Phosphate-functionalized magnetic microspheres for immobilization of Zr ions for selective enrichment of the phosphopeptides

In this work, we developed phosphate functionalized magnetic Fe₃O₄@C microspheres to immobilize Zr⁴⁺ ions for selective extraction and concentration of phosphopeptides for mass spectrometry analysis. Firstly, we synthesized Fe₃O₄@C magnetic microspheres as our previous work reported. Then, the microspheres were functionalized with phosphate groups through a simple hydrolysis reaction using 3-(trihydroxysilyl)propyl methylphosphate. And the Zr⁴⁺ ions were immobilized on phosphate-functionalized magnetic microspheres by using phosphate chelator. Finally, we successfully employed Zr⁴⁺-phosphate functionalized magnetic microspheres to selectively isolate the phosphopeptides from tryptic digests of standard protein and real samples including rat brain. All the experimental results demonstrate the enrichment efficiency and selectivity of the method we reported here.     

Hydrophilic Nb-immobilized magnetic core–shell microsphere – A novel immobilized metal ion affinity chromatography material for highly selective enrichment of phosphopeptides

Rapid and selective enrichment of phosphopeptides from complex biological samples is essential and challenging in phosphorylated proteomics. In this work, for the first time, niobium ions were directly immobilized on the surface of polydopamine-coated magnetic microspheres through a facile and effective synthetic route. The Fe₃O₄@polydopamine-Nb⁵⁺ (denoted as Fe₃O₄@PD-Nb⁵⁺) microspheres possess merits of high hydrophilicity and good biological compatibility, and demonstrated low limit of detection (2 fmol). The selectivity was also basically satisfactory (β-casein:BSA = 1:500) to capture phosphopeptides. They were also successfully applied for enrichment of phosphopeptides from real biological samples such as human serum and nonfat milk. Compared with Fe₃O₄@PD-Ti⁴⁺ microspheres, the Fe₃O₄@PD-Nb⁵⁺ microspheres exhibit superior selectivity to multi-phosphorylated peptides, and thus may be complementary to the conventional IMAC materials.     

Iminodiacetic acid-modified magnetic poly(2-hydroxyethyl methacrylate)-based microspheres for phosphopeptide enrichment

Magnetic non-porous hydrophilic poly(2-hydroxyethyl methacrylate-co-glycidyl methacrylate) microspheres prepared by the dispersion polymerization and modified with iminodiacetic acid (IDA) were employed for the IMAC separation of phosphopeptides. Fe³⁺ and Ga³⁺ ions immobilized on IDA-modified magnetic microspheres were used for the enrichment of phosphopeptides from the proteolytic digests of two model proteins differing in their physico-chemical properties and phosphate group content: porcine pepsin A and bovine α-casein. The optimum conditions for phosphopeptide adsorption and desorption in both cases were investigated and compared. The phosphopeptides separated from the proteolytic digests were analyzed by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. The ability of the prepared Fe³⁺- and Ga³⁺-IDA-modified magnetic microspheres to capture phosphopeptides from complex mixtures was shown on an example of bovine milk proteolytic digest.     

The highly selective capture of phosphopeptides by zirconium phosphonate-modified magnetic nanoparticles for phosphoproteome analysis

The highly selective capture of phosphopeptides from proteolytic digests is a great challenge for the identification of phosphoproteins by mass spectrometry. In this work, the zirconium phosphonate-modified magnetic Fe₃O₄/SiO₂ core/shell nanoparticles have been synthesized and successfully applied for the selective capture of phosphopeptides from complex tryptic digests of proteins before the analysis of MALDI-TOF mass spectrometry with the desired convenience of sample handling. The ratio of magnetic nanoparticle to protein and the incubation time for capturing phosphopeptides from complex proteolytic digests were investigated, and the optimized nanoparticle-to-protein ratio and incubation time were between 15:1 to 30:1 and 30 min, respectively. The excellent detection limit of 0.5 fmol β-casein has been achieved by MALDI-TOF mass spectrometry with the specific capture of zirconium phosphonate-modified magnetic Fe₃O₄ nanoparticles. The great specificity of zirconium phosphonate-modified magnetic Fe₃O₄ nanoparticles to phosphopeptides was demonstrated by the selective capture of phosphopeptides from a complex tryptic digest of the mixture of α-casein and bovine serum albumin at molar ratio of 1 to 100 in MALDI-TOF-MS analysis. An application of the magnetic nanoparticles to selective capture phosphopeptides from a tryptic digest of mouse liver lysate was further carried out by combining with nano-LC-MS/MS and MS/MS/MS analyses, and a total of 194 unique phosphopeptides were successfully identified.     

