Abstract
Limosilactobacillus reuteri ZJ625 and Ligilactobacillus salivarius ZJ614 are potential probiotic bacteria with improved benefits when administered to the host as a multi-strain preparation. To elucidate the mechanisms of cell-to-cell crosstalk between these two strains, we studied their intracellular and extracellular proteomes in co-culture by liquid-chromatography mass-spectrometry (LC-MS) using Dionex Nano-RSLC and fusion mass spectrometer. The experiment consisted of five biological replicates, and samples were collected during the mid-exponential growth phase. The quantitative proteomic profiles revealed several differentially expressed proteins (DEPs), which are down- or up-regulated between and within groups for both the intracellular and extracellular proteomes. These DEPs include proteins synthesising autoinducer-2, a sensor compound for cell-to-cell bacterial crosstalk during quorum sensing in mixed culture. Other important DEPs identified include enolase, phosphoglycerate kinase, and l-lactate dehydrogenase, which play roles in carbohydrate metabolism. Proteins associated with transcription, ATP production and transport across the membrane, DNA repair, and those with the potential to bind to the host epithelium were also identified. The post-translational modifications associated with the proteins include oxidation, deamidation, and ammonia loss. Importantly, this study revealed a significant expression of S-ribosylhomocysteine lyase (luxS) involved in synthesising autoinducer-2 that plays important roles in quorum sensing, aiding bacterial cell-to-cell crosstalk in co-cultures. The proteome of L. salivarius ZJ614 was most affected when co-cultured with L. reuteri ZJ625. In contrast, omitting some medium components from the defined medium exerted more effects on L. reuteri ZJ625 than L. salivarius ZJ614.
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Introduction
Probiotics are safe-to-consume microbial preparations that modulate the gut microbiome and enhance mucosal immunity through interactions with the host intestinal epithelium [1]. Although the mechanism of actions of probiotics is not fully understood, these beneficial microbes are characterised by some molecular effectors on the cell that interacts with the gut microbiome and produces bioactive substances [2]. Probiotics alter the gastric pH, compete with pathogenic microbes for nutrients and attachment sites, and inhibit the proliferation of pathogenic organisms by producing antimicrobial substances such as bacteriocins [3,4,5]. Probiotic-microbiome interactions contribute to health by suppressing the proliferation of pathogens, particularly in oral or vaginal microbial imbalances [5]. The intake of probiotics re-establish gut microbiome balances, maintains intestinal barrier integrity, modulates immune responses, inhibits pathogens, and ameliorates chronic inflammation [6].
Some microbes with probiotic effects include species and strains of yeast, lactobacilli, and Bifidobacterium commonly used in food, drugs, and feed additives [7]. Traditionally, Bifidobacterium and lactobacilli are abundant in the gut and fermented foods as starter cultures during fermentation [2, 8, 9]. Recently, other bacterial species, including Akkermansia muciniphila [10] and Faecalibacterium prausnitzii have been identified to benefit the host and termed next-generation probiotics [11]. Maintaining the gut microbiome and its interactions with the host is important in sustaining intestinal homeostasis [12]. Clinical studies have revealed the potential of probiotics to ameliorate acute inflammation in pouchitis patients [13,14,15]. Probiotics also improve the absorption of amino acids in the gut and enhance the growth performance of mammals post-weaning [16, 17]. LAB inhibits food spoilage bacteria and prolongs the shelf life of fermented food [18]. Lactobacillus and Bifidobacterium, including L. acidophilus, Bifidobacterium longum, Ligilactobacillus salivarius, and Limosilactobacillus reuteri, regulate the levels of inflammatory cytokines such as TNF-α, IL-6, and IL-1β [19]. Despite this, knowledge of the mechanisms of host-microbe interactions and microbial structures relating to probiotic actions are poorly understood [20].
