Marco Balestrieri

Failure to increase glucose consumption through the pentose-phosphate pathway results in the death of glucose-6-phosphate dehydrogenase gene- deleted mouse embryonic stem cells subjected to oxidative stress

Mouse embryonic stem (ES) glucose-6-phosphate (G6P) dehydrogenase-deleted cells ( G6pd delta), obtained by transient Cre recombinase expression in a G6pd -loxed cell line, are unable to produce G6P dehydrogenase (G6PD) protein (EC 1.1.1.42). These G6pd delta cells proliferate in vitro without special requirements but are extremely sensitive to oxidative stress. Under normal growth conditions, ES G6pd delta cells show a high ratio of NADPH to NADP(+) and a normal intracellular level of GSH. In the presence of the thiol scavenger oxidant, azodicarboxylic acid bis[dimethylamide], at concentrations lethal for G6pd delta but not for wild-type ES cells, NADPH and GSH in G6pd delta cells dramatically shift to their oxidized forms. In contrast, wild-type ES cells are able to increase rapidly and intensely the activity of the pentose-phosphate pathway in response to the oxidant. This process, mediated by the [NADPH]/[NADP(+)] ratio, does not occur in G6pd delta cells. G6PD has been generally considered essential for providing NADPH-reducing power. We now find that other reactions provide the cell with a large fraction of NADPH under non-stress conditions, whereas G6PD is the only NADPH-producing enzyme activated in response to oxidative stress, which can act as a guardian of the cell redox potential. Moreover, bacterial G6PD can substitute for the human enzyme, strongly suggesting that a relatively simple mechanism of enzyme kinetics underlies this phenomenon.

Evaluation of oxidative damage in mozzarella cheese produced from bovine or water buffalo milk

Abstract Technological processes are the main sources of protein and lipid oxidation in food. The oxidative status was determined in a soft Italian cheese, namely mozzarella, produced from water buffalo or bovine milk. The amount of protein-bound carbonyls, dityrosine and α-lactalbumin aggregates were measured to evaluate the extent of protein oxidation. The α-tocopherylquinone/α-tocopherol ratio and the trolox-equivalent antioxidant capacity were used as redox markers in the fat fraction. The levels of protein-bound carbonyls and α-lactalbumin aggregates were found significantly higher in bovine mozzarella than in buffalo mozzarella. On the other hand, higher amounts of redox markers were found in buffalo mozzarella. The levels of dityrosine aggregates were similar in the two types of cheese. The data suggest that protein and fat are more protected against oxidative structure alterations in buffalo mozzarella than in bovine mozzarella.

Conjugated linoleic acid protects against gliadin-induced depletion of intestinal defenses.

SCOPE The involvement of oxidative stress in gluten-induced toxicity has been evidenced in vitro and in clinical studies but has never been examined in vivo. We recently demonstrated the protective activity of conjugated linoleic acid (CLA), which functions by the activation of nuclear factor erythroid 2-related factor2 (Nrf2), a key transcription factor for the synthesis of antioxidant and detoxifying enzymes (phase 2). Here, we evaluate the involvement of nuclear factor erythroid 2-related factor2 in gliadin-mediated toxicity in human Caco-2 intestinal cells and in gliadin-sensitive human leukocyte antigen-DQ8 transgenic mice (DQ8) and the protective activity of CLA. METHODS AND RESULTS Gliadin effects in differentiated Caco-2 cells and in DQ8 mice, fed with a gliadin-containing diet with or without CLA supplementation, were evaluated by combining enzymatic, immunochemical, immunohistochemical, and quantitative real-time PCR (qRT-PCR) assays. Gliadin toxicity was accompanied by downregulation of phase 2 and elevates proteasome-acylpeptide hydrolase activities in vitro and in vivo. Notably, gliadin was unable to generate severe oxidative stress extent or pathological consequences in DQ8 mice intestine comparable to those found in celiac patients and the alterations produced were hampered by CLA. CONCLUSION The beneficial effects of CLA against the depletion of crucial intestinal cytoprotective defenses indicates a novel nutritional approach for the treatment of intestinal disease associated with altered redox homeostasis.

Surface-exposed glycoproteins of hyperthermophilic Sulfolobus solfataricus P2 show a common N-glycosylation profile.