Fe3O4@Al2O3 magnetic core-shell microspheres for rapid and highly specific capture of phosphopeptides with mass spectrometry analysis

Selective detection of phosphopeptides from complex biological samples is a challenging and highly relevant task in many proteomics applications. In this study, a novel phosphopeptide enrichment approach based on the strong interaction of Fe(3)O(4)@Al(2)O(3) magnetic core-shell microspheres with phosphopeptides has been developed. With a well-defined core-shell structure, the Fe(3)O(4)@Al(2)O(3) magnetic core-shell microspheres not only have a shell of aluminum oxide, giving them a high-trapping capacity for the phosphopeptides, but also have magnetic property that enables easy isolation by positioning an external magnetic field. The prepared Fe(3)O(4)@Al(2)O(3) magnetic core-shell microspheres have been successfully applied to the enrichment of phosphopeptides from the tryptic digest of standard phosphoproteins beta-casein and ovalbumin. 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 1:50 as well as tryptic digest product of casein and five protein mixtures. The results also proved a stronger selective ability of Fe(3)O(4)@Al(2)O(3) magnetic core-shell microspheres over Fe(3+)-immobilized magnetic silica microspheres, commercial Fe(3+)-IMAC (immobilized metal affinity chromatography) resin, and TiO(2) beads. Finally, the Al(2)O(3) coated Fe(3)O(4) microspheres were successfully utilized for enrichment of phosphopeptides from digestion products of rat liver extract. These results show that Fe(3)O(4)@Al(2)O(3) magnetic core-shell microspheres are very good materials for rapid and selective separation and enrichment of phosphopeptides.     

The use of liquid phase deposition prepared phosphonate grafted silica nanoparticle‐deposited capillaries in the enrichment of phosphopeptides

In our current work, we describe how open tubular‐immobilized metal‐ion affinity chromatography (OT‐IMAC) capillary columns connected to a solid phase microextraction (in‐tube SPME) device can be used for the enrichment of phosphopeptides. A phosphonate modified silica nanoparticle (NP)‐deposited capillary was prepared by liquid phase deposition (LPD), and used for the immobilization of Fe³⁺, Zr⁴⁺ or Ti⁴⁺. The enrichment capacities of three different OT‐IMAC capillary columns were compared by using tryptically digested α‐casein as sample. The improved extraction efficiency in our technique was demonstrated by comparing to a directly modified capillary, and a comparison of phosphopeptide extraction from simple and complex samples was tested for both modes. Our results show that the NP‐IMAC‐Zr⁴⁺ capillary column can be used to selectively isolate phosphopeptides from real samples, and can enrich for β‐casein phosphopeptides from concentrations as low as 1.7×10^?9 M.     

Nanodiamond-based two-step sampling of multiply and singly phosphorylated peptides for MALDI-TOF mass spectrometry analysis

Simultaneous detection of multiply and singly phosphorylated peptides using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) is challenging because of suppression effects during ionization. In oder to overcome this problem, this study presents a new approach to improve the detection of phosphopeptides by stepwise enrichment using polyarginine-coated (PA-coated) and titanium dioxide-coated (TiO(2)-coated) nanodiamonds for fractionation of multiply and singly phosphorylated peptides prior to on-probe MALDI MS analysis. The feasibility of this approach was demonstrated using synthetic peptides containing different numbers of phosphate groups, tryptic digests of α-casein, β-casein, and complex protein mixtures. The high specificity of the approach is shown in its effective enrichment and fractionation of phosphopeptides from the digest of β-casein and bovine serum albumin at a molar ratio as low as 1 : 1000, which out-performs the commercial Fe(3+)-IMAC and TiO(2) isolation kits. It offers a simple and effective alternative for the fractionation and identification of multiply and singly phosphorylated peptides by MALDI MS and allows for deduction of more information from limited starting materials.     