Limosilactobacillus reuteri is an ideal organism for studying the evolutionary behaviour of gut symbionts primarily due to its ability to colonise diverse hosts, including birds [21]. In some vertebrates like pigs, chickens, and rodents, L. reuteri is a dominant species that forms a biofilm-like union with the epithelium of the upper digestive tract [22, 23] and modulates the gut microbiome [24, 25]. L. reuteri, like other probiotics, exerts anti-inflammatory effects, enhances gut barrier functions, stimulates the repair of damaged mucosa [26, 27], and inhibits pathogens through the secretion of organic acids, ethanol, reuterin, and reutericyclin [28]. Furthermore, L. reuteri maintains health and alleviates disease along the gut-brain axis [29]; attenuates hepatic diseases [30], inflammatory bowel disease, cystic fibrosis [31]; and enhances insulin sensitivity [32]. Ligilactobacillus salivarius also play functional roles in strengthening the intestinal integrity [33] and decreasing inflammatory cytokines in the serum and bacterial translocations and modulates the gut microbiome [34]. Feeding piglets with L. salivarius post-weaning increases daily weight gain while alleviating post-weaning diarrhoea [24, 35]. Thus indicating the potential of L. salivarius to prevent and mitigate colonic inflammation by modulating the gut microbiota [36]. To fully derive probiotics benefits, understanding strain-specific actions is necessary for a targeted therapeutic approach development [12].
Proteomics is the study of the identities and quantification, prediction of complexes, interactions, post-translational modifications, and cellular localization of the proteins expressed in a cell or an entire organism [37, 38]. Additionally, proteomics is used to study the responses of a biological system to defined physiological perturbations [38]. The ability of probiotics to attach to the host intestine is partly mediated through the presence of surface proteins [39]. Hence, studying the intracellular and surface proteome (secretome) of L. reuteri ZJ625 and L. salivarius ZJ614 in co-culture can reveal the mechanism of intercellular interactions between the two strains. To elucidate the mechanisms of intercellular crosstalk between L. salivarius ZJ614 and L. reuteri ZJ625 in co-culture, proteomics was employed to study the differentially expressed proteins and their associations with different physiological processes. We also examined the post-translational modifications and protein-protein interactions to understand how co-culturing affects the intracellular and extracellular proteome of L. salivarous ZJ614 and L. reuteri ZJ625.
Methodology
Bacterial Source
The isolates were sourced from the culture collection of the Gastrointestinal Microbiology and Biotechnology Unit, Agricultural Research Council, Animal Production Institute Irene, Pretoria, South Africa, based on a previous study where L. salivarius ZJ614 and L. reuteri ZJ625 were isolated from indigenous South African Windsnyer pigs. L. salivarius ZJ614 and L. reuteri ZJ625 were characterised and confirmed for probiotics properties such as auto- and co-aggregation, resistance to gastric acid, and the potential to transfer antimicrobial resistance genes. When tested in experimental animals, they performed better when administered in a co-culture [24].
Experimental Design
The nutritional needs of L. salivarius ZJ614 and L. reuteri ZJ625 were determined to formulate defined media that adequately support their growth. The minimal defined media was prepared following a series of leave-one-out experiments to determine the minimum nutrient requirements of the strains. Moreover, we examined the growth kinetics of the strains in these media to establish the optimal sampling points to harvest them for proteomics studies. The results of the composition of the defined media and the growth behaviours of L. salivarius ZJ614 and L. reuteri ZJ625 were published in our previous work [40]. The experiment was performed by culturing L. salivarius ZJ614 and L. reuteri ZJ625 in single- and co-cultures in the complete chemically defined (CDM) and minimally defined (MDM) media with five biological replicates resulting in fifteen CDM and MDM cultures, respectively, and a total of thirty (30) samples for both. The culture of L. salivarius ZJ614 in CDM and MDM is abbreviated CLS and MLS, respectively. Of L. reuteri ZJ625, CDM is CLR, and MLR is for culture in MDM. For the co-cultures of both isolates, the culture in MDM is abbreviated as MLRLS, while for CDM, CLRLS was used.
Culture and Sample Preparations
The strains were cultured singly and in co-cultures anaerobically at 37 °C overnight. The bacterial growth was arrested at 18 h post-incubation, corresponding to the mid-exponential growth phase. The harvested cultures were centrifuged (12,000 × g) for 30 s, and the cell pellets were washed twice using 0.8% physiological buffered saline solution and straightway stored at − 80 °C. The supernatant (for secretome analysis) was collected in sterile 2-ml Eppendorf tubes for the respective samples and stored at − 80 °C.
