Synergistic toxic effects of high-strength ammonia and ZnO nanoparticles on biological nitrogen removal systems and role of exogenous C10-HSL regulation.

The inhibitory effects of zinc oxide nanoparticles (ZnO NPs) and impacts of N-acyl-homoserine lactone (AHL)-based quorum sensing (QS) on biological nitrogen removal (BNR) performance have been well-investigated. However, the effects of ammonia nitrogen (NH4+-N) concentrations on NP toxicity and AHL regulation have seldom been addressed yet. This study consulted on the impacts of ZnO NPs on BNR systems when high NH4+-N concentration was available. The synergistic toxic effects of high-strength NH4+-N (200 mg/L) and ZnO NPs resulted in decreased ammonia oxidation rates and dropped the nitrogen removal efficiencies by 17.5% ± 0.2%. The increased extracellular polymeric substances (EPS) production was observed in response to the high NH4+-N and ZnO NP stress, which indicated the defense mechanism against the toxic effects in the BNR systems was stimulated. Furthermore, the regulatory effects of exogenous N-decanoyl-homoserine lactone (C10-HSL)-mediated QS system on NP-stressed BNR systems were revealed to improve the BNR performance under different NH4+-N concentrations. The C10-HSL regulated the intracellular reactive oxygen species levels, denitrification functional enzyme activities, and antioxidant enzyme activities, respectively. This probably synergistically enhanced the defense mechanism against NP toxicity. However, compared to the low NH4+-N concentration of 60 mg/L, the efficacy of C10-HSL was inhibited at high NH4+-N levels of 200 mg/L. The findings provided the significant application potential of QS system for BNR when facing toxic compound shock threats.

Effects of AI-2 quorum sensing related luxS gene on Streptococcus suis formatting monosaccharide metabolism-dependent biofilm.

Biofilm is the primary cause of persistent infections caused by Streptococcus suis (S. suis). Metabolism and AI-2 quorum sensing are intricately linked to S. suis biofilm formation. Although the role of the AI-2 quorum sensing luxS gene in S. suis biofilm has been reported, its specific regulatory mechanism remains unclear. This study explored the differences in biofilm formation and monosaccharide metabolism among the wild type (WT), luxS mutant (ΔluxS) and complement strain (CΔluxS), and Galleria mellonella larvae were used to access the effect of luxS gene deletion on the virulence of S. suis in different monosaccharide medias. The results indicated that deletion of the luxS gene further compromised the monosaccharide metabolism of S. suis, impacting its growth in media with fructose, galactose, rhamnose, and mannose as the sole carbon sources. However, no significant impact was observed in media with glucose and N-acetylglucosamine. This deletion also weakened EPS synthesis, thereby diminishing the biofilm formation capacity of S. suis. Additionally, the downregulation of adhesion gene expression due to luxS gene deletion was found to be independent of the monosaccharide medias of S. suis.

Contribution of the Sensor Histidine Kinases PhcS and VsrA to the Quorum Sensing of Ralstonia pseudosolanacearum Strain OE1-1.

The soilborne Gram-negative phytopathogenic beta-proteobacterium Ralstonia pseudosolanacearum strain OE1-1 produces methyl 3-hydroxymyristate (3-OH MAME) as the quorum sensing (QS) signal by the methyltransferase PhcB and senses the chemical, activating the LysR family transcriptional regulator PhcA, which regulates the QS-dependent genes responsible for QS-dependent phenotypes including virulence. The sensor histidine kinases PhcS and VsrA are reportedly involved in the regulation of QS-dependent genes. To elucidate the function of PhcS and VsrA in the active QS, we generated the phcS-deletion and vsrA-deletion mutants, which exhibited weak changes to their QS-dependent phenotypes including virulence. The phcS and vsrA-deletion mutant (ΔphcS/vsrA) had significant changes in its QS-dependent phenotypes and was nonvirulent, similar to the phcA-deletion mutant. The mutant (PhcS-H230Q) with a substitution of histidine to glutamine at amino acid position 230 in PhcS but not the mutant (VsrA-H256Q) with a substitution of histidine to glutamine at amino acid position 256 in VsrA exhibited significant changes in QS-dependent phenotypes and lost virulence. The transcriptome analysis with RNA-sequencing revealed significant alterations to the expression of QS-dependent genes in the ΔphcS/vsrA and PhcS-H230Q but not VsrA-H256Q, similar to the phcA-deletion mutant. The exogenous 3-OH MAME application led to a significantly enhanced QS-inducible major exopolysaccharide EPS I production of the strain OE1-1 and phcB-deletion mutant but not ΔphcS/vsrA and PhcS-H230Q. Collectively, results of the present genetic study suggested that PhcS contributes to QS along with VsrA and that histidine at amino acid position 230 of PhcS is required for 3-OH MAME sensing, thereby influencing QS-dependent phenotypes including virulence of the strain OE1-1. [Formula: see text] The author(s) have dedicated the work to the public domain under the Creative Commons CC0 "No Rights Reserved" license by waiving all of his or her rights to the work worldwide under copyright law, including all related and neighboring rights, to the extent allowed by law, 2024.

