Bimetallic Ordered Large-Pore MesoMOFs for Simultaneous Enrichment and Dephosphorylation of Phosphopeptides.

Despite the fact that bimetallic metal-organic frameworks (MOFs) could afford multiple functionalities by a synergistic effect of individual metallic centers, their intrinsic microporous structure frequently restricts their wide applications with bulky molecules involved. An urgent need is consequently triggered to design bimetallic hierarchical mesoporous MOFs (mesoMOFs). Herein, Zr/Ce mesoMOFs with a uniform pore size of up to 8 nm was successfully synthesized by a copolymer template strategy with the aid of a Hoffmeister ion. The obtained Zr/Ce mesoMOFs feature high porosity, good chemical and thermal stabilities, and tunable element components, and up to 70% Zr could be incorporated into the mesoporous Ce-based framework without deteriorating its crystallinity. Thanks to the synergistic effect of inherent Ce and Zr as well as the large and open pore channels, a broad range of phosphopeptides with different molecule sizes could be effectively checked out, thanks to their simultaneous enrichment and dephosphorylation capabilities. Such an ability to efficiently concentrate phosphopeptides remained intact even in the presence of abundant non-phosphorylated species. The practical detection of phosphopeptides from human serum was also verified, prefiguring the great potentials of bimetallic large-pore mesoMOFs for the proteome applications.

One-pot synthesis and multiple MS/MS fragmentation studies of phospholysine peptides.

RATIONALE: Compared with phosphorylation of arginine and histidine, the study of phosphorylation of lysine lags far behind. The major challenges toward the current study of phosphorylation of lysine include synthesis and unambiguous phosphosite identification. This study provided a simple chemical synthesis method to construct phospholysine peptides (pLys peptides) and investigated their fragmentation under multiple activation types. METHODS: Herein, we developed a synthetic method for pLys peptides in aqueous solution within one pot. Two peptides were lysine-phosphorylated using this method. The purified pLys peptides were first characterized using NMR, then were subjected to nano-liquid chromatography-tandem mass spectrometry (nanoLC-MS/MS) analysis under multiple fragmentation method including collision-induced dissociation (CID), higher energy collisional dissociation (HCD), electron transfer dissociation (ETD), electron transfer/higher energy collisional dissociation (EThcD), and ultraviolet photodissociation (UVPD) fragmentation to investigate the relevant diagnostic ions. RESULTS: Two pLys peptides were synthesized with a moderate yield following an easily handled experimental protocol. NMR spectra showed the phosphorylation occurred on ε-NH2 of lysine but not other groups. As for the fragmentation, in general, pLys immonium ions and phosphate-related neutral losses were ubiquitous among spectra derived from these activation types except for ETD. Using these ions as diagnostic ions, the misassigned phosphosites by algorithm could be recorrected. UVPD-generated spectra owned good sequence-coverage and abundant fragment ions, with pLys immonium ions and neutral losses of weak intensity. CONCLUSIONS: A synthetic method was developed for pLys peptides in aqueous solution within one pot. The characteristic pLys immonium ions and phosphate-related neutral loss could serve as the diagnostic ions for unambiguous phosphosite identification of pLys peptides. In addition, UVPD was promising for the identification of pLys peptides.

Chemical Synthesis of PDZ Domains.

Developments in chemical protein synthesis have enabled the generation of tailor-made proteins including incorporation of many types of modifications into proteins, enhancing our ability to control site-specificity of protein posttranslational modifications (PTMs), modify protein backbones and introduce photocrosslinking probes. For PDZ (postsynaptic density protein, disks large, zonula occludens) protein domains, expressed protein ligation (EPL) has been employed to introduce analogs of cognate amino acids, amide-to-ester bond mutations, and phosphorylations in the study of PDZ domain-mediated protein-protein interactions (PPIs). Here, we present protocols for EPL of PDZ domains focusing on phosphorylation and amide-to-ester modifications in the PDZ domain proteins.

A Two-Dimensional Metallacycle Cross-Linked Switchable Polymer for Fast and Highly Efficient Phosphorylated Peptide Enrichment.

