosphopeptides (163 phosphorylation sites) from 133 proteins in mouse liver lysate. Significantly more phosphopeptides were identified than by the conventional Fe(3+)-IMAC approach, indicating the excellent performance of the Zr(4+)-IMAC approach. The high specificity of Zr(4+)-IMAC adsorbent was found to mainly result from the strong interaction between chelating Zr(4+) and phosphate group on phosphopeptides. Enrichment of phosphopeptides by Zr(4+)-IMAC provides a powerful approach for large scale phosphoproteome analysis.     

Highly selective enrichment of phosphopeptides by on‐chip indium oxide functionalized magnetic nanoparticles coupled with MALDI‐TOF MS

Selective and efficient preconcentration is indispensable for low concentration of phosphopeptides in phosphorylated protein‐related samples prior to MS‐based analysis. Herein, an on‐chip system coupled magnetic SPE with MALDI‐TOF MS was designed. A metal oxide affinity chromatography material, indium oxide, was coated on the surface of Fe₃O₄ magnetic nanoparticles to prepare the adsorbent, spatially confined with an applied magnetic field. The adsorbent exhibited high selectivity for phosphopeptides in tryptic digests of the mixture of β‐casein and BSA (1:1000) and the mixture of β‐casein, BSA, and ovalbumin (1:100:100). Thanking to the enrichment ability and specificity for phosphopeptides with the adsorbent, the on‐chip magnetic SPE‐MALDI‐TOF MS approach showed high sensitivity with a low detection limit of 4 fmol. In addition, the developed approach was used to analyze phosphopetides in non‐fat milk digests and human serum successfully.     

Large-scale phosphoproteome analysis of human liver tissue by enrichment and fractionation of phosphopeptides with strong anion exchange chromatography

The mixture of phosphopeptides enriched from proteome samples are very complex. To reduce the complexity it is necessary to fractionate the phosphopeptides. However, conventional enrichment methods typically only enrich phosphopeptides but not fractionate phosphopeptides. In this study, the application of strong anion exchange (SAX) chromatography for enrichment and fractionation of phosphopeptides was presented. It was found that phosphopeptides were highly enriched by SAX and majority of unmodified peptides did not bind onto SAX. Compared with Fe(3+) immobilized metal affinity chromatography (Fe(3+)-IMAC), almost double phosphopeptides were identified from the same sample when only one fraction was generated by SAX. SAX and Fe(3+)-IMAC showed the complementarity in enrichment and identification of phosphopeptides. It was also demonstrated that SAX have the ability to fractionate phosphopeptides under gradient elution based on their different interaction with SAX adsorbent. SAX was further applied to enrich and fractionate phosphopeptides in tryptic digest of proteins extracted from human liver tissue adjacent to tumorous region for phosphoproteome profiling. This resulted in the highly confident identification of 274 phosphorylation sites from 305 unique phosphopeptides corresponding to 168 proteins at false discovery rate (FDR) of 0.96%.     

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.     

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.     

Enrichment of phosphopeptides by Fe3+-immobilized mesoporous nanoparticles of MCM-41 for MALDI and nano-LC-MS/MS analysis

Fe3+-immobilized mesoporous molecular sieves MCM-41 with particle size of ca. 600 nm and pore size of ca. 3 nm is synthesized and applied to selectively trap and separate phosphopeptides from tryptic digest of proteins. For the capture of phosphopeptides, typically 10 microL of tryptic digest solution was first diluted to 1 mL by solution of ACN/0.1% TFA (50:50, v/v) and incubated with 10 microL of 0.1% acetic acid dispersed Fe3+-immobilized MCM-41 for 1 h under vibration. Fe3+-immobilized MCM-41 with trapped phosphopeptides was separated by centrifugation. The deposition was first washed with a volume of 300 microL of solution containing 100 mM NaCl in ACN/0.1% TFA (50:50, v/v) and followed by a volume of 300 microL of solution of 0.1% acetic acid to remove nonspecifically bound peptides. The nanoparticles with trapped phosphopeptides are mixed with 2,5-dihydroxybenzoic acid (2,5-DHB) and deposited onto the target for analysis by matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS). It was found that phosphopeptides from tryptic digest of alpha-casein and beta-casein are effectively and specifically trapped on Fe3+-immobilized MCM-41 with few peptides nonspecifically adsorbed. After the extraction by Fe3+-immobilized MCM-41, the suppression to the detection of phosphopeptides caused by abundant nonphosphopeptides from tryptic digest is effectively eliminated, and the detection of phosphopeptides by MALDI is greatly enhanced with the value of signal-to-noise (S/N) increased by more than an order of magnitude. It is demonstrated that the mechanism of the adsorption of phosphopeptides on Fe3+-immobilized MCM-41 is based on the interaction between the Fe3+ and the phosphate group. Finally, Fe3+-immobilized MCM-41 is applied to extract phosphopeptides from tryptic digest of the lysate of mouse liver for phosphoproteome analysis by nano-LC-MS/MS.     

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).     