Cell surface proteins of hyperthermophilic Archaea actively participate in intercellular communication, cellular uptake, and energy conversion to sustain survival strategies in extreme habitats. Surface (S)-layer glycoproteins, the major component of the S-layers in many archaeal species and the best-characterized prokaryotic glycoproteins, were shown to have a large structural diversity in their glycan compositions. In spite of this, knowledge on glycosylation of proteins other than S-layer proteins in Archaea is quite limited. Here, the N-glycosylation pattern of cell-surface-exposed proteins of Sulfolobus solfataricus P2 were analyzed by lectin affinity purification, HPAEC-PAD, and multiple mass spectrometry-based techniques. Detailed analysis of SSO1273, one of the most abundant ABC transporters present in the cell surface fraction of S. solfataricus, revealed a novel glycan structure composed of a branched sulfated heptasaccharide, Hex4(GlcNAc)2 plus sulfoquinovose where Hex is d-mannose and d-glucose. Having one monosaccharide unit more than the glycan of the S-layer glycoprotein of S. acidocaldarius, this is the most complex archaeal glycan structure known today. SSO1273 protein is heavily glycosylated and all 20 theoretical N-X-S/T (where X is any amino acid except proline) consensus sequence sites were confirmed. Remarkably, we show that several other proteins in the surface fraction of S. solfataricus are N-glycosylated by the same sulfated oligosaccharide and we identified 56 N-glycosylation sites in this subproteome.

Estradiol esterification in the human preovulatory follicle

In the preovulatory follicle, the LH surge stimulates progesterone production, reduces estradiol synthesis, and scales up the permeability of the blood-follicle barrier. The purpose of this study was to investigate whether the extent of these changes is correlated with the levels of estradiol, estradiol esters, and cholesteryl esters in the follicular fluid. The follicular levels of progesterone, estradiol, estradiol linoleate, cholesterol, and cholesteryl linoleate were measured by HPLC. The estradiol linoleate/estradiol ratio, which reflects the efficiency of in vivo estradiol esterification, and the cholesteryl linoleate/cholesterol ratio were calculated and found negatively correlated. The estradiol level was positively correlated with the cholesteryl linoleate/cholesterol ratio while negatively correlated with the estradiol linoleate/estradiol ratio. The in vitro activity of lecithin-cholesterol acyltransferase, the enzyme esterifying both cholesterol and estradiol, was assayed by incubating the fluid with labeled substrates. This activity was not correlated with either the estradiol linoleate/estradiol or the cholesteryl linoleate/cholesterol ratio. The enzyme K(m) and V(max) values were lower with estradiol than with cholesterol. Higher estradiol linoleate/estradiol ratios and lower cholesteryl linoleate/cholesterol ratios were associated with higher level of Haptoglobin penetration into the follicle. This level, which was determined by ELISA, was found increased with increased progesterone concentration and, therefore, used as a marker of the LH-stimulated permeability of the blood-follicle barrier. Our data suggest that early preovulatory follicles contain more cholesteryl esters and less estradiol esters than follicles closer to ovulation.

Synthesis of ascorbate and urate in the ovary of water buffalo.

Blood flow interruption is associated with oxygen depletion and loss of factors for function and survival in downstream tissues or cells. Hypoxia and absence of gonadotropins trigger apoptosis and atresia in the ovary. We studied the antioxidant response of follicular cells to plasma deprivation in ovaries dissected from water buffalo. Aliquots of follicular fluid were aspirated from each antral follicle, before and during incubation of the ovaries at 39°C. Urate, ascorbate, retinol and α-tocopherol in the fluid were, titrated by High Performance Liquid Chromatography (HPLC) with spectrophotometric or spectrofluorimetric detection. The total antioxidant capacity of follicular fluid was determined as absorbance decrease, following addition of a source of radical chromophores. The more the incubation progressed, the higher levels of urate, ascorbate and total antioxidant capacity were found. Conversely, changes in concentration of the liposoluble antioxidants were not observed. Ascorbate synthesizing activity in the follicle was demonstrated by detecting the enzyme L-gulono-γ-lactone oxidase in microsomes prepared from granulosa cells. These cells were also analyzed for the expression of the enzyme CPP32. The enzyme level, measured as DEVD-p-nitroanilide cleaving activity, was found related with the immunoreactivity to anti-CPP32 antibodies. Negative correlation between the enzyme activity (which is known to be induced by peroxynitrite) and the follicular level of urate (which scavenges peroxynitrite) was also observed. The amount of nitrotyrosine, a product of peroxynitrite attack on proteins, was measured in follicular fluids by Enzyme Linked ImmunoSorbent Assay (ELISA). This amount was found positively correlated with the CPP32 activity, and negatively correlated with the urate level in follicular fluid. Alterations in concentrations of ascorbate or urate may be associated with oxidative stress during follicular atresia.