Extraction of Intracellular and Extracellular Proteins
The bacterial cell pellets were resuspended in Tris-buffer having 5 mM Tris (2-carboxyethyl) phosphine hydrochloride (TCEP) and placed in a cooled sonic batch for 30 s, followed by vortex at high speed for 30 s. This procedure was repeated 5 times for each sample, followed by centrifuging (at 12,000 × g) the solubilised pellets for 10 min to pellet insoluble material. Protein concentration was then determined from the soluble portion.
Secretome samples (medium supernatant) were concentrated using 4 mL Amicon 3 kDa NMW cut-off filters. The samples were concentrated to 500 mL before dilution with Tris buffer to 5 mL (10 × dilution). This was repeated twice before protein concentration was determined at 280 nm using a NanoDrop spectrophotometer (Thermo Scientific).
On-Bead Protein Digestion
The chemicals used for this work are analytical grade or equivalent. The extracted proteins were diluted in 100 mM Tris–HCl (Sigma) containing 100 mM NaCl and 1% SDS (Sigma) followed by reduction using 5 mM triscarboxyethyl phosphine (TCEP; Fluka) in 100 mM Tris buffer at 60 °C for 1 h. Methylation of cysteine residues was carried out using 20 mM S-methyl methanethiosulfonate (Sigma) in 100 mM triethylammonium bicarbonate (TEAB) at room temperature for 30 min. Following thiol methylation, a solution of 100 mM ammonium acetate, 30% acetonitrile, and pH 4.5 was used as a binding buffer to dilute the samples twofold. The protein solution was then added to MagResyn (Resyn Biosciences), a hydrophilic interaction liquid chromatography (HILIC) magnetic particle prepared according to the manufacturer’s guide and incubated at 4 °C overnight to allow for protein binding. This was followed by removing the supernatant and washing the magnetic particles using the washing buffer (95% acetonitrile (ACN; Romil) twice. The washing was proceeded by suspending the magnetic particles in 25 mM ammonium bicarbonate containing trypsin (New England Biosystems) at a ratio of 1:50. The mixture was then incubated for 18 h at 37 °C, followed by peptide extraction using 50 mL of 15-trifluoroacetic acid (TFA) (Sigma). The samples were lyophilised and dissolved in 50 mL 2% acetonitrile-H2O; 0.1% formic acid solution (FA; Sigma) for analysis.
Liquid-Chromatography Mass-Spectrometry Analysis
Liquid chromatography was performed using the Dionex nano-RSLC system with a 5 mm × 300 μm trap column (Thermo Scientific) and a CSH 25 cm × 75 μm × 1.7 μm particle size analytical column. The solvent system used consisted of loading-solvent A (2% acetonitrile–water; 0.1% formic acid) and solvent B (100% acetonitrile–water). The samples were loaded onto the trap column using loading solvent at a flow rate of 2μL/min from a temperature-controlled autosampler set at 7 °C. Loading was performed for 5 min before the sample was eluted onto the analytical column. The flow rate was set to 300 nL/minute, and the gradient generated 5.0–30%B over 60 min and 30–50%B from 60 to 80 min. Chromatography was performed at 45 °C, and the outflow was delivered to the mass spectrometer.
A fusion mass spectrometer fitted with a NanoSpray Flex ionisation source (Thermo Scientific) was used for mass spectrometry analysis. The samples were infused via a stainless-steel nano-pore emitter. A positive mode with a spray voltage of 1.8 kV and ion transfer capillary at 275 °C was used for data collection. Internal spectral standardisation was performed using polysiloxane ions with a mass-to-charge ratio (m/z) of 445.12003. An orbitrap detector was used in acquiring MS1 scans and data in profile mode. The orbitrap detector was programmed to scan at 120,000 resolutions over a range of 375 to 1500 with an automatic gain control (AGC) target of 4 E5 and the highest injection time of 50 ms. To acquire MS2, a monoisotopic precursor selection of the ion with charges + 2 to + 7 and an error tolerance of ± 10 ppm was used. Precursor ions were excluded from fragmentation once for a period of 60 s. The quadrupole mass analyser with an HCD energy of 30% was employed for selecting the precursor ions for fragmentation in HCD mode. The data were obtained in centroid mode following fragment ions detection in the Orbitrap mass analyser at 30,000 resolutions and AGC target of 5E4 at the highest injection time of 100 ms.
