Cristina Lamberti

First evidence of a membrane-bound, tyramine and β-phenylethylamine producing, tyrosine decarboxylase in Enterococcus faecalis: A two-dimensional electrophoresis proteomic study

The soluble and membrane proteome of a tyramine producing Enterococcus faecalis, isolated from an Italian goat cheese, was investigated. A detailed analysis revealed that this strain also produces small amounts of β‐phenylethylamine. Kinetics of tyramine and β‐phenylethylamine accumulation, evaluated in tyrosine plus phenylalanine‐enriched cultures (stimulated condition), suggest that the same enzyme, the tyrosine decarboxylase (TDC), catalyzes both tyrosine and phenylalanine decarboxylation: tyrosine was recognized as the first substrate and completely converted into tyramine (100% yield) while phenylalanine was decarboxylated to β‐phenylethylamine (10% yield) only when tyrosine was completely depleted. The presence of an aspecific aromatic amino acid decarboxylase is a common feature in eukaryotes, but in bacteria only indirect evidences of a phenylalanine decarboxylating TDC have been presented so far. Comparative proteomic investigations, performed by 2‐DE and MALDI‐TOF/TOF MS, on bacteria grown in conditions stimulating tyramine and β‐phenylethylamine biosynthesis and in control conditions revealed 49 differentially expressed proteins. Except for aromatic amino acid biosynthetic enzymes, no significant down‐regulation of the central metabolic pathways was observed in stimulated conditions, suggesting that tyrosine decarboxylation does not compete with the other energy‐supplying routes. The most interesting finding is a membrane‐bound TDC highly over‐expressed during amine production. This is the first evidence of a true membrane‐bound TDC, longly suspected in bacteria on the basis of the gene sequence.

Proteomic characterization of a selenium-metabolizing probiotic Lactobacillus reuteri Lb2 BM for nutraceutical applications.

Selenium (Se), Se‐cysteines and selenoproteins have received growing interest in the nutritional field as redox‐balance modulating agents. The aim of this study was to establish the Se‐concentrating and Se‐metabolizing capabilities of the probiotic Lactobacillus reuteri Lb2 BM, for nutraceutical applications. A comparative proteomic approach was employed to study the bacteria grown in a control condition (MRS modified medium) and in a stimulated condition (4.38 mg/L of sodium selenite). The total protein extract was separated into two pI ranges: 4–7 and 6–11; the 25 identified proteins were divided into five functional classes: (i) Se metabolism; (ii) energy metabolism; (iii) stress/adhesion; (iv) cell shape and transport; (v) proteins involved in other functions. All the experimental results indicate that L. reuteri Lb2 BM is able to metabolize Se(IV), incorporating it into selenoproteins, through the action of a selenocysteine lyase, thus enhancing organic Se bioavailability. This involves endo‐ergonic reactions balanced by an increase of substrate‐level phosphorylation, chiefly through lactic fermentation. Nevertheless, when L. reuteri was grown on Se a certain degree of stress was observed, and this has to be taken into account for future applicative purposes. The proteomic approach has proven to be a powerful tool for the metabolic characterization of potential Se‐concentrating probiotics.

Survey of Campylobacter jejuni in retail chicken meat products by application of a quantitative PCR protocol

Campylobacter-contaminated food products are currently the cause of the highest number of gastroenteritis cases in developed countries. Apart for biosafety measures at the primary production level, no other official control measures are currently in place for its control. This is partly due to the lack of quantitative data regarding the prevalence and contamination level of different food products by Campylobacter spp. that does not allow for quantitative risk assessment. PCR-based methods, applied without prior enrichment, in food samples circumvent limitations associated with the quantification of foodborne pathogens by traditional, culture-dependent methods. In this study, we report the development of a protocol, based on the amplification of the rpoB gene of Campylobacter jejuni, by quantitative PCR (qPCR), directly in food samples. The quantification limit of the protocol was determined to be in the order of 10 colony forming units (cfu)/g or ml of food sample. The optimized protocol was applied for the survey of C. jejuni in naturally contaminated poultry samples. In parallel, traditional sampling was also performed. A high percentage of samples (87%) resulted to be positive by qPCR, while no C. jejuni was detected by traditional analysis. Furthermore, important differences were observed in the detection by qPCR between samples before and after enrichment.

Different protein expression profiles in cheese and clinical isolates of Enterococcus faecalis revealed by proteomic analysis

The use of Enterococcus faecalis in the food industry has come under dispute because of the pathogenic potential of some strains of this species. In this study, we have compared the secretome and whole‐cell proteome of one food isolate (E. faecalis DISAV 1022) and one clinical isolate (E. faecalis H1) by 2‐DE and iTRAQ analyses, respectively. Extracellular protein patterns differed significantly, with only seven proteins common to both strains. Notably, only the clinical isolate expressed various well‐characterized virulence factors such as the gelatinase coccolysin (GelE) and the extracellular serine proteinase V8 (SprE). Moreover, various other putative virulence factors, e.g. superoxide dismutase, choline‐ and chitin‐binding proteins and potential moonlighting proteins, have been detected exclusively in the secretome of the clinical isolate, but not in the food isolate. The iTRAQ analysis of whole‐cell proteins of the two strains highlighted a stronger expression of pathogenic traits such as an endocarditis‐specific antigen and an adhesion lipoprotein in the pathogenic strain E. faecalis H1. Subsequently, six food isolates (including E. faecalis DISAV 1022) and six clinical isolates (including E. faecalis H1) were tested for the presence of gelatinase and protease activity in the culture supernatants. Both enzymatic activities were found in the clinical as well as the food isolates which clearly indicates that protease expression is strain specific and not representative for pathogenic isolates. Genetic analyses revealed that not only the gelatinase and serine protease genes but also the regulatory fsr genes must be present to allow protease expression.

