High-throughput workflow for identification of phosphorylated peptides by LC-MALDI-TOF/TOF-MS coupled to in situ enrichment on MALDI plates functionalized by ion landing

Multiple phosphorylated protein selective analysis via fluorous derivatization and liquid chromatography-electrospray ionization-mass spectrometry analysis

Post-translational modification of proteins is involved in protein function and higher-order structure. Among such modification, phosphorylation is an important intracellular signal transduction pathway. Many studies on phosphorylated protein analysis using liquid chromatography-electrospray ionization-mass spectrometry (LC-ESI-MS) have been developed. However, there are few reports on the analysis of highly phosphorylated proteins because of their handling difficulty. Hence, we developed an analytical method that converts multiple phosphate groups contained in the peptides into perfluoroalkyl groups for selective analysis using fluorous affinity. Here, tryptic digested β-casein fragment peptides [RELEELNVPGEIVE(pSer)L(pSer)(pSer)(pSer)EESITR and FQ(pSer)EEQQQTEDELQDK] were used as model phosphorylated peptides. 1H,1H,2H,2H-Perfluorooctanethiol (PFOT) and 2,2,2-trifluoroethanethiol (TFET) were used as derivatization reagents for mono-phosphorylated peptides and multi-phosphorylated peptides, respectively, to derivatize via β-elimination/Michael addition. The derivatives were analyzed by LC-ESI-MS. A fluorous LC column is typically used to selectively retain the fluorous-derivatized peptides, which are expected to be separated from contaminants and non-phosphorylated peptides. When this method was applied to β-casein, TFET- and PFOT-derivatized peptides were strongly retained in the fluorous LC column and clearly separated from non-phosphorylated peptides on the chromatogram. Therefore, the developed method enables quantification of mono- and multi-phosphorylated peptides and is suitable for application in proteomics.

Capillary electrophoretic profiling of in-bone tryptic digests of proteins as a potential tool for the detection of inflammatory states in oral surgery

The commonly used histological assessment of pathological states of alveolar bone tissues in oral surgery needs laborious and time-consuming processing by an experienced histologist. Therefore, a simpler and faster methodology is required in this field. Following this demand, this paper reports a straightforward approach using the tryptic cleavage of proteins directly in bone without its demineralization, followed by the capillary electrophoresis-ultraviolet detection profiling of the yielded protein digest. Cleavage-derived peptides were separated by capillary electrophoresis in acidic background electrolytes, pH 2.01-2.54. The best resolution of peptide fragments with the highest peak capacity was achieved in the background electrolyte composed of 55 mM H₃ PO₄ , 14 mM tris(hydroxymethyl)aminomethan, pH 2.01. The differences in the obtained capillary electrophoresis-ultraviolet detection profiles with characteristic patterns for particular bone samples were subsequently discriminated by linear discriminant analysis over principal components. This approach was first verified on porcine bone tissues as model samples; jawbone and calf bone tissues could be discriminated with an accuracy of 100%. Subsequently, the method was capable of differentiating unequivocally between human healthy and inflammatory alveolar bone tissues obtained from oral surgery. This procedure seems to be promising as complement or even an alternative to the traditional histological discrimination between healthy and inflammatory bone tissues in oral surgery.

Simple preparation of magnetic metal-organic frameworks composite as a "bait" for phosphoproteome research

Phosphospecific enrichment techniques and mass spectrometry (MS) are primary tools for comprehending the cellular phosphoproteome. In this work, a rational and extremely facile route to synthesize the magnetic metal-organic frameworks (mMOFs) was employed and the prepared composite was first utilized as a "bait" for selective enrichment of phosphopeptides. Typically, the mMOFs was synthesized via electrostatic self-assembly between the negatively charged Fe₃O₄ magnetic nanoparticles (MNPs) and positively charged MIL-101(Fe). The obtained Fe₃O₄/MIL-101(Fe) composite possessed well-defined structures, rough surface, highly specific surface area and excellent magnetic property. To demonstrate their ability for enrichment of phosphopeptides, we applied Fe₃O₄/MIL-101(Fe) as a "bait" to capture the phosphopeptides from standard protein digestion and practical samples. The enriched phosphopeptides were analyzed by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS). The MS results show that the Fe₃O₄/MIL-101(Fe) exhibits superior enrichment performance for phosphopeptides with low detectable concentration assessed to be 8 fmol, selectivity investigated to be 1:1000 using β-casein/bovine serum albumin mixture and enrichment recovery evaluated to be 89.8%. Based on these excellent properties, the prepared composite was used to enrich the phosphopeptides from tilapia eggs biological samples for the first time. A total number of 51 phosphorylation sites were identified from the digest of tilapia eggs proteins, suggesting the excellent potential of Fe₃O₄/MIL-101(Fe) composite in the practical application.

Planar Functionalized Surfaces for Direct Immunoaffinity Desorption/Ionization Mass Spectrometry

BACKGROUND

Recent studies show that the haptoglobin phenotype in individuals with diabetes mellitus is an important factor for predicting the risk of myocardial infarction, cardiovascular death, and stroke. Current methods for haptoglobin phenotyping include PCR and gel electrophoresis. A need exists for a reliable method for high-throughput clinical applications. Mass spectrometry (MS) can in principle provide fast phenotyping because haptoglobin α 1 and α 2, which define the phenotype, have different molecular masses. Because of the complexity of the serum matrix, an efficient and fast enrichment technique is necessary for an MS-based assay.

METHODS

MALDI plates were functionalized by ambient ion landing of electrosprayed antihaptoglobin antibody. The array was deposited on standard indium tin oxide slides. Fast immunoaffinity enrichment was performed in situ on the plate, which was further analyzed by MALDI-TOF MS. The haptoglobin phenotype was determined from the spectra by embedded software script.

RESULTS

The MALDI mass spectra showed ion signals of haptoglobin α subunits at m/z 9192 and at m/z 15 945. A cohort of 116 sera was analyzed and the reliability of the method was confirmed by analyzing the identical samples by Western blot. One hundred percent overlap of results between the direct immunoaffinity desorption/ionization MS and Western Blot analysis was found.

CONCLUSIONS

MALDI plates modified by antihaptoglobin antibody using ambient ion landing achieve low nonspecific interactions and efficient MALDI ionization and are usable for quick haptoglobin phenotyping.