A comparative genomic and phenotypic study of Vibrio cholerae model strains using hybrid sequencing.

Next-generation sequencing methods have become essential for studying bacterial biology and pathogenesis, often depending on high-quality, closed genomes. In this study, we utilized a hybrid sequencing approach to assemble the genome of C6706, a widely used Vibrio cholerae model strain. We present a manually curated annotation of the genome, enhancing user accessibility by linking each coding sequence to its counterpart in N16961, the first sequenced V. cholerae isolate and a commonly used reference genome. Comparative genomic analysis between V. cholerae C6706 and N16961 uncovered multiple genetic differences in genes associated with key biological functions. To determine whether these genetic variations result in phenotypic differences, we compared several phenotypes relevant to V. cholerae pathogenicity like genetic stability, acid sensitivity, biofilm formation and motility. Notably, V. cholerae N16961 exhibited greater motility and reduced biofilm formation compared to V. cholerae C6706. These phenotypic differences appear to be mediated by variations in quorum sensing and cyclic di-GMP signalling pathways between the strains. This study provides valuable insights into the regulation of biofilm formation and motility in V. cholerae.

Use of Rgg quorum-sensing machinery to create an innovative recombinant protein expression system in Streptococcus thermophilus.

Streptococcus thermophilus holds promise as a chassis for producing and secreting heterologous proteins. Used for thousands of years to ferment milk, this species has generally recognized as safe (GRAS) status in the USA and qualified presumption of safety (QPS) status in Europe. In addition, it can be easily genetically modified thanks to its natural competence, and it secretes very few endogenous proteins, which means less downstream processing is needed to purify target proteins, reducing costs. Extracellular degradation of heterologous proteins can be eliminated by introducing mutations that inactivate the genes encoding the bacterium's three major surface proteases. Here, we constructed an inducible expression system that utilizes a peptide pheromone (SHP1358) and a transcriptional regulator (Rgg1358) involved in quorum-sensing regulation. We explored the functionality of a complete version of the system, in which the inducer is produced by the bacterium itself, by synthesizing a luciferase reporter protein. This complete version was assessed with bacteria grown in a chemically defined medium but also in vivo, in the faeces of germ-free mice. We also tested an incomplete version, in which the inducer had to be added to the culture medium, by synthesizing luciferase and a secreted form of elafin, a human protein with therapeutic properties. Our results show that, in our system, protein production can be modulated by employing different concentrations of the SHP1358 inducer or other SHPs with closed amino acid sequences. We also constructed a genetic background in which all system leakiness was eliminated. In conclusion, with this new inducible expression system, we have added to the set of tools currently used to produce secreted proteins in S. thermophilus, whose myriad applications include the delivery of therapeutic peptides or proteins.

[Advances in microbial whole-cell sensors for the detection of aromatic compounds].

The inherent stability and recalcitrance of benzene ring structures render aromatic compounds a major ecological concern and a substantial risk to human health. Hence, developing a facile and efficacious detection technique for aromatic compounds is essential. As our comprehension of aromatic compound characteristics deepens, microbial cell-based biosensors have emerged as increasingly popular tools in the detection of aromatic compounds. This article introduces the operational principles of microbial whole-cell biosensors and elucidates the construction techniques and applications of electroactive biofilm-based microbial whole-cell sensors, transcription factor-based microbial whole-cell sensors, and degradation gene promoter-dependent microbial whole-cell sensors in the detection of aromatic compounds. In addition, we review the methodologies for improving the performance of microbial whole-cell sensors based on surface display, logic gate construction, genetic circuit modification, and quorum sensing signal amplification.