Influence of ethanol, malate and arginine on histamine production of Lactobacillus hilgardii isolated from an Italian red wine

Wine, like other fermented foods, may contain biogenic amines produced by lactic acid bacteria via amino acids decarboxylation. The most relevant amines from the toxicological standpoint are histamine and tyramine. The complexity of fermented substrates makes it difficult to suggest a priori how variables can modulate amine production. Lactobacillus hilgardii ISE 5211 was isolated from an Italian red wine. Besides producing lactate from malate, this strain is also able to convert arginine to ornithine and histidine to histamine. In the present investigation we studied the influence of malate, arginine and ethanol on histamine accumulation by L. hilgardii ISE 5211. Ethanol concentrations above 13% inhibit both histamine accumulation and bacterial growth; concentrations below 9% affect neither growth nor histamine production. However, an ethanol concentration of 11% allows a low but continuous accumulation of histamine to occur. Arginine also delays histamine accumulation, while malate appears to have no effect on histidine–histamine conversion.

ADI pathway and histidine decarboxylation are reciprocally regulated in Lactobacillus hilgardii ISE 5211: proteomic evidence

Amine production by amino acid decarboxylation is a common feature that is used by lactic acid bacteria (LAB) to complement lactic fermentation, since it is coupled with a proton-extruding antiport system which leads to both metabolic energy production and the attenuation of intracellular acidity. Analogous roles are played in LAB by both malolactic fermentation (MLF) and the arginine deiminase (ADI) pathway. The present investigation was aimed at establishing reciprocal interactions between amino acid decarboxylation and the two above mentioned routes. The analyses were carried out on a Lactobacillus hilgardii strain (ISE 5211) that is able to decarboxylate histidine to histamine, which had previously been isolated from wine and whose complete genome is still unknown. The 2DE proteomic approach, followed by MALDI TOF–TOF and De Novo Sequencing, was used to study the protein expression levels. The experimental evidence has indicated that malate does not influence histidine decarboxylase (HDC) biosynthesis and that histidine does not affect the malolactic enzyme level. However, the expression of the ADI route enzymes, arginine deiminase and ornithine transcarbamylase, is down-regulated by histidine: this biosynthetic repression is more important (4-fold) in cultures that are not supplemented with arginine, but is also significant (2-fold) in an arginine supplemented medium that normally induces the ADI pathway. On the other hand, arginine partially represses HDC expression, but only when histidine and arginine are both present in the culture medium. This proteomic study has also pointed out a down-regulation exerted by histidine over sugar metabolism enzymes and a GroEL stress protein. These data, together with the reciprocal antagonism between arginine deimination and histidine decarboxylation, offer clue keys to the understanding of the accumulation of lactate, amine, ammonia and ethylcarbamate in wine, with consequent implications on different health risk controls.

Effects of Two Different Domestic Boiling Practices on The Allergenicity of Cow Milk Proteins

BACKGROUND The sale of raw drinking milk through automatic dispensers is permitted in some EU member states, but consumers are usually advised to boil the milk before consumption. The present study has been conducted to evaluate the effects of two common domestic boiling techniques on the proteins of raw milk and, in particular, on their potential allergenicity. RESULTS Native one-dimensional electrophoresis, N-terminal amino acid sequencing and immunoblotting have been used to characterize the protein pattern and to evaluate the possible changes in the allergenic properties of the processed milk. The main result of this investigation is that heating induces the aggregation of β-lactoglobulin in higher-molecular-weight products, while caseins seem to be more resistant to the treatments. β-Lactoglobulin aggregates have been found to be non-immunoreactive with the sera of subjects suffering from cows milk protein allergy. CONCLUSION Domestic boiling modifies the milk protein profile, causing a minor reduction in milk allergenicity.

Enhanced arginine biosynthesis and lower proteolytic profile as indicators of Saccharomyces cerevisiae stress in stationary phase during fermentation of high sugar grape must: A proteomic evidence

A strain of Saccharomyces (S) cerevisiae (ISE19), which displayed an initial good adaptation to a high sugar medium with increased acetate and glycerol production but weak overall growth/fermentation performances, was selected during the alcoholic fermentation of Cortese grape must. To obtain insights into the metabolic changes that occur in the must during growth in particular conditions (high ethanol, high residual sugars and low nitrogen availability) leading to a sluggish fermentation or even fermentation arrest, comparative in-gel proteomic analyses were performed on cells grown in media containing 200g/L and 260g/L of glucose, respectively, while the YAN (Yeast Assimilable Nitrogen) concentration was maintained as it was. Two post-translationally different arginine synthases (pIs 5.6 and 5.8) were found in higher abundances in the high glucose-grown cells, together with an increased abundance of a glycosyltransferase involved in cell-wall mannans synthesis, and of two regulatory proteins (K7_Bmh1p and K7_Bmh2p) that control membrane transport. In parallel, a proteinase K-like proteolytic enzyme and three other protein fragments (Indolepyruvate decarboxylase 1, Fba1p and Eno1p) were present in lower abundances in the high glucose condition, where oxidative stress and cell cycle involved enzymes were also found to be less abundant. The overall results suggest that in stationary phase stress conditions, leading to stuck fermentation, S. cerevisiae ISE19 decreases cell replication, oxidative stress responses and proteolytic activity, while induces other metabolic modifications that are mainly based on cell-wall renewal, regulation of the solute transport across the cell membrane and de novo arginine synthesis.