Bioinformatics and Data Analysis
The raw data generated from the mass spectrometer were imported into Proteome Discoverer v1.4 (Thermo Scientific) and processed using the Sequest algorithm. The processed data were parsed against the Lactobacilli database using a semi-tryptic cleavage with 2 allowed missed cleavages. The precursor and fragment mass tolerances were 10 ppm and 0.02 Da, respectively. Deamidation (NQ) and oxidation (M) were set as dynamic modifications. Peptide validation was performed using the target-decoy PSM validator node. The search results were imported into Scaffold Q + (v5.2.2) (www.proteomesoftware.com) for downstream statistical analysis. Student’s t-test (p < 0.05, Benjamini-Hochberg) employing multiple test corrections and normalisation of 0.0 was carried out on the data to determine the statistical significance of the expressed proteins and identification of differentially expressed proteins (DEPs). The DEPs and their levels of expression, p-values, and functions were presented as tables. Furthermore, protein-protein interaction (PPI) network analyses were carried out using String Version 11.5 (https://string-db.org/) [41]. The PPI data were exported as vector files for network analyses using Cytoscape v3.9.1 (https://apps.cytoscape.org/) [42] and annotation/interpretation using AutoAnnotate v1.4.0 (http://baderlab.org/Software/AutoAnnotate), a Cytoscape sub-software for network analysis and interpretation [43]. The functions of the DEPs were determined by mapping the identified protein on the UniProt database via the UniProtKB using ChEBI (https://www.uniprot.org/) [44], and pathways analyses using Kyoto Encyclopedia of Genes and Genomes (KEGG) (https://www.genome.jp/kegg/pathway.html). The functional enrichment data were exported in tab-delimited formats and summarised by FDR for visualisation using Tidyverse v1.3.0 [45] in R v4.2.1 [46].
Criteria for Protein Identification
The MS/MS-based peptide and identified proteins were confirmed using Scaffold (version 5.1.2, Proteome Software Inc., Portland, OR). Identified peptides were accepted at more than 88.0% probability of achieving a false discovery rate (FDR) of less than 0.1%. The Scaffold Local FDR algorithm was used to assign the peptide probabilities from Sequest. In contrast, the peptide prophet algorithm set the peptide probabilities from X! Tandem [47] with Scaffold delta-mass correction. Proteins were identified at a greater than 6.0% probability of obtaining an FDR of less than 1.0% and having not less than 2 identified peptides. Protein probabilities were assigned by the Protein Prophet algorithm [48]. However, proteins containing similar peptides, not differentiable based on MS/MS analysis alone, were classified to satisfy the principles of parsimony. In contrast, the proteins having significant peptide evidence were grouped into clusters.
Results
Bacterial Growth and Cell Density
The strains were harvested from the defined media at 18 h post-incubation after measuring the pH and growth densities at 600 nm. The pH of the bacterial culture indicates a drop in pH 18 h post-incubation for the experimental groups, irrespective of culture conditions. The growth densities indicate relatively higher densities in the co-culture compared to the single cultures on both the complete and minimal defined media. The average growth densities and pH for the growth of L. reuteri ZJ625 and L. salivarius ZJ614 were computed and presented in Table 1.
Protein Identification
The samples were compared between groups to identify the proteins and differential proteins from the different experimental groups. The proteins were identified at p < 0.05, 1.0% false discovery rate (FDR) protein threshold, minimum peptides of 2 and peptide threshold of 0.1% FDR. For the group comparison of the intracellularly expressed proteins (Fig. 1A), the highest total amount of proteins was observed from L. reuteri ZJ625 in CDM and MDM (CLR vs CLR) and that of L. salivarius ZJ614 in CDM and MDM (MLS vs CLS), while the lowest number of proteins were observed between the co-cultures in the complete and minimal defined media (CLRLS vs MLRLS). For the extracellularly expressed proteins (secretome), the highest number of proteins was observed between L. reuteri ZJ625 and the co-culture (CLR vs CLRLS). In contrast, the lowest was observed in CLS vs MLS. The numbers of unique and common proteins expressed between and within groups for intracellularly and extracellularly expressed proteins are presented in Fig. 1A, B respectively.