Impact of AbaI mutation on virulence, biofilm development, and antibiotic susceptibility in Acinetobacter baumannii.

The quorum sensing (QS) system mediated by the abaI gene in Acinetobacter baumannii is crucial for various physiological and pathogenic processes. In this study, we constructed a stable markerless abaI knockout mutant (ΔabaI) strain using a pEXKm5-based allele replacement method to investigate the impact of abaI on A. baumannii. Proteomic analysis revealed significant alterations in protein expression between the wild type (WT) and ΔabaI mutant strains, particularly in proteins associated with membrane structure, antibiotic resistance, and virulence. Notably, the downregulation of key outer membrane proteins such as SurA, OmpA, OmpW, and BamA suggests potential vulnerabilities in outer membrane integrity, which correlate with structural abnormalities in the ΔabaI mutant strain, including irregular cell shapes and compromised membrane integrity, observed by scanning and transmission electron microscopy. Furthermore, diminished expression of regulatory proteins such as OmpR and GacA-GacS highlights the broader regulatory networks affected by abaI deletion. Functional assays revealed impaired biofilm formation and surface-associated motility in the mutant strain, indicative of altered colonization capabilities. Interestingly, the mutant showed a complex antibiotic susceptibility profile. While it demonstrated increased susceptibility to membrane-targeting antibiotics, its response to beta-lactams was more nuanced. Despite increased expression of metallo-beta-lactamase (MBL) superfamily proteins and DcaP-like protein, the mutant unexpectedly showed lower MICs for carbapenems (imipenem and meropenem) compared to the wild-type strain. This suggests that abaI deletion affects antibiotic susceptibility through multiple, potentially competing mechanisms. Further investigation is needed to fully elucidate the interplay between quorum sensing, antibiotic resistance genes, and overall antibiotic susceptibility in A. baumannii. Our findings underscore the multifaceted role of the abaI gene in modulating various cellular processes and highlight its significance in A. baumannii physiology, pathogenesis, and antibiotic resistance. Targeting the abaI QS system may offer novel therapeutic strategies for this clinically significant pathogen.

Reducing tetracycline resistance genes in wheat soil using natural quorum sensing inhibitors: A new approach for mitigating antibiotic resistance gene contamination.

The distribution and transmission of antibiotic resistance genes (ARGs) in agricultural soils constitute a significant threat to food safety and human health. Natural quorum sensing inhibitors (QSIs), with advantages such as low plant toxicity and low application costs, present a potential approach for mitigating ARG contamination by targeting bacterial quorum sensing systems. This study explored the impacts and mechanisms of three natural QSIs (vanillin, catechin, and tannin) on the abundance of tetracycline resistance genes (TRGs) in both rhizosphere and non-rhizosphere soils. Results illustrated a notable reduction in TRG abundance across three natural QSI treatments, with catechin displaying the most pronounced effect in the rhizosphere soil. Furthermore, the application of natural QSIs had a significant influence on the bacterial community structure and population dynamics, particularly evident in the alterations induced by catechin on bacterial interactions within the soil ecosystem. Natural QSIs inhibited the production of N-acyl homoserine lactone (AHL) signaling molecules. The primary environmental factors driving changes in bacterial community were identified as pH and NO3--N content. Through mechanisms involving the modulations of AHL concentrations and soil environmental factors, natural QSIs were found to impact bacterial population, ultimately leading to a decrease in TRG abundance. Importantly, the application of natural QSIs did not exhibit adverse effects on plant phenotypic traits. These findings serve as a useful reference for implementing natural QSIs to effectively control soil ARG contamination.

Pseudomonas aeruginosa Mediates Host Necroptosis through Rhl-Pqs Quorum Sensing Interaction.