Isolation of phosphopeptides using zirconium-chlorophosphonazo chelate-modified silica nanoparticles

Due to the low abundance of phosphoproteins and substoichiometry of phosphorylation, the elucidation of protein phosphorylation requires highly specific materials for isolation of phosphopeptides from biological samples prior to mass spectrometric analysis. In this study, chlorophosphonazo type derivatives of chromotropic acid including p-hydroxychlorophosphonazo (HCPA) and chlorophosphonazo I (CPA I), traditionally used in the photometric determination of transition metal ions, have been employed as chelating ligands in the preparation of novel affinity materials for phosphopeptide enrichment. The chromogenic reagents of HCPA and CPA I were chemically modified on the surface of silica nanoparticles, and the functionalized materials were charged with zirconium ions through the strong complexation between chelating ligands and Zr(4+). The obtained zirconium-chlorophosphonazo chelate-modified silica nanoparticles (Zr-HCPA-SNPs and Zr-CPA I-SNPs) were applied to the selective enrichment of phosphopeptides, followed by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) analysis. The purification procedures were optimized using α-casein digest at first, and then the performance of these two affinity materials for efficient and specific enrichment of phosphopeptides was evaluated with the tryptic digests of standard proteins (α-casein, β-casein, ovalbumin and bovine serum albumin). It is found that Zr-HCPA-SNPs are superior to Zr-CPA I-SNPs in phosphopeptide enrichment. Using Zr-HCPA-SNPs to trap phosphopeptides in α-casein digest, the detection limit was close to 50fmol based on MALDI-TOF MS analysis. Finally, Zr-HCPA-SNPs were used to directly isolate phosphopeptides from diluted human serum of healthy, diabetes and hypertension persons, respectively. Our results show that the constitution and level of phosphopeptides are remarkably different among the three groups, which indicate the powerful potentials of Zr-HCPA-SNPs in disease diagnosis and biomarker screening.     

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.     

Rapid enrichment of phosphopeptides by BaTiO3 nanoparticles after microwave-assisted tryptic digest of phosphoproteins, and their identification by MALDI-MS

We show that BaTiO₃ nanoparticles (NPs) can be used as a novel substrate for the rapid enrichment of phosphopeptides from microwave tryptic digests of α-casein and non-fat milk prior to their identification by MALDI-MS. Protein digestion is achieved by microwave tryptic digest for 50?s, and the resulting phosphopeptides can be effectively adsorbed on the surfaces of the NPs. The phosphopeptides were selectively detected via MALDI-MS. Digestion, enrichment and detection are accomplished within ～60?min. The method was applied to the indentification of 24 phosphopeptides from α-casein and of 21 phosphopeptides (of the α-casein type) from nonfat milk.

Highly specific capture and direct MALDI-MS analysis of phosphorylated peptides using novel multifunctional chitosan-GMA-IDA-Fe (III) nanosphere

In this study, we describe a method for highly specific enrichment of phosphopeptides with multifunctional chitosan–glycidyl methacrylate (GMA)–iminodiacetic acid (IDA)–Fe (III) nanospheres for direct analysis by matrix-assisted laser desorption–ionization mass spectrometry (MALDI-MS). This is the first time that chitosan has been used to create nanospheres support material for selective enrichment of phosphopeptides by modification with GMA, derivatization with IDA, and loading with Fe (III) ions. Chitosan-GMA-IDA-Fe (III) nanospheres with a diameter of 20 to 100 nm have multifunctional chemical moieties which confer unique properties, good dispersibility in highly acidic binding buffers, as well as good biocompatibility and chemical stability which improves their specific interaction with phosphopeptides using various types of acid binding buffers. The process of enrichment is very simple, quick, efficient, and specific. Its high specificity and efficiency for purification of phosphopeptides is reflected in the very low and substoichiometric amounts of phosphopeptides which can be detected, in quantities as low as 1:3,000 M ratios. Compared with other state-of the-art technologies such as the use of conventional Fe³⁺-IMAC and TiO₂, these chitosan nanosphere techniques show superior specificity and sensitivity. Moreover, the resultant chitosan-GMA-IDA-Fe³⁺ nanosphere-absorbed phosphopeptides can be either directly analyzed by MALDI-TOF MS analysis or eluted and further analyzed by nano-LC-MS/MS.     