Identification of Differentially Expressed Proteins (DEPs)
To identify the DEPs between the groups, quantitative protein profiles revealed the expression level (either high or low) using a student t-test at p < 0.05. The analysis of the DEPs of the intracellularly expressed proteins between CLR and CLRLS showed two significant differential proteins linked to the 50 s ribosomal protein, which is high in the co-culture (L. reuteri ZJ625 plus L. salivarius ZJ614) and low in the single culture. Of the total expressed proteins between CLS and CLRLS, 420 proteins were significantly differentially expressed. The DEPs include clusters of elongation factor TU, Chaperon GroEl, DNA-directed RNA polymerase subunit, 30S ribosomal proteins, ATP synthase subunits, and isoleucine tRNA ligase. The comparison of MLRLS and CLRLS revealed 149 DEPs that are either up- or down-regulated depending on the experimental group. The differential proteins observed from MLRLS vs CLRLS include S-ribosylhomocysteine lyase (luxS), phosphocarrier protein HPr, Redox-sensing transcriptional repressor Rex, chaperon GroEL, a cluster of protein translocase subunit, and chaperon protein DnaK, among others. Comparison of CLR and MLR revealed 47 differential proteins (p < 0.05), which are also associated with chaperone GroEL, a cluster of arginine tRNA ligase, ornithine carbamoyl transferase, and a cluster of phosphoglycerate kinase. Although differential proteins were observed when CLS and MLS were compared, the quantitative profile was insignificant between these groups. Also, no significant DEPs were identified between MLR and MLRLS, and only one DEP belonging to a cluster of aspartate tRNA ligase was observed between MLS and MLRLS (Table 2).
For the secretome, the highest number of DEPs was observed between CLS vs CLRLS, followed by MLS vs MLSLR, and CLS vs MLS, while the lowest was observed between CLR vs CLRLS, followed by CLRLS vs MLRLS and CLR vs MLR. However, no DEPs were observed between MLR vs MLRLS. The observed DEPs include chaperonin, 50S ribosomal protein, cysteine-tRNA ligase, cell division protein, adenylosuccinate synthase, peptide chain release factor, phosphoglycerate kinase, glucose-6-phosphate isomerase, elongation factor, ribosome-recycling factor, chaperone protein, enolase, and S-adenosylmethionine, among others. Some important DEPs observed from the intracellularly and extracellularly expressed proteins, their quantitative profiles, and their biological functions are listed in Tables 2 and 3. The differential proteins are displayed as scatter and volcano plots (Supplementary Fig. 1), while the distribution is presented as a barplot (Fig. 2).
Functional Enrichment Analyses of the Differentially Expressed Proteins
To map the metabolic potential of the differentially expressed proteins between and within the groups, we conducted network enrichment analyses against L. reuteri and L. salivarius genomes. Overall, the network analyses for both the intracellularly and extracellularly expressed proteomes indicated that the protein-protein interactions networks have significantly more interactions than expected (very low p-value < 0.005) (Fig. 3). Thus, revealing partial biological connections of the proteins as a group (Table 4). The DEPs are associated with several biological processes and molecular functions and are distributed in the bacteria’s cellular, anatomical entities, cytoplasm, and intracellular components (Fig. 4). The metabolic pathway enrichment analysis revealed the association of the DEPs in important metabolic pathways, including cellular metabolic processes, organic substances metabolism, protein metabolism, and transcription/translation processes. In the same way, metabolic functional analysis revealed the involvement of the DEPs in enzymatic activities, RNA binding, translation, and protein transport across the cell. (Fig. 5)
Post-Translation Modifications
Different post-translational modifications were identified on the proteins from the other experimental groups. The post-translational modifications associated with the significantly differential proteins include oxidation, deamidation, ammonia loss, methylthiolation, and dehydration. Table 5 lists examples of some of the DEPs and the associated PTMs. However, the same PTMs were observed in intracellular and extracellularly expressed proteomes, with variations in the associated experimental groups.