Pseudomonas aeruginosa (P. aeruginosa) is an opportunistic pathogen that can cause serious infections in immunocompromised patients. Quorum sensing (QS), a communication system evolved by P. aeruginosa to survey its density, is well acknowledged to be involved in various activities during bacterial infection. Recent studies have revealed the link between P. aeruginosa QS and host innate immune response. Previous evidence suggests that programmed cell death exists in response to P. aeruginosa infection. However, it remains unclear whether QS plays a role in the host programmed cell death process during the infection. In this study, we found that the deficiency of one of QS subsystems, rhl, markedly increased mouse bone marrow macrophage cell death induced by P. aeruginosa, which was accompanied by elevated phosphorylation of RIPK3 and MLKL. This highly increased necroptosis activation was caused by the upregulation of another QS subsystem, pqs, because the deletion of pqs in rhl-deficient P. aeruginosa abolished macrophage necroptosis in vitro and in vivo. In sum, our data highlight the cross-talk between P. aeruginosa QS and host necroptosis, which is executed through the rhl-pqs axis.

Identification of critical amino acids in the DNA binding domain of LuxO: Lessons from a constitutive active LuxO.

Quorum sensing plays a vital role in the environmental and host life cycles of Vibrio cholerae. The quorum-sensing circuit involves the consorted action of autoinducers, small RNAs, and regulatory proteins to control a plethora of physiological events in this bacterium. Among the regulatory proteins, LuxO is considered a low-cell-density master regulator. It is a homolog of NtrC, a two-component response regulator. NtrC belongs to an evolving protein family that works with the alternative sigma factor σ54 to trigger gene transcription. Structurally, these proteins comprise 3 domains: a receiver domain, a central AAA+ATPase domain, and a C-terminal DNA-binding domain (DBD). LuxO communicates with its cognate promoters by employing its DNA binding domain. In the present study, we desired to identify the critical residues in the DBD of LuxO. Our combined mutagenesis and biochemical assays resulted in the identification of eleven residues that contribute significantly to LuxO regulatory function.

Cyclic AMP is a global virulence regulator governing inter and intrabacterial signalling in Acinetobacter baumannii.

Acinetobacter baumannii is an opportunistic nosocomial pathogen with high morbidity and mortality rates. Current treatment options for this pathogen are limited due to its increasing resistance to last-resort antibiotics. Despite A. baumannii's leading position in the World Health Organisations priority pathogens list, little is known about its virulence regulation. Through a high-throughput screening approach to identify novel biofilm regulators, we identified a previously uncharacterised predicted adenylate cyclase (AC), CavA, as a central regulator of this phenotype. cAMP is a crucial mediator of various aspects of bacterial physiology in other species but information about its role in A. baumannii is limited. We confirm that CavA AC is functional and synthesizes cAMP in A. baumannii. Using dRNA-seq, we verify that CavA is a negative biofilm formation regulator affecting Csu pili and exopolysaccharide production. We demonstrate for the first time that in A. baumannii, cAMP is atop of a hierarchical signalling cascade controlling inter- and intrabacterial signalling by modulating quorum sensing and cyclic di-GMP systems, ultimately governing virulence in vivo and adaptive antibiotic resistance. In contrast to the well-established paradigm in other bacteria where cAMP and cyclic di-GMP levels are inversely regulated, we uncover that the levels of these second messengers are directly proportional in A. baumannii. Overall, this study uncovers the central role of CavA and cAMP in the pathogenic success of A. baumannii and highlights this signalling cascade as a high potential target for novel therapeutic development.

The activity of the quorum sensing regulator HapR is modulated by the bacterial extracellular vesicle (BEV)-associated protein ObfA of Vibrio cholerae.