The selective and efficient capture of phosphopeptides is critical for comprehensive and in-depth phosphoproteome analysis. Here we report a new switchable two-dimensional (2D) supramolecular polymer that serves as an ideal platform for the enrichment of phosphopeptides. A well-defined, positively charged metallacycle incorporated into the polymer endows the resultant polymer with a high affinity for phosphopeptides. Importantly, the stimuli-responsive nature of the polymer facilitates switchable binding affinity of phosphopeptides, thus resulting in an excellent performance in phosphopeptide enrichment and separation from model proteins. The polymer has a high enrichment capacity (165 mg/g) and detection sensitivity (2 fmol), high enrichment recovery (88%), excellent specificity, and rapid enrichment and separation properties. Additionally, we have demonstrated the capture of phosphopeptides from the tryptic digest of real biosamples, thus illustrating the potential of this polymeric material in phosphoproteomic studies.

Synthesis of Phospho-Polypeptides via Phosphate-Containing N-Carboxyanhydride: Application in Enzyme-Induced Self-Assembly, and Calcium Carbonate Mineralization.

An easy synthetic strategy was developed to synthesize the phosphate-functionalized amino acid N-carboxyanhydride (NCA), using simple primary amine initiators to obtain homo and block phospho-polypeptides with controlled molecular weight and molecular weight distribution. The methodology was extended to the synthesis of the end-functionalized homo polypeptides (15 to 50 repeat unit) and block co-polypeptides with PEG (0.7 K, 2 K, and 5 K) and glycopolypeptide (15-unit mannose glycopolypeptide) as one of the blocks. The deprotected fully water-soluble anionic phosphate-based polypeptides showed pH-dependent helical conformation with a helical content of 20 %, which further changed to ß-sheets upon addition of the enzyme alkaline phosphatase (ALP) due to dephosphorylation. The block co-polypeptide containing PEG as one of the blocks led to its self-assembly into colloidal structures, such as vesicles with a hydrodynamic diameter of ∼250 nm, due to the formation of amphiphilic block co-polymer upon dephosphorylation. The nature of the colloidal structures formed can be temporally controlled by the extent of dephosphorylation. Finally, the phospho-polypeptides serve as a template for the mineralization of calcium carbonate with varying polymorphs and morphologies.

Preorganization Increases the Self-Assembling Ability and Antitumor Efficacy of Peptide Nanomedicine.

Inspired by the biological process of phosphorylation for which different sites of the same protein may have different activities and functions, we utilized phosphatase-based enzyme-instructed self-assembly (EISA) to construct self-assembled nanomedicine from the precursors with different phosphorylated sites. We found that, although the obtained self-assembling molecules after EISA were identical, the changes of EISA catalytic sites could determine the outcome of molecular self-assembly. The precursor with the phosphorylated site in the middle preorganized before EISA, while the ones with other phosphorylated sites could not preorganize before EISA. After EISA, the preorganized precursor then resulted in more stable and ordered assemblies than those of the others, which showed increased cellular uptake and up to 1.7-fold higher efficacy in an antitumor therapeutic compared to those assembled from unorganized precursors.

Synthesis and Antimicrobial Activity of Phosphonopeptide Derivatives Incorporating Single and Dual Inhibitors.

In diagnostic microbiology, culture media are widely used for detection of pathogenic bacteria. Such media employ various ingredients to optimize detection of specific pathogens such as chromogenic enzyme substrates and selective inhibitors to reduce the presence of commensal bacteria. Despite this, it is rarely possible to inhibit the growth of all commensal bacteria, and thus pathogens can be overgrown and remain undetected. One approach to attempt to remedy this is the use of "suicide substrates" that can target specific bacterial enzymes and selectively inhibit unwanted bacterial species. With the purpose of identifying novel selective inhibitors, six novel phosphonopeptide derivatives based on d/l-fosfalin and ß-chloro-l-alanine were synthesized and tested on 19 different strains of clinically relevant bacteria. Several compounds show potential as useful selective agents that could be exploited in the recovery of several bacterial pathogens including Salmonella, Pseudomonas aeruginosa, and Listeria.

Site-Specific Phosphorylation of PDZ Domains.

Classical approaches for probing protein phosphorylation events rely on phosphomimicking amino acids or enzymatic phosphorylation of proteins. In many cases, phosphomimicking amino acids inadequately imitate actual protein phosphorylation, whereas the latter method suffers from an inability to control site specificity and stoichiometry. To circumvent these shortcomings, chemical biological approaches have been developed to enable introduction of phosphorylated amino acids into proteins in a reliable and controlled way. Here, we describe methods to make semisynthetic, phosphorylated PDZ domains, covering expressed protein ligation (EPL) strategies involving modifications within the N-terminal or C-terminal regions. We also enclose protocols for the biophysical characterization of the semisynthetic phosphorylated PDZ domains to establish whether the introduced phosphorylation affects protein structure, stability, and function.

