Yiping Sun

Dandruff-associated Malassezia genomes reveal convergent and divergent virulence traits shared with plant and human fungal pathogens

Fungi in the genus Malassezia are ubiquitous skin residents of humans and other warm-blooded animals. Malassezia are involved in disorders including dandruff and seborrheic dermatitis, which together affect >50% of humans. Despite the importance of Malassezia in common skin diseases, remarkably little is known at the molecular level. We describe the genome, secretory proteome, and expression of selected genes of Malassezia globosa. Further, we report a comparative survey of the genome and secretory proteome of Malassezia restricta, a close relative implicated in similar skin disorders. Adaptation to the skin environment and associated pathogenicity may be due to unique metabolic limitations and capabilities. For example, the lipid dependence of M. globosa can be explained by the apparent absence of a fatty acid synthase gene. The inability to synthesize fatty acids may be complemented by the presence of multiple secreted lipases to aid in harvesting host lipids. In addition, an abundance of genes encoding secreted hydrolases (e.g., lipases, phospholipases, aspartyl proteases, and acid sphingomyelinases) was found in the M. globosa genome. In contrast, the phylogenetically closely related plant pathogen Ustilago maydis encodes a different arsenal of extracellular hydrolases with more copies of glycosyl hydrolase genes. M. globosa shares a similar arsenal of extracellular hydrolases with the phylogenetically distant human pathogen, Candida albicans, which occupies a similar niche, indicating the importance of host-specific adaptation. The M. globosa genome sequence also revealed the presence of mating-type genes, providing an indication that Malassezia may be capable of sex.

Proteomic analysis of rat soleus muscle undergoing hindlimb suspension‐induced atrophy and reweighting hypertrophy

A proteomic analysis was performed comparing normal rat soleus muscle to soleus muscle that had undergone either 0.5, 1, 2, 4, 7, 10 and 14 days of hindlimb suspension‐induced atrophy or hindlimb suspension‐induced atrophied soleus muscle that had undergone 1 hour, 8 hour, 1 day, 2 day, 4 day and 7 days of reweighting‐induced hypertrophy. Muscle mass measurements demonstrated continual loss of soleus mass occurred throughout the 21 days of hindlimb suspension; following reweighting, atrophied soleus muscle mass increased dramatically between 8 hours and 1 day post reweighting. Proteomic analysis of normal and atrophied soleus muscle demonstrated statistically significant changes in the relative levels of 29 soleus proteins. Reweighting following atrophy demonstrated statistically significant changes in the relative levels of 15 soleus proteins. Protein identification using mass spectrometry was attempted for all differentially regulated proteins from both atrophied and hypertrophied soleus muscle. Five differentially regulated proteins from the hindlimb suspended atrophied soleus muscle were identified while five proteins were identified in the reweighting‐induced hypertrophied soleus muscles. The identified proteins could be generally grouped together as metabolic proteins, chaperone proteins and contractile apparatus proteins. Together these data demonstrate that coordinated temporally regulated changes in the skeletal muscle proteome occur during disuse‐induced soleus muscle atrophy and reweighting hypertrophy.

Proteomic analysis of the atrophying rat soleus muscle following denervation

A proteomic analysis was performed comparing normal rat soleus muscle to denervated soleus muscle at 0.5, 1, 2, 4, 6, 8 and 10 days post denervation. Muscle mass measurements demonstrated that the times of major mass changes occurred between 2 and 4 days post denervation. Proteomic analysis of the denervated soleus muscle during the atrophy process demonstrated statistically significant (at the p < 0.01 level) changes in 73 soleus proteins, including coordinated changes in select groups of proteins. Sequence analysis of ten differentially regulated proteins identified metabolic proteins, chaperone and contractile apparatus proteins. Together these data indicate that coordinated temporally regulated changes in the proteome occur during denervation‐induced soleus muslce atrophy, including changes in muscle metabolism and contractile apparatus proteins.

Tandem mass spectrometry methods for definitive protein identification in proteomics research.