Application of polydopamine-coated nylon capillary-channeled polymer fibers as a stationary phase for mass spectrometric phosphopeptide analysis

Capillary-channeled polymer (C-CP) fibers are demonstrated as a selective stationary phase for phosphopeptide analysis via LC–MS. Taking advantage of the oxidative self-polymerization of dopamine under alkaline conditions, a simple system involving a dilute aqueous solution of 0.2% w/v dopamine hydrochloride in 0.15% w/v TRIS buffer, pH 8.5 was utilized to coat polydopamine onto nylon 6 C-CP fibers. Confirmation of the polydopamine coating on the fibers (nylon-PDA) was made through attenuated total reflection-FTIR (ATR-FTIR) analysis. Imaging using SEM was also performed to examine the morphology and topography of the nylon-PDA. Subsequent loading of Fe³⁺ to the nylon-PDA matrix was confirmed by SEM/energy dispersive X-ray spectroscopy (SEM/EDX). The Fe³⁺-bound nylon-PDA fibers packed in a microbore column format were tested in the off-line preconcentration of phosphopeptides from a 1:100 mixture of β-casein/BSA digests for MALDI-TOF analysis. The packed column was also installed onto an HPLC system as a platform for the online sample clean-up and enrichment of phosphopeptides from a 1:1000 mixture of β-casein/BSA protein digests that were determined by subsequent ESI–MS analysis.     

Development of core–shell structure Fe3O4@Ta2O5 microspheres for selective enrichment of phosphopeptides for mass spectrometry analysis

Protein phosphorylation is one of the most important post-translational modifications. Due to the dynamic nature and low stoichiometry of the protein phosphorylation, enrichment of phosphopeptides from proteolytic mixtures is often necessary prior to their characterization by mass spectrometry. Many metal oxides such as titanium dioxide and zirconium dioxide have been successfully applied to isolation and enrichment of phosphopeptides. Recently, niobium pentoxide was proved to have the ability for selective enrichment of phosphopeptides. Considering the proximity of tantalum to niobium, we supposed that Ta₂O₅ can be used as affinity probes for phosphopeptide enrichment. In the work, we synthesized Fe₃O₄@Ta₂O₅ magnetic microspheres with core–shell structure for selective enrichment of phosphopeptides. To demonstrate its ability for selective enrichment of phosphopeptides, we applied Fe₃O₄@Ta₂O₅ magnetic microspheres to isolation and enrichment of the phosphopeptides from tryptic digestion of standard proteins and real samples, and then the enriched peptides were analyzed by matrix-assisted laser desorption mass spectrometry analysis (MALDI-MS) or liquid chromatography coupled to electrospray ionization mass spectrometry (LC–ESI-MS). Experiment results demonstrate that Ta₂O₅ coated-magnetic microspheres show the excellent potential for selective enrichment of phosphopeptides.     