Discussion
The species of the genus Lactobacillus include several beneficial strains with roles in fermented food products and as probiotics, revealed by their genomes harbouring genes with functional traits [49,50,51]. Limosilactobacillus reuteri ZJ625 and Ligilactobacillus salivarius ZJ614 are important potential probiotics with benefits, including pathogenic microbe inhibition, suppression of anti-inflammatory cytokines, and improvement of gastrointestinal functions in post-weaning piglets through the modulation of the intestinal microbiota [24]. Dlamini et al. [24] showed that the functional effects of consuming L. salivarius ZJ614 and L. reuteri ZJ625 were enhanced in multi-strain preparation compared to their single-strain formulations. Previous studies have also revealed the preference for multi-strain probiotics over single-strain preparations due to the strain, disease, and host specificities of different probiotic microbes [52, 53]. However, the mechanisms of the enhanced benefits derived from multi-strain probiotics must be better understood. To elucidate the interactions between L. salivarius ZJ614 and L. reuteri ZJ625, we used labelled-free proteomics to study the mechanisms of cell-to-cell crosstalk between the two isolates in co-cultures using defined media. Defined media were used for culturing the isolates to avert the confounding challenges associated with data interpretation using undefined enriched media [40, 54, 55].
In this study, the intracellular and extracellular proteomes from the different experimental groups were compared to determine the variations in the protein abundance in each group. Although there are variations in the amount and identities of the proteins expressed by the strains in the experimental groups, the DEPs are similar and largely exhibit very close biological and molecular functions. Overall, higher amounts of proteins and DEPs were observed from the intracellular proteome than the extracellular proteome. This variation could be because proteins are synthesized intracellularly, and most of the cell’s metabolic activities occur intracellularly [56]. The variations in the protein abundance between and within groups indicate the influence of the different culture conditions and especially the absence of some media components, including some minerals (cobalt (II) chloride, calcium chloride, zinc sulphate, potassium chloride, and copper sulphate), amino acids (L-alanine, L-valine, L-proline, and L-aspartic acid), nucleotide bases (guanine, adenine, xanthine, and nicotinic acid), and vitamins (thiamine hydrochloride, folic acid, p-aminobenzoic acid, and biotin) in the minimal defined medium.
Functional annotation of the differential proteins revealed their roles in several biological and molecular processes. For example, the expression of 50S ribosomal protein that maintains the structure and function of the aminoacyl-tRNA binding site during translation [57] was up-regulated in the co-culture in CDM (CLRLS) compared to the single culture of L. reuteri ZJ625 (CLR). However, the differential expressions of most of the proteins between CLR and CLRLS were insignificant, indicating a less effect of co-culturing on the proteome of L. reuteri ZJ625 in the presence of L. salivarius ZJ614 in CDM. In contrast, comparing the proteins expressed between the co-culture (CLRLS) and CLS (L. salivarius ZJ614) showed higher significantly expressed differential proteins between the two groups. The expression of elongation factor G, a protein involved in accurate protein synthesis under stress conditions [58], was higher in the CLRLS than in CLS. Similarly, some important proteins, such as enolase and phosphoglycerate kinase, necessary for glucose degradation during glycolysis and pyruvate synthesis from D-glyceraldehyde 3-phosphate [58], were highly expressed in CLRLS compared to CLS. The genes that code for these proteins were previously reported as adaptational genes acquired by LAB for survival in nutrient-rich growth medium [59]. These findings indicate the effect of medium components and co-culturing on the intracellular and extracellularly expressed proteome of L. salivarius ZJ614 and L. reuteri ZJ625, denoting possible synergy, additive, and/or inhibitory interactions between the two strains. Interestingly, these results indicate the roles of the differential proteins in converting glucose during glycolysis, pentose phosphate pathway, and pyruvate production by the co-culture. This was evidenced by the high levels of phosphoglycerate kinase and enolase that catalyse the production of phosphoenolpyruvate from 2-phosphoglycerate. However, the expression of L-lactate dehydrogenase that breaks fructose to pyruvate [60] was highly expressed in CLS compared to CLRLS, denoting the ability of L. reuteri ZJ625 to influence the fermentation by L. salivarius ZJ614 in a mixed-culture. Between-group comparison of L. salivarius ZJ614 on MDM and CDM indicates no significant differential proteins signifying the ability of L. salivarius ZJ614 to thrive and maintain metabolic activities despite the absence of some medium components. Also, no significant differential proteins were observed between MLR and MLRLS, similar to what was observed between CLR and CLRLS.
