Multiplex Real-Time PCR with HRM for Detection of Lactobacillus sakei and Lactobacillus curvatus in Food Samples

Optimization of fermentation processes requires monitoring the species composition of starter cultures and their growth during fermentation. Most starter cultures contain closely related species. Nowadays, high-resolution melting (HRM) analysis is extensively used for multiplex identification of closely related species. In the present paper, we applied real-time polymerase chain reaction (PCR) with HRM analysis for the detection and differentiation of Lactobacillus sakei and L. curvatus. A primer pair was selected for the site of the rpoA gene of Lactobacillus spp. Eleven starter cultures and fifteen fermented sausages with a known bacterial composition were successfully tested using real-time PCR with HRM analysis with the developed primer pair.

In vitro comparison of the effects of probiotic, commensal and pathogenic strains on macrophage polarization

Macrophages are important with respect to both innate and adaptive immune responses and are known to differentiate into pro-inflammatory M1- or anti-inflammatory M2-phenotypes following activation. In order to study how different bacteria affect macrophage polarization, we exposed murine RAW 264.7 macrophages to sixteen different strains representing probiotic strains, pathogens, commensals and strains of food origin. Increased inducible nitric oxide synthase (iNOS) or arginase-1 gene expression indicates M1 or M2 polarization, respectively, and was quantified by qRT-PCR. Strains of Escherichia and Salmonella elevated iNOS expression more so than strains of Enterococcus, Lactobacillus and Lactococcus, indicating that Gram-negative strains are more potent M1 inducers. However, strain-specific responses were observed. For instance, Escherichia coli Nissle 1917 was a poor inducer of iNOS gene expression compared to the other E. coli strains, while Enterococcus faecalis Symbioflor-1 was more potent in this respect compared to all the eleven Gram-positive strains tested. Macrophage polarization was further characterized by quantifying secreted pro- and anti-inflammatory cytokines. Exposure to the pathogen E. coli 042 produced a cytokine profile indicating M1 differentiation, which is in accordance with the PCR data. However, exposure to most strains resulted in either high or low secretion levels of all cytokines tested, rather than a clear M1 or M2 profile. In general, the Gram-negative strains induced high levels of cytokine secretion compared to the Gram-positive strains. Interestingly, strains of human origin had a higher impact on macrophages compared to strains of food origin.

Proteome analysis of Lactobacillus plantarum strain under cheese-like conditions

As a food grade fermentation starter, Lactobacillus plantarum (L. plantarum) also named as the secondary starters during cheese ripening. In this study, the concentration of NaCl was screened as the main factor in the cheese-like conditions (15°C, pH5.2, 6% NaCl) to assess the potential properties of L. plantarum. A comprehensive proteome profile of L. plantarum strain was analyzed with iTRAQ proteomics methods fractionated by SCX chromatography. Proteins involved in carbohydrate transport and metabolism, cell envelope, peptide-glycan biosynthesis and lipid transport and metabolism were found significant changes. Meanwhile, the same trends were found in mRNA expression levels analyzed by RT-PCR. Some general transportation proteins related to ion transporters were detected as more abundant, which may reveal a rescue mechanism of the microbe in sodium-dependent glucose transfer. The understanding of L. plantarum proteome in salt tolerance could be useful to get strain adapted for specific applications.

BIOLOGICAL SIGNIFICANCE

The bacterial biota has a primary role in affecting cheese quality. Under cheese-like conditions, L. plantarum mainly increased the levels of enzymes that responsible for the flavour development during cheese ripening. However, the mechanisms of proteomic adaptation remain largely unclear in unraveling details of the salt tolerance of L. plantarum. This study revealed a dramatic change involved in carbohydrate transport and metabolism, cell envelope, peptide-glycan biosynthesis, lipid transport and metabolism, and glycolysis. Meanwhile, these pathways provide a comprehensive proteome profile of L. plantarum survived under cheese-like conditions. Furthermore, this study shows that iTRAQ proteomics provide more reliable information in describing the molecular rescue strategy of L. plantarum in sodium-dependent glucose transfer.

The spxB gene as a target to identify Lactobacillus casei group species in cheese

This study focused on the spxB gene, which encodes for pyruvate oxidase. The presence of spxB in the genome and its transcription could be a way to produce energy and allow bacterial growth during carbohydrate starvation. In addition, the activity of pyruvate oxidase, which produces hydrogen peroxide, could be a mechanism for interspecies competition. Because this gene seems to provide advantages for the encoding species for adaptation in complex ecosystems, we studied spxB in a large set of cheese isolates belonging to the Lactobacillus casei group. Through this study, we demonstrated that this gene is widely found in the genomes of members of the L. casei group and shows variability useful for taxonomic studies. In particular, the HRM analysis method allowed for a specific discrimination between Lactobacillus rhamnosus, Lactobacillus paracasei and L. casei. Regarding the coding region, the spxB functionality in cheese was shown for the first time by real-time PCR, and by exploiting the heterogeneity between the L. casei group species, we identified the bacterial communities encoding the spxB gene in this ecosystem. This study allowed for monitoring of the active bacterial community involved in different stages of ripening by following the POX pathway.

High resolution melting analysis (HRM) as a new tool for the identification of species belonging to the Lactobacillus casei group and comparison with species-specific PCRs and multiplex PCR

The correct identification and characterisation of bacteria is essential for several reasons: the classification of lactic acid bacteria (LAB) has changed significantly over the years, and it is important to distinguish and define them correctly, according to the current nomenclature, avoiding problems in the interpretation of literature, as well as mislabelling when probiotic are used in food products. In this study, species-specific PCR and HRM (high-resolution melting) analysis were developed to identify strains belonging to the Lactobacillus casei group and to classify them into L. casei, Lactobacillus paracasei and Lactobacillus rhamnosus. HRM analysis confirmed to be a potent, simple, fast and economic tool for microbial identification. In particular, 201 strains, collected from International collections and attributed to the L. casei group, were examined using these techniques and the results were compared with consolidated molecular methods, already published. Seven of the tested strains don't belong to the L. casei group. Among the remaining 194 strains, 6 showed inconsistent results, leaving identification undetermined. All the applied techniques were congruent for the identification of the vast majority of the tested strains (188). Notably, for 46 of the strains, the identification differed from the previous attribution.

Evaluation of high-resolution melting and other molecular methods in discrimination of Lactobacillus isolates

AIMS

Fermented and probiotic products are mainly based on the activity of diverse Lactobacillus species. Distinguishing of these species, especially the closely related ones might be problematic. Our aim was to compare and evaluate molecular methods that have the potential of discrimination and might serve as alternatives of traditional microbiological techniques.

METHODS AND RESULTS

In our experiments, PCR methods using general and species-specific bacterial primers, RFLP, sequencing and HRM assays were tested and their efficiency compared. A new universal primer pair was designed for amplification of short fragments of the 16S rDNA of six Lactobacillus, a Lactococcus and a Streptococcus species; furthermore, successful HRM analysis was performed on them that resulted in the separation of each species, including the almost indistinguishable Lact. paracasei ssp. paracasei and Lact. paracasei ssp. tolerans subspecies.

CONCLUSIONS

The results showed that HRM might be a useful, time- and cost-saving one-step tool for preliminary classification of isolates, although the use of additional techniques, like species-specific PCR, analysis of RFLP patterns and sequencing, might be necessary for confirmation of the results.

SIGNIFICANCE AND IMPACT OF THE STUDY

The newly developed HRM primers offer a quick and efficient tool for discrimination of lactobacilli, including very closely related Lactobacillus subspecies.