Mesoporous Fe2O3 microspheres: rapid and effective enrichment of phosphopeptides for MALDI-TOF MS analysis

Mesoporous Fe(2)O(3) microspheres have been successfully synthesized by the polymerization (urea and formaldehyde)-induced ferric hydroxide colloid aggregation. The urea-formaldehyde resin was removed by calcination in air. The obtained mesoporous Fe(2)O(3) materials have spherical morphology with uniform particle size of approximately 3.0 microm and porous surface with large inter-particle pores of approximately 48.0 nm. The surface area is as large as approximately 33.3 m(2)/g and the pore volume is 0.31 cm(3)/g. The mesoporous Fe(2)O(3) microspheres were used for the enrichment of phosphopeptides for the first time, in which high sensitivity, selectivity and capacity of specifically enriched phosphopeptides were achieved under a mild condition in a relative short time. After enriched from tryptic digest products of beta-casein by the novel mesoporous Fe(2)O(3) microspheres, phosphopeptides can be selectively detected with high intensity in MALDI-TOF mass spectrometry. Elimination of "shadow effect" was observed by using mesoporous Fe(2)O(3) microspheres, and the detectable limitation is 5x10(-10) M. This material is also effective for enrichment of phosphopeptides from the complex tryptic digests of commercial phosphoprotein casein, with much more phosphorylated sites (26 in 27 of total) and higher signal/noise ratio in the MALDI-TOF mass spectrometry, compared to commercial Fe(2)O(3) nanoparticles. It shows a great potential application in the field of rapid and effective isolation of phosphopeptides.     

Use of polyethylenimine-modified magnetic nanoparticles for highly specific enrichment of phosphopeptides for mass spectrometric analysis

Phosphopeptides have been isolated and concentrated by use of polyethyleneimine (PEI)-modified magnetic nanoparticles as an extremely specific affinity probe. The particles specifically captured phosphopeptides from a tryptic digest of a protein mixture that contained 0.07% (mole/mole) phosphoproteins, which is the highest specificity obtained to date. The time required for enrichment of the phosphopeptides was 1 min only. PEI-modified magnetic nanoparticles carry positive charges over a wide range of pH—between 3 and 11. This feature means the particles are effectively dispersed in solution during phosphopeptide capture. Mass spectrometric analysis revealed the very high efficiency of enrichment of phosphopeptides that contain both single and multiply-phosphorylated sites. The detection limit in the analysis of phosphopeptides obtained from both bovine α-casein and β-casein by matrix-assisted laser desorption/ionization mass spectrometry was 5 fmol. This approach was also used to enrich the phosphopeptides in a protein digest obtained from non-fat milk.     

聚多巴胺修饰棉花固定金属离子用于磷酸化多肽的富集

本文通过多巴胺自聚合在天然的棉花纤维表面,构建了仿生聚多巴胺(PDA)膜层,然后利用儿茶酚羟基固定Ti~(4+),设计并合成了一种固定金属亲合色谱(Immobilized Metal Ion Affinity Chromatography,IMAC)材料Cotton@PDA-Ti~(4+),并将其用于磷酸化多肽的富集。该材料机械性能好,化学性能稳定和生物相容性好,且制备过程简单,通过简易的In-pipet-tip固相萃取(SPE)装置使整个富集操作过程简便快速。实验结果表明,Cotton@PDA-Ti~(4+)不仅可以从简单的蛋白酶解物(β-casein)中富集磷酸化多肽,并且在含有大量非磷酸化多肽的复杂体系样品中对磷酸化多肽也表现出良好的选择性。另外,利用Cotton@PDA-Ti~(4+)对磷酸化多肽进行富集也有较高的效率。我们将该材料应用于实际样品,如人体血清以及脱脂牛奶酶解物中磷酸化多肽的富集,均表现出了较好的选择性。说明该方法有可能用于磷酸化蛋白质组的全分析。     

Ti-SBA-15介孔材料用于磷酸化肽的高效富集

结合基质辅助激光解吸飞行时间质谱(MALDI-TOF MS)检测技术,考察了Ti-SBA-15介孔材料对β-酪蛋白酶解产物中磷酸化肽的选择性富集性能。实验结果显示,含Ti和Si物质的量比为0.08的Ti-SBA-15介孔材料可选择性地对β-酪蛋白酶解产物中的磷酸化肽进行选择性富集;对于β-酪蛋白和牛血清白蛋白物质的量比为1:100的蛋白质酶解混合液,Ti-SBA-15仍能实现对其磷酸化肽的有效富集。上述结果表明,作为一种多孔、高比表面积的磷酸化多肽的选择性吸附材料,Ti-SBA-15有望在磷酸化蛋白质组的分析中得到广泛的应用。     

