Quantitative proteome analysis of age‐related changes in mouse gastrocnemius muscle using mTRAQ

Aging is associated with a progressive loss of skeletal muscular function that often leads to progressive disability and loss of independence. Although muscle aging is well documented, the molecular mechanisms of this condition still remain unclear. To gain greater insight into the changes associated with aging of skeletal muscle, we performed quantitative proteomic analyses on young (6 months) and aged (27 months) mouse gastrocnemius muscles using mTRAQ stable isotope mass tags. We identified and quantified a total of 4585 peptides corresponding to 236 proteins (protein probability >0.9). Among them, 33 proteins were more than 1.5‐fold upregulated and 20 proteins were more than 1.5‐fold downregulated in aged muscle compared with young muscle. An ontological analysis revealed that differentially expressed proteins belonged to distinct functional groups, including ion homeostasis, energy metabolism, protein turnover, and Ca²⁺ signaling. Identified proteins included aralar1, β‐enolase, fatty acid‐binding protein 3, 3‐hydroxyacyl‐CoA dehydrogenase (Hadh), F‐box protein 22, F‐box, and leucine‐rich repeat protein 18, voltage‐dependent L‐type calcium channel subunit beta‐1, ryanodine receptor (RyR), and calsequestrin. Ectopic expression of calsequestrin in C2C12 myoblast resulted in decreased activity of nuclear factor of activated T‐cells and increased levels of atrogin‐1 and MuRF1 E3 ligase, suggesting that these differentially expressed proteins are involved in muscle aging.     

Development of a novel assay for proprotein converting enzyme activity on a multiplex bead‐based array system

We describe the development of a novel, robust assay system for determining the changes in activity of proprotein converting enzymes. An assay for prolyl oligopeptidase (POP) activity was constructed using a peptide‐streptavidin substrate coupled to magnetic microspheres and cleavage was detected by loss of streptavidin on the MAGPIX reader. Test analysis of postmortem pituitary extracts from schizophrenia patients showed an increase in POP activity compared to controls. The results were validated using both fluorometric and Western blot analyses for POP activity and immunoreactivity, respectively. The assays can be multiplexed for measuring the activity of multiple proprotein cleaving enzymes simultaneously in laboratory and clinical settings and should add valuable new information for conditions such as neuropsychiatric diseases, diabetes, endocrine dysfunction, and cancer, where effects on proteolysis of biologically active peptides play a key role.     

Patatin-related phospholipase pPLAIIIβ-induced changes in lipid metabolism alter cellulose content and cell elongation in Arabidopsis

The release of fatty acids from membrane lipids has been implicated in various plant processes, and the patatin-related phospholipases (pPLAs) constitute a major enzyme family that catalyzes fatty acid release. The Arabidopsis thaliana pPLA family has 10 members that are classified into three groups. Group 3 pPLAIII has four members but lacks the canonical lipase/esterase consensus catalytic sequences, and their enzymatic activity and cellular functions have not been delineated. Here, we show that pPLAIIIβ hydrolyzes phospholipids and galactolipids and additionally has acyl-CoA thioesterase activity. Alterations of pPLAIIIβ result in changes in lipid levels and composition. pPLAIIIβ-KO plants have longer leaves, petioles, hypocotyls, primary roots, and root hairs than wild-type plants, whereas pPLAIIIβ-OE plants exhibit the opposite phenotype. In addition, pPLAIIIβ-OE plants have significantly lower cellulose content and mechanical strength than wild-type plants. Root growth of pPLAIIIβ-KO plants is less sensitive to treatment with free fatty acids, the enzymatic products of pPLAIIIβ, than wild-type plants; root growth of pPLAIIIβ-OE plants is more sensitive. These data suggest that alteration of pPLAIIIβ expression and the resulting lipid changes alter cellulose content and cell elongation in Arabidopsis.     

Endoplasmic reticulum- and Golgi-localized phospholipase A2 plays critical roles in Arabidopsis pollen development and germination

The phospholipase A(2) (PLA(2)) superfamily of lipolytic enzymes is involved in a number of essential biological processes, such as inflammation, development, host defense, and signal transduction. Despite the proven involvement of plant PLA(2)s in many biological functions, including senescence, wounding, elicitor and stress responses, and pathogen defense, relatively little is known about plant PLA(2)s, and their genes essentially remain uncharacterized. We characterized three of four Arabidopsis thaliana PLA(2) paralogs (PLA(2)-β, -γ, and -δ) and found that they (1) are expressed during pollen development, (2) localize to the endoplasmic reticulum and/or Golgi, and (3) play critical roles in pollen development and germination and tube growth. The suppression of PLA(2) using the RNA interference approach resulted in pollen lethality. The inhibition of pollen germination by pharmacological PLA(2) inhibitors was rescued by a lipid signal molecule, lysophosphatidyl ethanolamine. Based on these results, we propose that plant reproduction, in particular, male gametophyte development, requires the activities of the lipid-modifying PLA(2)s that are conserved in other organisms.     