A novel class of bifunctional acylpeptide hydrolases – potential role in the antioxidant defense systems of the Antarctic fish Trematomus bernacchii

Oxidative challenge is an important factor affecting the adaptive strategies of Antarctic fish, but data on antioxidant defenses in these organisms remain scarce. In this context, a key role could be played by acylpeptide hydrolase (APEH), which was recently hypothesized to participate in the degradation of oxidized and cytotoxic proteins, although its physiological function is still not fully clarified. This study represents the first report on piscine members of this enzyme family, specifically from the Antarctic teleost Trematomus bernacchii. The cDNAs corresponding to two apeh genes were isolated, and the respective proteins were functionally and structurally characterized with the aim of understanding the biological significance of these proteases in Antarctic fish. Both APEH isoforms (APEH‐1Tb and APEH‐2Tb) showed distinct temperature‐kinetic behavior, with significant differences in the Km values. Moreover, beside the typical acylpeptide hydrolase activity, APEH‐2Tb showed remarkable oxidized protein endohydrolase activity towards oxidized BSA, suggesting that this isoform could play a homeostatic role in removing oxidatively damaged proteins, sustaining the antioxidant defense systems. The 3D structures of both APEHs were predicted, and a possible relationship was found between the substrate specificity/affinity and the marked changes in the number of charged residues and hydrophobicity properties surrounding their catalytic sites. Our results demonstrated the occurrence of two APEH isoforms in T. bernacchii, belonging to different phylogenetic clusters, identified for the first time, and showing distinct molecular and temperature–kinetic behaviors. In addition, we suggest that the members of the new cluster ‘APEH‐2’ could participate in reactive oxygen species detoxification as phase 3 antioxidant enzymes, enhancing the protein degradation machinery.

Identification of a Cell-Bound Extracellular Protease Overproduced by Sulfolobus solfataricus in Peptide-Rich Media

A new protease, named SsMTP was identified from the archeon Sulfolobus solfataricus. The enzyme is associated to the cell-membrane and over-produced in response to the peptide-enriched media. SsMTP has a molecular mass of 120 kDa showing optimal activity at pH 2.0 in the temperature range 70 - 90 degrees C, and a half-life of 20 days at 80 degrees C. Primary structure analysis revealed that SsMTP represents a novel type of multi-domain thermopsin-like protease containing the catalytic domain followed by two distinct domains, PKD and Y_Y_Y, which are usually involved in a range of protein-protein interactions among the extracellular proteins.

Identification and Characterisation of a Novel Acylpeptide Hydrolase from Sulfolobus Solfataricus: Structural and Functional Insights

A novel acylpeptide hydrolase, named APEH-3Ss, was isolated from the hypertermophilic archaeon Sulfolobus solfataricus. APEH is a member of the prolyl oligopeptidase family which catalyzes the removal of acetylated amino acid residues from the N terminus of oligopeptides. The purified enzyme shows a homotrimeric structure, unique among the associate partners of the APEH cluster and, in contrast to the archaeal APEHs which show both exo/endo peptidase activities, it appears to be a “true” aminopeptidase as exemplified by its mammalian counterparts, with which it shares a similar substrate specificity. Furthermore, a comparative study on the regulation of apeh gene expression, revealed a significant but divergent alteration in the expression pattern of apeh-3Ss and apehSs (the gene encoding the previously identified APEHSs from S. solfataricus), which is induced in response to various stressful growth conditions. Hence, both APEH enzymes can be defined as stress-regulated proteins which play a complementary role in enabling the survival of S. solfataricus cells under different conditions. These results provide new structural and functional insights into S. solfataricus APEH, offering a possible explanation for the multiplicity of this enzyme in Archaea.

New antimicrobial peptides against foodborne pathogens: From in silico design to experimental evidence

Recently there has been growing interest in the discovery of new antimicrobial agents to increase safety and shelf-life of food products. Here, we developed an innovative approach by introducing the concept that mitochondrial targeting peptides (MTP) can interact and disrupt bacterial membranes, acting as antimicrobial agents. As proof-of-principle, we used a multidisciplinary strategy by combining in silico predictions, docking simulations and antimicrobial assays, to identify two peptides, MTP1 and MTP2, which were structurally and functionally characterized. Both compounds appeared effective against Listeria monocytogenes, one of the most important foodborne pathogens. Specifically, a significant bactericidal activity was evidenced with EC50 values of 16.8±1.2μM for MTP1 and 109±7.0μM for MTP2. Finally, NMR structure determinations suggested that MTP1 would be oriented into the membrane bilayer, while the molecular shape of MTP2 could indicate porin-mediated antimicrobial mechanisms, as predicted using molecular docking analysis. Therefore, MTPs represent alternative sources to design new potential bio-preservatives.