Project description:To acquire a deeper understanding of malignant melanoma (MM), it is essential to study the proteome of patient tissues. In particular, phosphoproteomics of MM has become of significant importance because of the central role that phosphorylation plays in the development of MM. Investigating clinical samples, however, is an extremely challenging task as there is usually only very limited quantities of material available to perform targeted enrichment approaches. Here, an automated phosphopeptide enrichment protocol using the AssayMap Bravo platform was applied to MM tissues and assessed for performance. The strategy proved to be highly-sensitive, less prone to variability, less laborious than existing techniques and adequate for starting quantities at the microgram level. An Fe(III)-NTA-IMAC-based enrichment workflow was applied to a dilution series of MM tissue lysates. The workflow was efficient in terms of sensitivity, reproducibility and phosphosite localization; and from only 12.5 µg of sample, more than 1,000 phosphopeptides were identified. In addition, from 60 µg of protein material the number of identified phosphoproteins from individual MM samples was comparable to previous reports that used extensive fractionation methods. Our data set included key pathways that are involved in MM progression; such as MAPK, melanocyte development and integrin signaling. Moreover, tissue-specific immunological proteins were identified, that have not been previously observed in the proteome of MM-derived cell lines. In conclusion, this workflow is suitable to study large cohorts of clinical samples that demand automatic and careful handling.

Project description:Protein identification and quantification is an important tool for biomarker discovery. With the increased sensitivity and speed of modern mass spectrometers, sample-preparation remains a bottleneck for studying large cohorts. To address this issue, we prepared and evaluated a simple and efficient workflow on the Opentrons OT-2 (OT-2) robot that combines sample digestion, cleanup and Evotip loading in a fully automated manner, allowing the processing of up to 192 samples in 6 hours. Our results demonstrate a highly sensitive workflow yielding both reproducibility and stability even at low sample inputs. The workflow is optimized for minimal sample starting amount to reduce the costs for reagents needed for sample preparation, which is critical when analyzing large biological cohorts. Building on the digesting workflow, we incorporated an automated phosphopeptide enrichment step using magnetic Ti-IMAC beads. This allows for a fully automated proteome and phosphoproteome sample preparation in a single step with high sensitivity. Using the integrated workflow, we evaluated the effects of cancer immune therapy on the plasma proteome in metastatic melanoma patients.

Project description:The field of phosphoproteomics has been revolutionized in the last years, with enhanced efficiency and sensitivity, now enabling deep phosphoproteomic analysis single-shot from minimal peptide inputs. In this study, we rigorously evaluate the effects of various experimental parameters in automated Zirconium-IMAC (Zr-IMAC) based phosphoproteomic sample preparation with focus on low peptide input samples. Assessing metrics such as number of identified phosphopeptides, selectivity, phosphosite localization scores and relative purification of multiply phosphorylated phosphopeptides, we were able to pinpoint key influencing variables. Determination of the optimal glycolic acid concentration in the loading buffer, percentage of ammonium hydroxide in the elution buffer, peptide to beads ratio, binding time, sample volume and loading buffer volume, allowed us to confidently localize up to ~15,800 phosphopeptides using 30 µg of peptides as starting material. Furthermore, we evaluated how sequential enrichment can boost the depth of the analysis, and most importantly, whether pooling fractions into a single-LCMS analysis also increases the phosphoproteome depth. As a result, we present a novel strategy based on incremental addition of beads and subsequent fraction pooling, which can boost by 17% the phosphoproteome coverage when compared to standard enrichment.

Project description:Chemical crosslinking mass spectrometry is rapidly emerging as a prominent technique to study protein structures. Structural information is obtained by covalently connecting peptides in close proximity by small reagents and identifying the resulting peptide pairs by mass spectrometry. However, sub-stoichiometric reaction efficiencies render routine detection of crosslinked peptides problematic. Here we present a new tri-functional crosslinking reagent, termed PhoX, which is decorated with a stable phosphonic acid handle. This makes the crosslinked peptides amenable to the well-established IMAC enrichment. The handle allows for 300x enrichment efficiency and 97% specificity, dramatically reducing measurement time and improving data quality. We exemplify the approach on various model proteins and protein complexes, e.g. resulting in a structural model of LRP1/RAP complex. PhoX is also applicable to whole cell lysates. When focusing the database search on ribosomal proteins, our first attempt resulted in 355 crosslinks, out-performing current efforts in less measurement time.