Vibrio cholerae, a facultative human pathogen and causative agent of the severe diarrheal disease cholera, transits between the human intestinal tract and aquatic reservoirs. Like other bacterial species, V. cholerae continuously releases bacterial extracellular vesicles (BEVs) from its surface, which have been recently characterised for their role during in vivo colonisation. However, between epidemic outbreaks, V. cholerae persists in the biofilm mode for extended periods in aquatic reservoirs, which enhances environmental fitness and host transition. In this study, we investigated the effect of V. cholerae BEVs on biofilm formation, a critical feature for ex vivo survival. In contrast to BEVs from planktonic cultures, our results show that physiological concentrations of BEVs from dynamic biofilm cultures facilitate V. cholerae biofilm formation, which could be linked to a proteinaceous factor. Comparative proteomic analyses of planktonic- and biofilm-derived BEVs identified a previously uncharacterised outer membrane protein as an abundant component of dynamic biofilm-derived BEVs, which was found to be responsible for the BEV-dependent enhancement of biofilm production. Consequently, this protein was named outer membrane-associated biofilm facilitating protein A (ObfA). Comprehensive molecular studies unravelled ObfA as a negative modulator of HapR activity. HapR is a key transcriptional regulator of the V. cholerae quorum sensing (QS) cascade acting as a potent repressor of biofilm formation and virulence. Consistently, obfA mutants not only exhibited reduced biofilm production but also reduced colonisation fitness. Surprisingly, our results demonstrate that ObfA does not affect HapR through the canonical QS system but via the Csr-cascade altering the expression of the small regulatory RNAs CsrC and CsrD. In summary, this study elucidates a novel intraspecies BEV-based communication in V. cholerae that influences biofilm formation and colonisation fitness via a new regulatory pathway involving HapR, Csr-cascade and the BEV-associated protein ObfA.

Soy protein hydrolysates induce menaquinone-7 biosynthesis by enhancing the biofilm formation of Bacillus subtilis natto.

Menaquinone-7 (MK-7) is a form of vitamin K2 with health-beneficial effects. A novel fermentation strategy based on combining soy protein hydrolysates (SPHs) with biofilm-based fermentation was investigated to enhance menaquinone-7 (MK-7) biosynthesis by Bacillus subtilis natto. Results showed the SPHs increased MK-7 yield by 199.4% in two-stage aeration fermentation as compared to the SP-based medium in submerged fermentation, which was related to the formation of robust biofilm with wrinkles and the enhancement of cell viability. Moreover, there was a significant correlation between key genes related to MK-7 and biofilm synthesis, and the quorum sensing (QS) related genes, Spo0A and SinR, were downregulated by 0.64-fold and 0.39-fold respectively, which promoted biofilm matrix synthesis. Meanwhile, SPHs also enhanced the MK-7 precursor, isoprene side chain, supply, and MK-7 assembly efficiency. Improved fermentation performances of bacterial cells during fermentation were attributed to abundant oligopeptides (Mw < 1 kDa) and moderate amino acids, particularly Arg, Asp, and Phe in SPHs. All these results revealed that SPHs were a potential and superior nitrogen source for MK-7 production by Bacillus subtilis natto.

Erythromycin disrupts Acinetobacter baumannii biofilms through destruction of the quorum sensing system.

BACKGROUND: This study was conducted to explore the effects of erythromycin on biofilms comprising Acinetobacter baumannii (A baumannii). METHODS: To clarify the effect of erythromycin on the biofilms of A baumannii, we collected pure Ab strains isolated and identified from a variety of sample types extracted from patients in the microbiological laboratory of our hospital from April to August 2023, and divided them into an experimental group (treated with erythromycin) and a control group (without erythromycin). The morphology and quantity of A baumannii biofilm were observed at 24h, 48h, 72h, and 5d post-treatment, respectively, and the expression of quorum sensing (QS) system gene (abaI, abaR) mRNA was detected by fluorescence quantitative PCR. RESULTS: The results showed that A baumanniis are prone to form multiple drug-resistant (MDR) bacteria, against which the most commonly used clinical antibiotics are ineffective. Overall, we found that the number of bacteria, the number of bacteria in the biofilm, and the number of biofilms formed gradually increased over time, with a statistical difference (P < .05). After the addition of erythromycin, significant improvements in biofilm formation were achieved, indicating that erythromycin can destroy A baumannii biofilms, inhibiting bacterial growth to a certain extent. The expression levels of abaI and abaR gradually increased over time, indicating that the role of the QS system became more apparent over time. Biofilm formation is related to the QS system of A baumanniis. After erythromycin treatment, abaI and abaR mRNA expression was downregulated in the experimental group. CONCLUSION: Erythromycin disrupts A baumannii biofilms by destroying the quorum sensing system.

Exploring Fatty Acid ß-Oxidation Pathways in Bacteria: From General Mechanisms to DSF Signaling and Pathogenicity in Xanthomonas.