Bifunctional Magnetic Supramolecular-Organic Framework: A Nanoprobe for Simultaneous Enrichment of Glycosylated and Phosphorylated Peptides.

Protein glycosylation and phosphorylation are two important protein post-translational modifications. Mass spectrometry (MS) has been proved to be a powerful technique in comprehensive characterization of protein glycosylation and phosphorylation; however, the complexity of biological matrices and weak ionization efficiency bring a big challenge. Capturing glycopeptides and phosphopeptides from complicated biological samples is indispensable before MS determinations. In this study, a bifunctional gallium ion immobilized magnetic pertriflated pillar[5]arene supramolecular-organic framework (magOTfP5SOF-Ga3+) was designed for the one-step simultaneous enrichment of glycopeptides and phosphopeptides. Thanks to the abundant sulfonic acid groups, the material owns strong hydrophilicity and leads to hydrophilic interaction chromatography for glycopeptides enrichment. Simultaneously, the high loading amount of gallium ion provides immobilized metal ion affinity for phosphopeptides enrichment. The established platform possesses quick magnetic response performance, high sensitivity (detection limits as low as 0.1 fmol and 0.05 fmol for glycopeptides and phosphopeptides, respectively), and good reusability. In addition, the method was applied to the determination of glycopeptides and phosphopeptides in clinical specimens, cell lysates, and mouse liver tissue samples, demonstrating its highly sensitive and specific glycoproteomics and phosphorproteomics analysis in complex biosamples.

New Developments in Microwave-Assisted Solid Phase Peptide Synthesis.

The unique combination of microwave heating with optimized carbodiimide activation has proven to be an indispensable technique for high-throughput peptide production. Here, we describe new methods in microwave-assisted solid phase peptide synthesis and optimized post-synthesis modifications that have been recently developed. These methods have drastically reduced synthesis time and solvent requirement while delivering peptides in high crude purities.

A study on the effect of synthetic α-to-ß3-amino acid mutations on the binding of phosphopeptides to 14-3-3 proteins.

Here we describe the synthesis of a series of α,ß-phosphopeptides, based on the phosphoepitope site on YAP1 (yes-associated protein 1), and the biochemical, biophysical and structural characterization of their binding to 14-3-3 proteins. The impact of systematic mono- and di-substitution of α → ß3 amino acid residues around the phosphoserine residue are discussed. Our results confirm the important role played by the +2 proline residue in the thermodynamics and structure of the phosphoepitope/14-3-3 interaction.

A Mass Spectrometry-Based Structural Assay for Activation-Dependent Conformational Changes in ß-Arrestins.

ß-Arrestins are key regulation proteins for G protein-coupled receptors (GPCRs) signaling. Experimental evidence suggests that ß-arrestins undergo conformational changes concomitant with binding to activated, phosphorylated GPCRs. We developed a mass spectrometry-based structural proteomic assay to monitor conformational changes associated with the activation of ß-arrestins. This assay utilizes synthesized phosphopeptides mimicking phosphorylated C-terminal tails of GPCRs to activate ß-arrestins. The activation-dependent conformational changes of ß-arrestins are revealed using limited proteolysis coupled with both SDS-PAGE and mass spectrometry analysis. As an in vitro ß-arrestin activation assay, this mass spectrometry-based structural method can be adapted as a simple but useful tool to study the nature and extent of conformational changes of ß-arrestins downstream of different receptors as well as ß-arrestin conformations associated with different functions, such as desensitization, internalization, and signaling.

Synthetic phosphopeptides: From spike-in standards to affinity tools for protein-protein interaction studies.

Synthetic isotope labeled phosphopeptides are valuable tools for the quantification and validation of phosphoproteome data. Here, we report that the same set of phosphopeptides, which are used as spike-in standards, can be successfully applied for identification of stimulus specific protein-protein interactions mediated by the respective phosphorylation sites. As a proof-of-concept, binding of two γH2AX (pS139) phosphosite specific interaction partners, MDC1 and 53BP1, was confirmed and elevated binding affinity was revealed in response to ionizing radiation. Our strategy is generally applicable and enables multiplexed validation and functional analysis of phosphorylation sites offering great potential for the follow-up of phosphoproteome studies.

Crystal structures of p120RasGAP N-terminal SH2 domain in its apo form and in complex with a p190RhoGAP phosphotyrosine peptide.