Between groups, comparisons also revealed the high expression of serine t-ligase that binds serine to tRNA in CLR compared to MLR. Enolase, an enzyme that enzymatically converts phosphoglycerate into phosphoenolpyruvate in a reversible reaction, was highly expressed in CLR compared to MLR. However, the ATP synthase subunit-α which synthesises ATP from ADP across the membrane was highly expressed in MLR compared to CLR. Also, a high level of ornithine carbamoyl transferase transfers the carbamoyl group to the N-atom of ornithine during the L-citrulline synthesis [58] was observed in MLR compared to CLR. The significant difference in the proteome of L. reuteri ZJ625, when cultured in different media (either MDM or CDM), indicates the response of the strain to changes in growth media components. Similar to the proteome of L. reuteri ZJ625 in a minimal medium, the co-culture also showed high expression of translocase subunit SecA, which catalyses ATP binding and import across the cell membrane into the cell when compared to CLRLS. Another protein highly expressed in MLRLS compared to CLRLS is GMP synthase, which is involved in glutamine biosynthesis. However, the trigger factor that acts as a chaperone in protein folding and maintaining freshly produced proteins in opened conformation was highly expressed in CLRLS, unlike MLRLS. Comparison of the isolates on the MDM revealed aspartate tRNA ligase, which aids in nucleic acid binding and aspartyl-tRNA aminoacylation. However, no significant DEPs were found between MLR and MLRLS. Even though several differential proteins were observed between CLS and MLS, no significant differences were found in their expression levels.
Quorum sensing is a bacterial cell-to-cell chemical communication in which bacteria respond to population density gradient through the production, detection, and response to extracellular signalling molecules known as autoinducers [61]. Bacteria integrate the information encoded through quorum sensing for within-species, within-genera, and between-species crosstalk, as well as interactions with the gut microbiome [62]. In this study, S-ribosylhomocysteine lyas (luxS) was significantly high in the co-culture from the minimal medium (MDM) compared to the same in the complete defined medium (CDM). This protein synthesises autoinducer-2 (AI-2), used to communicate the cell density and the metabolic potential of the environment between bacteria. It also regulates the transformation of S-ribosylhomocysteine to homocysteine and 4,5-dihydroxy-2,3-pentadione [63]. Autoinducer-2 is associated with probiotics interaction with the microbiome and stimulates the proliferation of Firmicutes during antimicrobial-associated dysbiosis [64]. The high expression of luxS by the strains co-cultured in MDM indicates the mechanisms of intercellular crosstalk between L. salivarius ZJ614 and L. reuteri ZJ625 and the potential ability of the strains to modulate the gut microbiome while check-mating their population density. The presence of several important proteins, such as elongation factor TU, glyceraldehyde-3-phosphate dehydrogenase, and the phosphor-carrier protein (HPr), previously reported to play roles in Lactobacilli attachment to the host epithelium [65], indicates the potential for crosstalk between the isolates in this study during probiotic-host interactions. Glyceraldehyde-3-phosphate dehydrogenase also possesses antigenic and immunomodulatory effects, stimulates B and T-cell activation, and increases IL-10 secretion in the host [66]. However, since this study was conducted in vitro, this conclusion needs to be validated using biological systems (cell/tissue culture, animal model experiment).
The protein-protein interactions (PPI) network analyses for the intracellularly and extracellularly expressed proteomes indicate significantly more interactions than expected. The PPI indicate the involvement of the proteins in cell processes, including transcription/translation, protein transport, and nucleotide metabolism. The PPI further indicates the interactions of the quorum-sensing enzyme luxS with S-adenosylmethionine synthase (metk) and cysteine—tRNA ligase (cysS), which are important enzymes that play roles in methionine and cysteine biosynthesis, respectively. The interactions of luxS with rplS, a protein sub-unit located on the 50S ribosomal protein and with roles in aminoacyl-tRNA binding, further indicate the role of the quorum-sensing enzyme in protein biosynthesis, as previously reported [67, 68].