Optimized procedures have been developed for the addition of sulfonic acid groups to the N‐termini of low‐level peptides. These procedures have been applied to peptides produced by tryptic digestion of proteins that have been separated by two‐dimensional (2‐D) gel electrophoresis. The derivatized peptides were sequenced using matrix‐assisted laser desorption/ionization (MALDI) post‐source decay (PSD) and electrospray ionization‐tandem mass spectrometry methods. Reliable PSD sequencing results have been obtained starting with sub‐picomole quantities of protein. We estimate that the current PSD sequencing limit is about 300 fmol of protein in the gel. The PSD mass spectra of the derivatized peptides usually allow much more specific protein sequence database searches than those obtained without derivatization. We also report initial automated electrospray ionization‐tandem mass spectrometry sequencing of these novel peptide derivatives. Both types of tandem mass spectra provide predictable fragmentation patterns for arginine‐terminated peptides. The spectra are easily interpreted de novo, and they facilitate error‐tolerant identification of proteins whose sequences have been entered into databases.

Sequencing of sulfonic acid derivatized peptides by electrospray mass spectrometry

We report the application of nanoelectrospray ionization tandem mass spectrometry (nES-MS/MS) and capillary LC/microelectrospray MS/MS (cLC/&mgr;ES-MS/MS) for sequencing sulfonic acid derivatized tryptic peptides. These derivatives were specifically prepared to facilitate low-energy charge-site-initiated fragmentation of C-terminal arginine-containing peptides, and to enhance the selective detection of a single series of y-type fragment ions. Both singly and doubly protonated peptides were analyzed by MS/MS and the results were compared with those from their derivatized counterparts. Model peptides and peptides from tryptic digests of gel-isolated proteins were analyzed. Derivatized singly protonated peptides fragment in the same way by nES-MS/MS as they do by post-source decay matrix-assisted laser desorption/ionization mass spectrometry (PSD-MALDI-MS). They produce fragment ion spectra dominated by y-ions, and the simplified spectra are readily interpreted de novo. Doubly protonated peptides fragment in much the same way as their non-derivatized doubly protonated counterparts. The fragmentation of doubly protonated derivatives is especially useful for sequencing peptides that possess a proline residue near the N-terminus of the molecule. The singly protonated forms of these proline-containing derivatives often show enhanced fragmentation on the N-terminal side of the proline and considerably reduced fragmentation on the C-terminal side. In addition, sulfonic acid derivatization increases the in-source fragmentation of arginine-containing peptides. This could be useful for sequence verification and sequence tagging for use in single stage mass spectrometry. Copyright 2000 John Wiley & Sons, Ltd.

Proteomic analysis of simulated occupational jet fuel exposure in the lung.

We analyzed protein expression in the cytosolic fraction prepared from whole lung tissue in male Swiss‐Webster mice exposed 1 h/day for seven days to aerosolized JP‐8 jet fuel at concentrations of 1000 and 2500 mg/m3, simulating military occupational exposure. Lung cytosol samples were solubilized and separated via large scale, high resolution two‐dimensional electrophoresis (2‐DE) and gel patterns scanned, digitized and processed for statistical analysis. Significant quantitative and qualitative changes in tissue cytosol proteins resulted from jet fuel exposure. Several of the altered proteins were identified by peptide mass fingerprinting, confirmed by sequence tag analysis, and related to impaired protein synthetic machinery, toxic/metabolic stress and detoxification systems, ultrastructural damage, and functional responses to CO2 handling, acid‐base homeostasis and fluid secretion. These results demonstrate a significant but comparatively moderate JP‐8 effect on protein expression and corroborate previous morphological and biochemical evidence. Further molecular marker development and mechanistic inferences from these observations await proteomic analysis of whole tissue homogenates and other cell compartment, i.e., mitochondria, microsomes, and nuclei of lung and other targets.

Proteomic analysis of rat soleus and tibialis anterior muscle following immobilization.