Convergent dynamics of the juvenile European sea bass gut microbiota induced by poly-β-hydroxybutyrate

Poly-β-hydroxybutyrate (PHB) is a bacterial energy and carbon storage compound which exhibits a controlling effect on the gastrointestinal microbiota. Its beneficial activities for aquaculture have already been shown in terms of increased disease resistance and growth performance in a number of studies. However, the action of PHB on the intestinal microbial community in the treated animals has not yet been studied in depth. In this research, the effects of PHB on the microbiota composition in the intestinal tract of juvenile sea bass were examined. It was found that fish cohabiting in the same tank were on average 87% similar regarding the intestinal microbiota. When subjected to the same treatment and environmental conditions but reared in different tanks, the compositions of the enteric communities diverged. The provision of PHB overruled this tank effect by sustaining a microbial core community in the gut that represented 60% of the total bacterial diversity at the highest PHB level of 10%. The microbial community compositions converged between replicate tanks upon supplementation of PHB and were characterized by high dynamics and increased evenness. The results are discussed in the framework of hypotheses that try to relate the intestinal microbial community composition to the health status of the host organisms.     

Quantification of proteins using data-independent analysis (MSE) in simple andcomplex samples: a systematic evaluation

A MS‐based method for the quantification of proteins termed data‐independent analysis (or MS^E) has been introduced recently. Although this method has been applied to the analysis of various types of biological samples, a thorough evaluation to assess the performance of this approach has yet to be conducted. Presented here is the first systematic and comprehensive study investigating the MS^E approach for quantitative analysis of low‐, medium‐, and high‐complexity samples. We demonstrate that this method has a linear dynamic range spanning three orders of magnitude with a limit of quantification of 61 amol/uL in low‐complexity samples and 488 amol/uL in high‐complexity samples. In addition, comprehensive sequence coverage was obtained and accurate quantification achieved for expression ratios ranging from 1:1.5 to 1:6. However, underestimation of ratios was detected independent of sample type, consistent with other quantitative proteomic methods. The present study provides validation of the MS^E approach for accurate quantitative proteomic analysis of biological samples while, at the same time, proving high sequence coverage of target proteins.     

On the multi-temporal correlation between photosynthesis and soil CO2 efflux: reconciling lags and observations

Although there is increasing evidence of the temporal correlation between photosynthesis and soil CO(2) efflux, no study has so far tested its generality across the growing season at multiple study sites and across several time scales. Here, we used continuous (hourly) data and applied time series analysis (wavelet coherence analysis) to identify temporal correlations and time lags between photosynthesis and soil CO(2) efflux for three forests from different climates and a grassland. Results showed the existence of multi-temporal correlations at time periods that varied between 1 and 16 d during the growing seasons at all study sites. Temporal correlations were strongest at the 1 d time period, with longer time lags for forests relative to the grassland. The multi-temporal correlations were not continuous throughout the growing season, and were weakened when the effect of variations in soil temperature and CO(2) diffusivity on soil CO(2) efflux was taken into account. Multi-temporal correlations between photosynthesis and soil CO(2) efflux exist, and suggest that multiple biophysical drivers (i.e. photosynthesis, soil CO(2) diffusion, temperature) are likely to coexist for the regulation of allocation and transport speed of carbon during a growing season. Future studies should consider the multi-temporal influence of these biophysical drivers to investigate their effect on the transport of carbon through the soil-plant-atmosphere continuum.     

Molecular mechanism of an adverse drug–drug interaction of allopurinol and furosemide in gout treatment

Gout patients receiving a combination of allopurinol and furosemide require higher allopurinol doses to achieve the target serum urate (SU) of <6 mg/dl (Stamp et al., 2012) [1]. Our study aimed to identify the molecular basis for this observation. We used a fluorimetric assay to determine the impact of furosemide and oxypurinol (the active metabolite of allopurinol) on xanthine oxidase (XO) activity. Immunoblot analysis quantified expression of XO and AMP-kinase (AMPK) in drug-treated human liver (HepG2) and primary kidney (HRCE) cells. In silico analysis identified miR-448 as a potential XO-regulator, whose expression level in HepG2 cells was examined by qPCR.