Another important mechanism by which the living cells expand their chemical structure and information carried by the 20 proteinogenic amino acids is by binding covalent modifications to polypeptide chains. Most of these modifications are linked after synthesising the polypeptide chains (translation) and are termed post-translational modifications (PTMs) [69]. In this study, the post-translational modifications identified are oxidation, deamidation, methylthiolation, ammonia loss, and dehydration (Table 5). These PTMs were observed on proteins associated with different physiological processes, including transcription, amino acid degradation, glucose metabolism, ATP synthesis, and S-ribosylhomocysteine lyase (luxS) (involved in synthesising autoinducer-2). Proteins PTMs affect the chemical structures of the modified residues and closely associated polypeptide regions, influencing the protein conformation, folding, binding abilities, and, importantly, their functions [69]. For instance, thiol-based PTMs on S-ribosylhomocysteine lyase (luxS) and ornithine carbamoyltransferase were previously reported to induce several transcription factors involved in detoxification pathways [70] and redox regulation of cellular metabolism in bacteria [71]. Deamidation and ammonia loss involve the release of ammonia into the surrounding medium and function in the competitive survival strategy for available amino acids by lactic acid bacteria [72]. Bacteria employ post-translational modifications as crucial strategies to survive and adapt to their environment. PTMs control several aspects of protein functions and microbial physiology, such as protein-protein interactions, protein turnover, cell-to-cell crosstalk, and cell differentiation [73].
Conclusion
The study elucidates the interactions and influence of co-culturing between L. reuteri ZJ625 and L. salivarius ZJ614 in defined media through label-free proteomics analysis. Co-culturing of the two strains resulted in the expression of differential proteins with biological, molecular, and enzymatic activities in the defined media. The differentially expressed proteins were associated with post-translational modifications such as deamidation, ammonia loss, oxidation, dehydration, and methylthiolation. Importantly, this study revealed the interactions between L. reuteri ZJ625 and L. salivarius ZJ614 mediated by the secretion of S-ribosylhomocysteine lyase (luxS) useful in an autoinducer-2 synthesis useful in cell-to-cell bacterial crosstalk in co-cultures. The proteome of L. salivarius ZJ614 was most affected when co-cultured with L. reuteri ZJ625. In contrast, the effect of removing medium components from the minimal medium was more evident on L. reuteri ZJ625 than on L. salivarius ZJ614. To fully explore the benefits of multi-strain probiotics for biological applications, ex vivo and in vivo proteomics studies should be carried out. This will grant the understanding of the effects of probiotics in the host and the mechanisms of probiotics-microbiome modulation.
Data Availability
The data from this study will be made available by the corresponding author upon reasonable request.
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Acknowledgements
The authors acknowledge the Gastrointestinal Microbiology and Biotechnology Unit of the Agricultural Research Council, Animal Production Institute Irene, Pretoria, South Africa, for the lab space to conduct this work and the College of Agriculture, Engineering and Sciences for tuition remission granted to IDK for his PhD program.
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Open access funding provided by University of KwaZulu-Natal. This research was funded by the Agricultural Research Council-Animal Production Parliamentary Grant (Cost centre: P02000032), South Africa.
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MAA, OAA, and MO conceived and supervised the work. IDK designed and executed the lab work, analysed the data, and drafted the manuscript. All the authors reviewed and edited the manuscript.
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Kwoji, I.D., Aiyegoro, O.A., Okpeku, M. et al. Elucidating the Mechanisms of Cell-to-Cell Crosstalk in Probiotics Co-culture: A Proteomics Study of Limosilactobacillus reuteri ZJ625 and Ligilactobacillus salivarius ZJ614. Probiotics & Antimicro. Prot. (2023). https://doi.org/10.1007/s12602-023-10133-y
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DOI: https://doi.org/10.1007/s12602-023-10133-y