Surface Shave: Revealing the Apical-Restricted Uroglycome.

This study aimed to investigate the highly differentiated urothelial apical surface glycome. The functions of the mammalian urothelium, lining the majority of the urinary tract and providing a barrier against toxins in urine, are dependent on the correct differentiation of urothelial cells, relying on protein expression, modification, and complex assembly to regulate the formation of multiple differentiated cell layers. Protein glycosylation, a poorly studied aspect of urothelial differentiation, contributes to the apical glycome and is implicated in the development of urothelial diseases. To enable surface glycome characterization, we developed a method to collect tissue apical surface N- and O-glycans. A simple, novel device using basic laboratory supplies was developed for enzymatic shaving of the luminal bladder urothelial surface, with subsequent release and mass spectrometric analysis of apical surface O- and N-glycans, the first normal mammalian urothelial N-glycome to be defined. Trypsinization of superficial glycoproteins was tracked using immunolabeling of the apically expressed uroplakin 3a protein to optimize enzymatic release, without compromising the integrity of the superficial urothelial layer. The approach developed for releasing apical tissue surface glycans allowed for comparison with the N-glycome of the total porcine bladder urothelial cells and thus identification of apical surface glycans as candidates implicated in the urothelial barrier function. Data are available in MassIve: MSV000087851.

Modeling Glycan Processing Reveals Golgi-Enzyme Homeostasis upon Trafficking Defects and Cellular Differentiation.

The decoration of proteins by carbohydrates is essential for eukaryotic life yet heterogeneous due to a lack of biosynthetic templates. This complex carbohydrate mixture-the glycan profile-is generated in the compartmentalized Golgi, in which level and localization of glycosylation enzymes are key determinants. Here, we develop and validate a computational model for glycan biosynthesis to probe how the biosynthetic machinery creates different glycan profiles. We combined stochastic modeling with Bayesian fitting that enables rigorous comparison to experimental data despite starting with uncertain initial parameters. This is an important development in the field of glycan modeling, which revealed biological insights about the glycosylation machinery in altered cellular states. We experimentally validated changes in N-linked glycan-modifying enzymes in cells with perturbed intra-Golgi-enzyme sorting and the predicted glycan-branching activity during osteogenesis. Our model can provide detailed information on altered biosynthetic paths, with potential for advancing treatments for glycosylation-related diseases and glyco-engineering of cells.

Ionisation bias undermines the use of matrix-assisted laser desorption/ionisation for estimating peptide deamidation: Synthetic peptide studies demonstrate electrospray ionisation gives more reliable response ratios.

RATIONALE: Although mass spectrometry (MS) is routinely used to determine deamination in peptide mixtures, the effects of the choice of ionisation source have not yet been investigated. In particular, matrix-assisted laser desorption/ionisation (MALDI) has become a popular tool with which to measure levels of glutamine deamidation in ancient proteins. Here we use model synthetic peptides to rigorously compare MALDI and electrospray ionisation (ESI). METHODS: We used two synthetic peptides, with glutamine (Q) in one substituted for glutamic acid (E) in the other, to investigate the suitability of MALDI and ESI sources for the assessment of deamidation in peptides using MS. We also compared measurements of the same Q- and E-containing peptide mixtures using two different mass analysers (time-of-flight (TOF) and Fourier transform ion cyclotron resonance (FT-ICR)). RESULTS: When standard mixtures of the Q- and E-containing peptides were analysed using MALDI, under-representation of the E-containing peptide was observed. This observation was consistent between analyses carried out using either TOF or FT-ICR-MS. When the same mixtures were analysed using ESI FT-ICR-MS, no ionisation bias was observed. CONCLUSIONS: MALDI may not be a suitable ionisation method for the determination of deamidation in peptide mixtures. However, ESI was successfully used to determine the ratio in known mixtures of Q- and E-containing peptides. These preliminary observations warrant further investigation into ionisation bias when measuring deamidation in other peptide sequences.