Analysis of the human casein phosphoproteome by 2-D electrophoresis and MALDI-TOF/TOF MS reveals new phosphoforms

Mammalian breast milk contains an array of proteins and other nutrients essential for the development of the newborn. In human milk, the caseins (alpha S1, beta and kappa) are a major class of proteins; however, the dynamic range of concentrations in which the various isoforms of each casein exist presents challenges in their characterization. To study human milk casein phosphoforms, we applied traditional two-dimensional polyacrylamide gel electrophoretic (2-DE) separation combined with matrix-assisted laser desorption ionization-time-of-flight (MALDI-TOF) tandem mass spectroscopic analysis. The abundant beta-casein was resolved as a train of 6 spots differing in phosphorylation level with 0-5 phosphates attached. To study the less abundant alpha S1-casein, a cysteine-tagging enrichment treatment was used prior to 2-DE. A train of 9 spots with 4.4 < p I < 5.3 were identified as alpha S1-casein. This included five previously uncharacterized phosphoforms with up to 8 phosphate groups located in two serine-rich tryptic phosphopeptides ( (27)L-R (51), (69)N-K (98)) consistent with alpha-caseins from various ruminant species. MS/MS analysis of the phosphopeptides released by tryptic digestion enabled identification of the residue-specific order of phosphorylation among the 6 beta-casein and 9 alpha S1-casein phosphoforms. Deamidation of N (47) of alpha S1-casein was also a feature of the MS analysis. This study represents the first comprehensive analysis of the human casein phosphoproteome and reveals a much higher level of phosphorylation than previously recognized. It also highlights the advantages of 2-DE for examining the global pattern of protein phosphoforms and the limitations of attempting to estimate phosphorylation site occupancies from "bottom-up" studies.     

Facile synthesis of C8-functionalized magnetic silica microspheres for enrichment of low-concentration peptides for direct MALDI-TOF MS analysis

In this study, novel C8-functionalized magnetic polymer microspheres were prepared by coating single submicron-sized magnetite particle with silica and subsequent modification with chloro (dimethyl) octylsilane. The resulting C8-functionalized magnetic silica (C8-f-M-S) microspheres exhibit well-defined magnetite-core-silica-shell structure and possess high content of magnetite, which endow them with high dispersibility and strong magnetic response. With their magnetic property, the synthesized C8-f-M-S microspheres provide a convenient and efficient way for enrichment of low-abundance peptides from tryptic protein digest and human serum. The enriched peptides/proteins were subjected for MALDI-TOF MS analysis and the enrichment efficiency was documented. In a word, the facile synthesis and efficient enrichment process of the novel C8-f-M-S microspheres make them promising candidates for isolation of peptides even in complex biological samples such as serum, plasma, and urine.     

Facile synthesis of magnetic metal organic frameworks for the enrichment of low‐abundance peptides for MALDI‐TOF MS analysis

In this work, core‐shell magnetic metal organic framework (MOF) microspheres were successfully synthesized by coating magnetite particles with mercaptoacetic acid and subsequent reactions with ethanol solutions of Cu(OAc)₂ and benzene‐1,3,5‐tricarboxylic acid (designated as H₃btc) alternately. The resulting Fe₃O₄@[Cu₃(btc)₂] possess strong magnetic responsiveness. We applied the novel nanocomposites in the enrichment of low‐concentration standard peptides, peptides in MYO and BSA tryptic digests and in human urine in combination with MALDI‐TOF MS analysis for the first time. In addition, the Cu₃(btc)₂ MOF shells exhibit strong affinity to peptides, thus providing a rapid and convenient approach to the concentration of low‐abundance peptides. Notably, peptides at an extremely low concentration of 10 pM could be detected by MALDI‐TOF MS after enrichment with the magnetic MOF composites. In brief, the facile synthesis and efficient enrichment process of the Fe₃O₄@[Cu₃(btc)₂] microspheres make them promising candidates for the isolation of peptides in even complex biological environments.     

Selective separation and enrichment of peptides for MS analysis using the microspheres composed of Fe3O4@nSiO2 core and perpendicularly aligned mesoporous SiO2 shell

In this work, we report the development of a novel enrichment protocol for peptides by using the microspheres composed of Fe₃O₄@nSiO₂ Core and perpendicularly aligned mesoporous SiO₂ shell (designated Fe₃O₄@nSiO₂@mSiO₂). The Fe₃O₄@nSiO₂@mSiO₂ microspheres possess useful magnetic responsivity which makes the process of enrichment fast and convenient. The highly ordered nanoscale pores (2 nm) and high‐surface areas of the microspheres were demonstrated to have good size‐exclusion effect for the adsorption of peptides. An increase of S/N ratio over 100 times could be achieved by using the microspheres to enrich a standard peptide, and the application of the microspheres to enrich universal peptides was performed by using myoglobin tryptic digest solution. The enrichment efficiency of re‐used Fe₃O₄@nSiO₂@mSiO₂ microspheres was also studied. Large‐scale enrichment of endogenous peptides in rat brain extract was achieved by the microspheres. Automated nano‐LC‐ESI‐MS/MS was applied to analyze the sample after enrichment, and 60 unique peptides were identified in total. The facile and low‐cost synthesis as well as the convenient and efficient enrichment process of the novel Fe₃O₄@nSiO₂@mSiO₂ microspheres makes it a promising candidate for selectively isolation and enrichment of endogenous peptides from complex biological samples.