Fatty acids (FAs) participate in extensive physiological activities such as energy metabolism, transcriptional control, and cell signaling. In bacteria, FAs are degraded and utilized through various metabolic pathways, including ß-oxidation. Over the past ten years, significant progress has been made in studying FA oxidation in bacteria, particularly in E. coli, where the processes and roles of FA ß-oxidation have been comprehensively elucidated. Here, we provide an update on the new research achievements in FAs ß-oxidation in bacteria. Using Xanthomonas as an example, we introduce the oxidation process and regulation mechanism of the DSF-family quorum sensing signal. Based on current findings, we propose the specific enzymes required for ß-oxidation of several specific FAs. Finally, we discuss the future outlook on scientific issues that remain to be addressed. This paper supplies theoretical guidance for further study of the FA ß-oxidation pathway with particular emphasis on its connection to the pathogenicity mechanisms of bacteria.

Structure-Based Discovery of Symmetric Disulfides from Garlic Extract as Pseudomonas aeruginosa Quorum Sensing Inhibitors.

Microorganisms are the most common cause of food spoilage. Pseudomonas aeruginosa is a common foodborne pathogen that causes food spoilage and poses a serious threat to food safety. As a crucial target in antitoxicity strategies, the quorum sensing (QS) system shows promising potential for further development. The garlic extract diallyl disulfide exhibits inhibitory activity against the QS system of P. aeruginosa, with disulfide bonds serving as the active component. However, the biological activity of other symmetric disulfides has not been investigated in this capacity. The study synthesized 39 disulfide bond-containing analogs and evaluated their activity as quorum sensing inhibitors (QSIs). The results showed that p-hydroxyphenyl substitution can replace the allyl groups while maintaining strong biological activity. The virulence factors production was reduced by compound 2i, with the strongest inhibitory effect being observed on elastase production. Synergistic inhibition was observed in the presence of antibiotics like ciprofloxacin and tobramycin. 2i successfully inhibited P. aeruginosa infection in the Galleria mellonella larvae model. Primary mechanism studies using transcriptome, surface plasmon resonance and molecular docking suggested that 2i inhibits the QS system by targeting the LasR protein. Thus, compound 2i could be used in developing QSIs for the control of P. aeruginosa infections.

The bacterial quorum sensing signal 2'-aminoacetophenone rewires immune cell bioenergetics through the Ppargc1a/Esrra axis to mediate tolerance to infection.

How bacterial pathogens exploit host metabolism to promote immune tolerance and persist in infected hosts remains elusive. To achieve this, we show that Pseudomonas aeruginosa (PA), a recalcitrant pathogen, utilizes the quorum sensing (QS) signal 2'-aminoacetophenone (2-AA). Here, we unveil how 2-AA-driven immune tolerization causes distinct metabolic perturbations in murine macrophages' mitochondrial respiration and bioenergetics. We present evidence indicating that these effects stem from decreased pyruvate transport into mitochondria. This reduction is attributed to decreased expression of the mitochondrial pyruvate carrier (Mpc1), which is mediated by diminished expression and nuclear presence of its transcriptional regulator, estrogen-related nuclear receptor alpha (Esrra). Consequently, Esrra exhibits weakened binding to the Mpc1 promoter. This outcome arises from the impaired interaction between Esrra and the peroxisome proliferator-activated receptor gamma coactivator 1-alpha (Ppargc1a). Ultimately, this cascade results in diminished pyruvate influx into mitochondria and, consequently reduced ATP production in tolerized murine and human macrophages. Exogenously added ATP in infected macrophages restores the transcript levels of Mpc1 and Esrra and enhances cytokine production and intracellular bacterial clearance. Consistent with the in vitro findings, murine infection studies corroborate the 2-AA-mediated long-lasting decrease in ATP and acetyl-CoA and its association with PA persistence, further supporting this QS signaling molecule as the culprit of the host bioenergetic alterations and PA persistence. These findings unveil 2-AA as a modulator of cellular immunometabolism and reveal an unprecedented mechanism of host tolerance to infection involving the Ppargc1a/Esrra axis in its influence on Mpc1/OXPHOS-dependent energy production and PA clearance. These paradigmatic findings pave the way for developing treatments to bolster host resilience to pathogen-induced damage. Given that QS is a common characteristic of prokaryotes, it is likely that 2-AA-like molecules with similar functions may be present in other pathogens.