A proteomic analysis was performed comparing normal slow twitch type fiber rat soleus muscle and normal fast twitch type fiber tibialis anterior muscle to immobilized soleus and tibialis anterior muscles at 0.5, 1, 2, 4, 6, 8 and 10 days post immobilization. Muscle mass measurements demonstrate mass changes throughout the period of immobilization. Proteomic analysis of normal and atrophied soleus muscle demonstrated statistically significant changes in the relative levels of 17 proteins. Proteomic analysis of normal and atrophied tibialis anterior muscle demonstrated statistically significant changes in the relative levels of 45 proteins. Protein identification using mass spectrometry was attempted for all differentially regulated proteins from both soleus and tibialis anterior muscles. Four differentially regulated soleus proteins and six differentially regulated tibialis anterior proteins were identified. The identified proteins can be grouped according to function as metabolic proteins, chaperone proteins, and contractile apparatus proteins. Together these data demonstrate that coordinated temporally regulated changes in the proteome occur during immobilization-induced atrophy in both slow twitch and fast twitch fiber type skeletal muscle.

Glutathione adducts, not carbamylated lysines, are the major modification of lens α-crystallins from renal failure patients

Abstractα-Crystallins from the water-soluble and the water-insoluble, guanidine-soluble portions of lenses from four renal failure patients and two normal donors of similar age were isolated and enzymatically digested into peptides. Molecular weights of the peptides, determined by fast atom bombardment mass spectrometry, indicated modifications specifically associated with renal failure. The only modifications observed in theα-crystallins from renal failure patients, but not in the normal old lenses, were glutathione adducts to Cys 131 and Cys 142. These adducts were present in the lenses of all four renal failure patients, but not in the two normal old lenses. The four lenses from the renal failure patients were searched for evidence of carbamylation at lysyl or cysteinyl residues: carbamylation was not detected. Because the same mass spectrometric methods had previously demonstrated sufficient sensitivity and specificity to detect as little as 5% modification in the examination ofin vitro carbamylated bovine lenses, these results indicated that carbamylation is not a major modification of the lensα-crystallins of renal failure patients.

Assignment of all four disulfide Bridges in echistatin

Echistatin is a 49-amino-acid protein fromEchis carinatus venom. It contains four disulfide bonds. Since the disulfide bonding is critical for biological activity, it is very important to assign the disulfide linkage in this protein. Echistatin was incubated in 250 mM oxalic acid at 100°C for 4 hr under nitrogen. Under these conditions, many overlapping disulfide-containing peptides were identified by ionspray mass spectrometry. Ionspray MS/MS data indicate that the four disulfide bonds are Cys 2–Cys 11, Cys 7–Cys 32, Cys 8–Cys 37, and Cys 20–Cys 39. To our knowledge, this is the first time all four disulfide bonds in echistatin have been assigned in one experiment without disulfide bond exchange. This approach, which combines oxalic acid hydrolysis and ionspray MS/MS, may be very useful for assigning disulfide bridges in other proteins from the disintegrin family.

Sequencing of Gel-Isolated Proteins Using Microblotter Capillary Liquid Chromatography-Electrospray Mass Spectrometry

Enzymatic digests of proteins isolated by sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS–PAGE) were separated by capillary high-performance liquid chromatography (HPLC). The column eluate was split to an electrospray mass spectrometer on one side and to both a UV detector and a microblotter on the other side. Using the microblotter, the peptides eluted from the column were collected directly onto a polyvinylidene difluoride (PVDF) membrane for Edman sequencing. Thus, a peptide mass map from the mass spectrometric analysis and a prepared PVDF membrane for subsequent Edman sequencing were generated in a single experiment. The addition of molecular mass information to the blotted LC eluate is useful for determining the most important peaks to undergo Edman sequencing. Coupling the capillary HPLC with a microblotter to electrospray mass spectrometry provides an integrated system for separation, collection, and structural analysis of protein digests. It provides high levels of sensitivity, recovery, and convenience for protein characterization. Proteins loaded onto SDS–PAGE at low picomole levels can be analyzed by the new integrated system.