Trehalose During Two Stress Responses in Acanthamoeba: Differentiation Between Encystation and Pseudocyst Formation.

The non-reducing disaccharide trehalose can serve as a protectant against a range of environmental stressors, such as heat, cold, or dehydration, in both prokaryotes and eukaryotes, with the exception of vertebrates. Here, we analyzed trehalose metabolism in the facultatively parasitic organism Acanthamoeba castellanii, known to respond to unfavorable external conditions by forming two resistant stages: a cyst, produced in the case of chronic stress, and a pseudocyst, formed in reaction to acute stress. The possible role of trehalose in the resistant stages was investigated using a combination of bioinformatic, molecular biological and biochemical approaches. Genes for enzymes from a widespread trehalose-6-synthase-trehalose-6-phosphate phosphatase (TPS-TPP) pathway and a prokaryotic trehalose synthase (TreS) pathway were identified. The expression patterns of the genes during encystation and pseudocyst formation were analyzed and correlated with the time course of cellular trehalose content determined mass spectrometrically. The data clearly demonstrate fundamental differences between encystation and pseudocyst formation at the level of cellular metabolism.

Fabrication and Application of Isotopically Labelled Gold Arrays for Multiplexed Peptide Analysis.

A new array-based technology for the simultaneous capture, chemical labelling and mass spectrometry analysis of peptides is presented. Isotopically labelled self-assembled monolayer (SAM) gold arrays are constructed and used simultaneously to capture and label a range of peptides. The array-immobilised, labelled peptides were released by MALDI ablation, analysed by MALDI mass spectrometry and readily identified as labelled peptides from their characteristic isotope pattern. This new solid-phase array platform has the advantage of minimal sample manipulation and is suitable for multiple analyses of single protein digests on a single MALDI target plate.

Structural and mechanistic insight into N-glycan processing by endo-α-mannosidase.

N-linked glycans play key roles in protein folding, stability, and function. Biosynthetic modification of N-linked glycans, within the endoplasmic reticulum, features sequential trimming and readornment steps. One unusual enzyme, endo-α-mannosidase, cleaves mannoside linkages internally within an N-linked glycan chain, short circuiting the classical N-glycan biosynthetic pathway. Here, using two bacterial orthologs, we present the first structural and mechanistic dissection of endo-α-mannosidase. Structures solved at resolutions 1.7-2.1 Å reveal a (ß/α)(8) barrel fold in which the catalytic center is present in a long substrate-binding groove, consistent with cleavage within the N-glycan chain. Enzymatic cleavage of authentic Glc(1/3)Man(9)GlcNAc(2) yields Glc(1/3)-Man. Using the bespoke substrate α-Glc-1,3-α-Man fluoride, the enzyme was shown to act with retention of anomeric configuration. Complexes with the established endo-α-mannosidase inhibitor α-Glc-1,3-deoxymannonojirimycin and a newly developed inhibitor, α-Glc-1,3-isofagomine, and with the reducing-end product α-1,2-mannobiose structurally define the -2 to +2 subsites of the enzyme. These structural and mechanistic data provide a foundation upon which to develop new enzyme inhibitors targeting the hijacking of N-glycan synthesis in viral disease and cancer.

Evaluation of a solid-supported tagging strategy for mass spectrometric analysis of peptides.

We have explored two divinylbenzene cross-linked polystyrene supports for use in a solid-supported N-terminal peptide tagging strategy. Resin-bound tags designed to be cleaved in a single step at the N-terminus of peptides have been devised and explored as peptide N-terminal tagging reagents (constructs) for subsequent mass spectrometric analysis. While the brominated tagging approach shows promise, the use of these specific solid supports has drawbacks, in terms of tagging reaction scale, for real applications in proteomics.

Development and application of mass spectrometric methods for the analysis of progranulin N-glycosylation.