Delaying production with prokaryotic inducible expression systems.

BACKGROUND: Engineering bacteria with the purpose of optimizing the production of interesting molecules often leads to a decrease in growth due to metabolic burden or toxicity. By delaying the production in time, these negative effects on the growth can be avoided in a process called a two-stage fermentation. MAIN TEXT: During this two-stage fermentation process, the production stage is only activated once sufficient cell mass is obtained. Besides the possibility of using external triggers, such as chemical molecules or changing fermentation parameters to induce the production stage, there is a renewed interest towards autoinducible systems. These systems, such as quorum sensing, do not require the extra interference with the fermentation broth to start the induction. In this review, we discuss the different possibilities of both external and autoinduction methods to obtain a two-stage fermentation. Additionally, an overview is given of the tuning methods that can be applied to optimize the induction process. Finally, future challenges and prospects of (auto)inducible expression systems are discussed. CONCLUSION: There are numerous methods to obtain a two-stage fermentation process each with their own advantages and disadvantages. Even though chemically inducible expression systems are well-established, an increasing interest is going towards autoinducible expression systems, such as quorum sensing. Although these newer techniques cannot rely on the decades of characterization and applications as is the case for chemically inducible promoters, their advantages might lead to a shift in future inducible expression systems.

Actinomycin D reduces virulence factors and biofilms against Aeromonas hydrophila.

AIMS: Aeromonas hydrophila, a Gram-negative bacterium, is ubiquitously found in many aquatic habitats, causing septicemia in humans and fishes. Attributed to abuse or misuse of conventional antimicrobial drug usage, antimicrobial resistance is at an alarming rise. There is an available alternative strategy to bacterial resistance to antimicrobials, which is inhibition of virulence and pathogenicity employing quorum sensing inhibitors (QSIs). Hence, actinomycin D's effectiveness against A. hydrophila SHAe 115 as a QSI was investigated in decreasing virulence factors and preventing biofilm formation. METHODS AND RESULTS: Actinomycin D, belongs to the QSI combating Pseudomonas aeruginosa PAO1 originally isolated from an entophytic actinomycete (Streptomyces cyaneochromogenes RC1) in Areca catechu L. In the present work, further investigations were carried out to assess the effect of actinomycin D at subminimal inhibitory concentrations (sub-MICs), QS-regulated virulence factors, and biofilm inhibition strategies. Intrinsic properties encompassing inhibition of the production of protease and hemolysin and subsequent activities on biofilm formation and eradication of mature biofilm were established along with weakened swimming and swarming motilities in A. hydrophila SHAe 115. In the Tenebrio molitor survival assay, actinomycin D effectively reduced the virulence and pathogenicity of A. hydrophila, resulting in elimination of mortality. However, the hydrolysate of actinomycin D, 2-hydroxy-4,6-dimethyl-3-oxo-3H-phenoxazine-1,9-dicarboxylic acid (HDPD), had lost the QSI activity in A. hydrophila. CONCLUSIONS: Actinomycin D was proved as a viable QSI in lessening A. hydrophila's the virulence and pathogenicity, as evident from our research findings.

Regulation of gene transcription in Escherichia coli O157:H7 in response to a natural derivate peptide of esculentin-1a used in combination with essential oils from plants of the Cymbopogon genus.

INTRODUCTION: We analyzed the expression of several genes implicated in the pathogenicity of Escherichia coli O157:H7, treating bacteria with Esc(1-21), a derivative of peptide esculentin-1 in combination with three essential oils obtained from plants from the Cympopogon genus. METHODS: We used the checkerboard assay to determine the antimicrobial activity of the combinations. We analyzed the expression of some genes implicated in the pathogenicity and quorum sensing system of E. coli O157:H7 by real-time RT-PCR technique. RESULTS: Treatment of the bacteria with the peptide combined with oils had an efficacious antimicrobial activity. The analysis of gene expression showed that all used combinations regulate positively the espAD and ler genes, located in the pathogenicity island, named the locus of enterocyte effacement. None of the combinations affects the quorum sensing genes: lsrABCFKR and qseBC. CONCLUSIONS: This study demonstrates that the use of essential oil/peptide combinations can be effective in fighting microbial infections.