The Rho and Ras pathways play vital roles in cell growth, division and motility. Cross-talk between the pathways amplifies their roles in cell proliferation and motility and its dysregulation is involved in disease pathogenesis. One important interaction for cross-talk occurs between p120RasGAP (RASA1), a GTPase activating protein (GAP) for Ras, and p190RhoGAP (p190RhoGAP-A, ARHGAP35), a GAP for Rho. The binding of these proteins is primarily mediated by two SH2 domains within p120RasGAP engaging phosphorylated tyrosines of p190RhoGAP, of which the best studied is pTyr-1105. To better understand the interaction between p120RasGAP and p190RhoGAP, we determined the 1.75 Å X-ray crystal structure of the N-terminal SH2 domain of p120RasGAP in the unliganded form, and its 1.6 Å co-crystal structure in complex with a synthesized phosphotyrosine peptide, EEENI(p-Tyr)SVPHDST, corresponding to residues 1100-1112 of p190RhoGAP. We find that the N-terminal SH2 domain of p120RhoGAP has the characteristic SH2 fold encompassing a central beta-sheet flanked by two alpha-helices, and that peptide binding stabilizes specific conformations of the ßE-ßF loop and arginine residues R212 and R231. Site-directed mutagenesis and native gel shifts confirm phosphotyrosine binding through the conserved FLVR motif arginine residue R207, and isothermal titration calorimetry finds a dissociation constant of 0.3 ± 0.1 µM between the phosphopeptide and SH2 domain. These results demonstrate that the major interaction between two important GAP proteins, p120RasGAP and p190RhoGAP, is mediated by a canonical SH2-pTyr interaction.

Assembly of PGAM5 into Multimeric Complexes Provides a Mechanism for Allosteric Regulation of Phosphatase Activity.

Phosphoglycerate mutase family member 5 (PGAM5) is a serine/threonine phosphatase that has been localized to both inner and outer mitochondrial membranes. PGAM5 has been suggested to regulate multiple aspects of mitochondrial dynamics, including fission/fusion and mitophagy, through phosphatase-dependent and phosphatase-independent mechanisms. Understanding how the phosphatase activity of PGAM5 is regulated will provide new insight into signaling mechanisms that link changes in cell physiology with mitochondrial function. In this chapter, we describe methods for obtaining both multimeric and dimeric complexes of PGAM5 and for characterizing their kinetic properties. The ability to purify different PGAM5 complexes and to characterize their kinetic properties will enable detailed biophysical studies of the quaternary structures of the various PGAM5-containing complexes. The phosphatase activity of different PGAM5 complexes varies over three orders of magnitude. We suggest that the ability to generate PGAM5 complexes that have a wide range of phosphatase activities will facilitate screens to identify small molecules that modulate the phosphatase activity of PGAM5.

Enzymatic Assemblies Disrupt the Membrane and Target Endoplasmic Reticulum for Selective Cancer Cell Death.

The endoplasmic reticulum (ER) is responsible for the synthesis and folding of a large number of proteins, as well as intracellular calcium regulation, lipid synthesis, and lipid transfer to other organelles, and is emerging as a target for cancer therapy. However, strategies for selectively targeting the ER of cancer cells are limited. Here we show that enzymatically generated crescent-shaped supramolecular assemblies of short peptides disrupt cell membranes and target ER for selective cancer cell death. As revealed by sedimentation assay, the assemblies interact with synthetic lipid membranes. Live cell imaging confirms that the assemblies impair membrane integrity, which is further supported by lactate dehydrogenase (LDH) assays. According to transmission electron microscopy (TEM), static light scattering (SLS), and critical micelle concentration (CMC), attaching an l-amino acid at the C-terminal of a d-tripeptide results in the crescent-shaped supramolecular assemblies. Structure-activity relationship suggests that the crescent-shaped morphology is critical for interacting with membranes and for controlling cell fate. Moreover, fluorescent imaging indicates that the assemblies accumulate on the ER. Time-dependent Western blot and ELISA indicate that the accumulation causes ER stress and subsequently activates the caspase signaling cascade for cell death. As an approach for in situ generating membrane binding scaffolds (i.e., the crescent-shaped supramolecular assemblies), this work promises a new way to disrupt the membrane and to target the ER for developing anticancer therapeutics.

Efficient, Selective Removal of Human Pluripotent Stem Cells via Ecto-Alkaline Phosphatase-Mediated Aggregation of Synthetic Peptides.