Mesoporous TiO2 aerogel for selective enrichment of phosphopeptides in rat liver mitochondria

The enrichment of low abundance phosphopeptides before MS analysis is a critical step for in-depth phosphoproteome research. In this study, mesoporous titanium dioxide (TiO₂) aerogel was prepared by precipitation and supercritical drying. The specific surface area up to 490.7 m² g⁻¹ is achieved by TiO₂ aerogel, much higher than those obtained by commercial TiO₂ nanoparticles and by the latest reported mesoporous TiO₂ spheres. Due to the large specific surface area and the mesoporous structure of the aerogel, the binding capacity for phosphopeptides is six times higher than that of conventional TiO₂ microparticles (173 vs 28 μmol g⁻¹). Because of the good compatibility of enrichment procedure with MALDI-TOF-MS and the large binding capacity of TiO₂ aerogel, a detection limit as low as 30 amol for analyzing phosphopeptides in β-casein digest was achieved. TiO₂ aerogel was further applied to enrich phosphopeptides from rat liver mitochondria, and 266 unique phosphopeptides with 340 phosphorylation sites, corresponding to 216 phosphoprotein groups, were identified by triplicate nanoRPLC-ESI-MS/MS runs, with false-positive rate less than 1% at the peptide level. These results demonstrate that TiO₂ aerogel is a kind of promising material for sample pretreatment in the large-scale phosphoproteome study.     

Functionalized diamond nanopowder for phosphopeptides enrichment from complex biological fluids

Diamond is known for its high affinity and biocompatibility towards biomolecules and is used exclusively in separation sciences and life science research. In present study, diamond nanopowder is derivatized as Immobilized Metal Ion Affinity Chromatographic (IMAC) material for the phosphopeptides enrichment and as Reversed Phase (C-18) media for the desalting of complex mixtures and human serum profiling through MALDI-TOF-MS. Functionalized diamond nanopowder is characterized by Fourier transform infrared (FT-IR) spectroscopy, scanning electron microscopy (SEM) and energy dispersive X-ray (EDX) spectroscopy. Diamond-IMAC is applied to the standard protein (β-casein), spiked human serum, egg yolk and non-fat milk for the phosphopeptides enrichment. Results show the selectivity of synthesized IMAC-diamond immobilized with Fe³⁺ and La³⁺ ions. To comprehend the elaborated use, diamond-IMAC is also applied to the serum samples from gall bladder carcinoma for the potential biomarkers. Database search is carried out by the Mascot program (www.matrixscience.com) for the assignment of phosphorylation sites. Diamond nanopowder is thus a separation media with multifunctional use and can be applied to cancer protein profiling for the diagnosis and biomarker identification.     

Zirconium oxide aerogel for effective enrichment of phosphopeptides with high binding capacity

In this study, zirconium oxide (ZrO₂) aerogel was synthesized via a green sol–gel approach, with zirconium oxychloride, instead of the commonly used alkoxide with high toxicity, as the precursor. With such material, phosphopeptides from the digests of 4 pmol of β-casein with the coexistence of 100 times (mol ratio) BSA could be selectively captured, and identified by MALDI-TOF MS. Due to the large surface area (416.0 m² g⁻¹) and the mesoporous structure (the average pore size of 10.2 nm) of ZrO₂ aerogel, a 20-fold higher loading capacity for phosphopeptide, YKVPQLEIVPN[pS]AEER (MW 1952.12), was obtained compared to that of commercial ZrO₂ microspheres (341.5 vs. 17.87 mg g⁻¹). The metal oxide aerogel was further applied in the enrichment of phosphopeptides from 100 ng nonfat milk, and 17 phosphopeptides were positively identified, with a 1.5-fold improvement in phosphopeptide detection compared with previously reported results. These results demonstrate that ZrO₂ aerogel can be a powerful enrichment material for phosphoproteome study.