PGRN is a modular protein with 7 1/2 repeats of the granulin domain separated by short spacer sequences. Elevated expression of PGRN is associated with cancer growth, while mutations of PGRN cause frontotemporal lobar degeneration (FTLD), an early onset form of dementia. PGRN is a glycoprotein, containing five N-glycosylation consensus sequons, three of which fall within granulin domains. A method tailored to enable detailed analysis of the PGRN oligosaccharides and glycopeptides has been developed. The approach involves in-gel deglycosylation using peptide-N-glycosidase F (PNGase F) followed by permethylation of the released oligosaccharides. Permethylation was applied for rapid sample clean-up and to improve sensitivity of MS detection and mass spectrometric fragmentation. Reversed-phase monolithic LC-ESI-MS/MS was used for analysis of permethylated oligosaccharides, enabling structural characterization of released N-linked glycans in one chromatographic run. In-gel tryptic digestion was further applied to the gel pieces containing deglycosylated protein, for N-glycosylation site determination. In addition, glycopeptides were produced using in-solution pronase digestion to identify species of N-glycan attached at particular sites. The method developed was applied to progranulin (PGRN) to characterize the structures of the released glycans and to identify the sites of glycosylation. Glycosylation of four out of five potential PGRN N-glycosylation consensus sites was demonstrated (the final one remains undetermined), with one of the four observed to be partially occupied. Two of the observed glycosylation sites occur within granulin domains, which may have important implications for understanding the structural basis of PGRN action.

Evaluation of gel electrophoresis conditions for the separation of metal-tagged proteins with subsequent laser ablation ICP-MS detection.

Although laser ablation (LA)-ICP-MS has been reported for the determination of metalloproteins separated by gel electrophoretic techniques (GE), systematic studies that define the conditions essential for successful measurements are still scarce. In this paper we present the results of our studies of basic conditions for the effective application of GE-LA-ICP-MS for the separation of metal-binding proteins, focusing on their stability during GE and post-separation gel treatment. The stability of metal-protein complexes (haemoglobin, myoglobin, superoxide dismutase, carbonic anhydrase, transferrin, albumin, cytochrome c) during GE is dependent on the nature of the metal-protein interaction and the principle of separation. We have observed that non-denaturing GE is a suitable separation technique for most metal-protein complexes (e.g. Zn in carbonic anhydrase and Fe in Tf and myoglobin were quantitatively recovered in a spiked liver cytosol), whereas separation by denaturing GE strongly impaired the stability of the complexes. Equally important is the post-separation treatment of the gel to enable successful detection of the metal. LA-ICP-MS requires drying of the gel without loss of protein-bound metal or cracking of the gel. This was successfully achieved using glycerol followed by heating. We demonstrate that staining of the gel prior to LA-ICP-MS using silver or Coomassie blue is not recommended, since most protein-bound metal is lost during the staining procedure. Furthermore it has been shown that only line scanning with a speed of less than 30 microm/s can reliably distinguish between lines 1 mm apart, while raster spot analysis carries the risk of misinterpretation due to contamination in/on inhomogeneous gels.

A method of isolating the collagen (I) alpha2 chain carboxytelopeptide for species identification in bone fragments.

We present a novel method for the isolation and analysis of the bone collagen (I) alpha2 chain carboxytelopeptide as a species biomarker. Conventional methods for the analysis and sequencing of mixtures of proteins and peptides commonly involve using the protease trypsin to cleave proteins present in the sample. However, in the study of collagen, these methods result in very complex mixtures of peptides that are difficult to analyze and the acquired results are not reproducible. Here we use bacterial collagenase (from Clostridium histolyticum) for its ability to cleave the highly unusual Gly-Xaa-Yaa repeating sequence of collagen, where Xaa usually is Pro and Yaa often is Hyp. Followed by a simple isolation step using a reverse phase solid phase extraction cartridge, the alpha2 (I) chain carboxytelopeptide can be readily analyzed by matrix-assisted laser desorption/ionization-mass spectrometry (MALDI-MS) and the results can be used to distinguish between different species of origin.