The incomplete differentiation of human induced pluripotent stem cells (iPSCs) poses a serious safety risk owing to their potential tumorigenicity, hindering their clinical application. Here, we explored the potential of phospho-D-peptides as novel iPSC-eliminating agents. Alkaline phosphatases overexpressed on iPSCs dephosphorylate phospho-D-peptides into hydrophobic peptides that aggregate and induce cell death. We isolated a peptide candidate, D-3, that selectively and rapidly induced toxicity in iPSCs within 1 hr but had little influence on various non-iPSCs, including primary hepatocytes and iPSC-derived cardiomyocytes. Two hours of D-3 treatment efficiently eliminated iPSCs from both single cultures and co-cultures spiked with increasing ratios of iPSCs. In addition, D-3 prevented residual iPSC-induced teratoma formation in a mouse tumorigenicity assay. These results suggest the enormous potential of D-3 as a low-cost and effective anti-iPSC agent for both laboratory use and for the safe clinical application of iPSC-derived cells in regenerative medicine.

Unambiguous Identification of Serine and Threonine Pyrophosphorylation Using Neutral-Loss-Triggered Electron-Transfer/Higher-Energy Collision Dissociation.

Tandem mass spectrometry (MS/MS) has emerged as the core technology for identification of post-translational modifications (PTMs). Here, we report the mass spectrometry analysis of serine and threonine pyrophosphorylation, a protein modification that has eluded detection by conventional MS/MS methods. Analysis of a set of synthesized, site-specifically modified peptides by different fragmentation techniques shows that pyrophosphorylated peptides exhibit a characteristic neutral loss pattern of 98, 178, and 196 Da, which enables the distinction between isobaric pyro- and diphosphorylated peptides. In addition, electron-transfer dissociation combined with higher energy collision dissociation (EThcD) provides exceptional data-rich MS/MS spectra for direct and unambiguous pyrophosphosite assignment. Remarkably, sufficient fragmentation of doubly charged precursors could be achieved by electron-transfer dissociation (ETD) with increased supplemental activation, without losing the labile modification. By exploiting the specific fragmentation behavior of pyrophosphorylated peptides during collision-induced dissociation (CID), a data dependent neutral-loss-triggered EThcD acquisition method was developed. This strategy enables reliable pyrophosphopeptide identification in complex samples, without compromising speed and sensitivity.

Epitope mapping and structural basis for the recognition of phosphorylated tau by the anti-tau antibody AT8.

Microtubule-associated protein tau becomes abnormally phosphorylated in Alzheimer's disease and other tauopathies and forms aggregates of paired helical filaments (PHF-tau). AT8 is a PHF-tau-specific monoclonal antibody that is a commonly used marker of neuropathology because of its recognition of abnormally phosphorylated tau. Previous reports described the AT8 epitope to include pS202/pT205. Our studies support and extend previous findings by also identifying pS208 as part of the binding epitope. We characterized the phosphoepitope of AT8 through both peptide binding studies and costructures with phosphopeptides. From the cocrystal structure of AT8 Fab with the diphosphorylated (pS202/pT205) peptide, it appeared that an additional phosphorylation at S208 would also be accommodated by AT8. Phosphopeptide binding studies showed that AT8 bound to the triply phosphorylated tau peptide (pS202/pT205/pS208) 30-fold stronger than to the pS202/pT205 peptide, supporting the role of pS208 in AT8 recognition. We also show that the binding kinetics of the triply phosphorylated peptide pS202/pT205/pS208 was remarkably similar to that of PHF-tau. The costructure of AT8 Fab with a pS202/pT205/pS208 peptide shows that the interaction interface involves all six CDRs and tau residues 202-209. All three phosphorylation sites are recognized by AT8, with pT205 acting as the anchor. Crystallization of the Fab/peptide complex under acidic conditions shows that CDR-L2 is prone to unfolding and precludes peptide binding, and may suggest a general instability in the antibody.

Preorganized Peptide Scaffolds as Mimics of Phosphorylated Proteins Binding Sites with a High Affinity for Uranyl.

Cyclic peptides with two phosphoserines and two glutamic acids were developed to mimic high-affinity binding sites for uranyl found in proteins such as osteopontin, which is believed to be a privileged target of this ion in vivo. These peptides adopt a ß-sheet structure that allows the coordination of the latter amino acid side chains in the equatorial plane of the dioxo uranyl cation. Complementary spectroscopic and analytical methods revealed that these cyclic peptides are efficient uranyl chelating peptides with a large contribution from the phosphorylated residues. The conditional affinity constants were measured by following fluorescence tryptophan quenching and are larger than 10(10) at physiological pH. These compounds are therefore promising models for understanding uranyl chelation by proteins, which is relevant to this actinide ion toxicity.