Project description:Comparison of several TiO2-based phosphopeptide enrichment methods

Project description:Protein phosphorylation is one of the most common post-translational modifications (PTMs), which is involved in many important physiological functions. Understanding protein phosphorylation at molecular level is critical to decipher its relevant biological processes and signaling networks. Mass spectrometry (MS) has been proved to be a powerful tool in comprehensive characterization of protein phosphorylation. Yet the low abundance and poor ionization efficiency of phosphopeptides make its MS analysis challenging; an enrichment with high efficiency and selectivity is always necessary before MS analysis. In this study, we developed a phosphorylated cotton fiber-based Ti(IV)-IMAC material (termed as: Cotton Ti-IMAC) that can serve as a novel platform for phosphopeptide enrichment. The cotton fiber can be effectively grafted with phosphate groups in a single step, where the titanium ions can then be immobilized onto to capture phosphopeptides. The material can be prepared with cost-effective reagents within only 4 hours. Benefiting from the flexibility and filterability of cotton fibers, the material can be easily packed as a spin-tip and make the enrichment process more convenient. Cotton Ti-IMAC successfully enriched phosphopeptides from protein standard digests and exhibited a high selectivity (β-casein/BSA = 1:1000) and excellent sensitivity (0.1 fmol/µL). Moreover, 2354 phosphopeptides was identified in a single LC-MS/MS injection after enriching from only 100 µg HeLa cell digests, with an enrichment specificity up to 97.51%. Taken together, we believe Cotton Ti-IMAC is ready to serve as a widely applicable and robust platform for achieving large-scale phosphopeptide enrichment and expanding our knowledge of phosphoproteomics in complex biological systems.

Project description:Protein phosphorylation in prokaryotes has gained more attention in recent years as several studies linked it to regulatory and signalling functions indicating an importance similar to protein phosphorylation in eukaryotes. Studies on bacterial phosphorylation have so far been conducted using manual or HPLC-supported phosphopeptide enrichment while automation of phosphopeptide enrichment has been established in eukaryotes, allowing for high throughput sampling. To facilitate the prospect of studying bacterial phosphorylation on a systems‐level we here establish an automated Ser/Thr/Tyr phosphopeptide enrichment workflow on the Agilent AssayMap platform. We present optimized buffer conditions for TiO2 and Fe(III)NTA-IMAC based enrichment, and the most advantageous, species specific starting amount for S. pyogenes, L. monocytogenes, and B. subtilis. Our data represents, to the best of our knowledge, the largest phosphoproteome identified by a single study for each of these bacteria. For higher sample amounts (> 250µg) we observed a superior performance of Fe(III)NTA cartridges, while more peptides were identified from smaller sample amounts using TiO2-based enrichment. Both cartridges largely enrich the same set of phosphopeptides suggesting no improvement of peptide yield from complementary use of both cartridges. Distribution of S/T/Y phosphorylation varied between bacterial strains with threonine being the main site of phosphorylation in S. pyogenes, while in B.subtilis and L. monocytogenes showed the highest percentage of phosphorylation at serine.

Project description:We describe the application of magnetic TiO2 and Ti-IMAC for uniform automated phosphopeptide enrichment. Combining hyper-porous magnetic microspheres with a magnetic particle-handling robot enables rapid (45 minutes), reproducible (r2 = 0.80) and high-fidelity (> 90% purity) phosphopeptide purification in a 96-well format.

Project description:IMAC and MOAC magnetic microsphere materials were tested with ug amounts of protein extracts from HepG2/C3A cells. We compared Zirconium (IV) IMAC (Zr-IMAC) magnetic microspheres to commonly used Titanium (IV) IMAC (Ti-IMAC) and TiO2 magnetic microspheres for phosphopeptide enrichment from simple and complex protein samples prior phosphopeptide sequencing and characterization by mass spectrometry (LC-MS/MS). We optimized sample-loading conditions to increase phosphopeptide recovery for Zr-IMAC, Ti-IMAC and TiO2 based workflows. Furthermore, optimized Zr-IMAC and Ti-IMAC magnetic microsphere format were compared to HPLC-based Fe(III)-IMAC for same sample amount (200 ug).

Project description:Reversible protein phosphorylation is a widespread posttranslational modification that plays a key role in eukaryotic signal transduction. Due to the large dynamic range of protein abundance, low stoichiometry and transient nature of protein phosphorylation, the detection and accurate quantification of substrate phosphorylation by protein kinases remains a challenge. Here, we combine tandem metal-oxide affinity chromatography (tandemMOAC) with stable isotope 15N metabolic labeling for the mass spectrometry measurement and accurate quantification of low abundant, transiently phosphorylated peptides. Since tandemMOAC is not biased towards the enrichment of acidophilic, basophilic or proline-directed kinase substrates, the method is applicable to identify targets of members of all three classes of protein kinases. Using this phosphoproteomics approach, we identified several mitogen-activated protein kinase (MPK) substrates downstream of the MKK7-MPK3/6 phosphorylation cascade of Arabidopsis. The MKK7-MPK3/6 module is involved in the regulation of plant development and plant basal and systemic immune responses but little is known about downstream cascade components. The identification and validation of dynamin-related protein (DRP) 2 as a novel phosphorylation substrate of the MKK7-MPK3/6 module establishes a novel link between MPK signaling and clathrin-mediated vesicle trafficking.