Improving the food safety of bakery products by simultaneously monitoring the occurrence of pyrrolizidine, tropane and opium alkaloids.

The exponential number of food alerts about concerning levels of some plant-alkaloids, such as pyrrolizidine, tropane and opium alkaloids, have stressed the need to monitor their occurrence in foods to avoid toxic health effects derived from their intake. Therefore, analytical strategies to simultaneously monitor the occurrence of these alkaloids should be developed to ensure food safety an comply with regulations. Accordingly, this work proposes an efficient multicomponent analytical strategy for the simultaneous extraction of these alkaloids from commercial bakery products. The analytical method was validated and applied to the analysis of 15 samples, revealing that 100% of them contained at least one of the target alkaloids, in some cases exceeding the maximum limits legislated. Moreover, in two samples the 3 different alkaloid families were detected. These results confirm the importance of simultaneously monitoring these alkaloids in food and highlight also considering some opium alkaloids in current legislation.

Bdellovibrio's prey-independent lifestyle is fueled by amino acids as a carbon source.

Identifying the nutritional requirements and growth conditions of microorganisms is crucial for determining their applicability in industry and understanding their role in clinical ecology. Predatory bacteria such as Bdellovibrio bacteriovorus have emerged as promising tools for combating infections by human bacterial pathogens due to their natural killing features. Bdellovibrio's lifecycle occurs inside prey cells, using the cytoplasm as a source of nutrients and energy. However, this lifecycle supposes a challenge when determining the specific uptake of metabolites from the prey to complete the growth inside cells, a process that has not been completely elucidated. Here, following a model-based approach, we illuminate the ability of B. bacteriovorus to replicate DNA, increase biomass, and generate adenosine triphosphate (ATP) in an amino acid-based rich media in the absence of prey, keeping intact its predatory capacity. In this culture, we determined the main carbon sources used and their preference, being glutamate, serine, aspartate, isoleucine, and threonine. This study offers new insights into the role of predatory bacteria in natural environments and establishes the basis for developing new Bdellovibrio applications using appropriate metabolic and physiological methodologies. KEY POINTS: • Amino acids support axenic lifestyle of Bdellovibrio bacteriovorus. • B. bacteriovorus preserves its predatory ability when growing in the absence of prey.

The Tradeoffs Between Persistence and Mutation Rates at Sub-Inhibitory Antibiotic Concentrations in Staphylococcus aureus.

The rational design of the antibiotic treatment of bacterial infections employs these drugs to reach concentrations that exceed the minimum needed to prevent the replication of the target bacteria. However, within a treated patient, spatial and physiological heterogeneity promotes antibiotic gradients such that the concentration of antibiotics at specific sites is below the minimum needed to inhibit bacterial growth. Here, we investigate the effects of sub-inhibitory antibiotic concentrations on three parameters central to bacterial infection and the success of antibiotic treatment, using in vitro experiments with Staphylococcus aureus and mathematical-computer simulation models. Our results, using drugs of six different classes, demonstrate that exposure to sub-inhibitory antibiotic concentrations not only alters the dynamics of bacterial growth but also increases the mutation rate to antibiotic resistance and decreases the rate of production of persister cells thereby reducing the persistence level. Understanding this trade-off between mutation rates and persistence levels resulting from sub-inhibitory antibiotic exposure is crucial for optimizing, and mitigating the failure of, antibiotic therapy.

Theoretical considerations and empirical predictions of the pharmaco- and population dynamics of heteroresistance.

Antibiotics are considered one of the most important contributions to clinical medicine in the last century. Due to the use and overuse of these drugs, there have been increasing frequencies of infections with resistant pathogens. One form of resistance, heteroresistance, is particularly problematic; pathogens appear sensitive to a drug by common susceptibility tests. However, upon exposure to the antibiotic, resistance rapidly ascends, and treatment fails. To quantitatively explore the processes contributing to the emergence and ascent of resistance during treatment and the waning of resistance following cessation of treatment, we develop two distinct mathematical and computer-simulation models of heteroresistance. In our analysis of the properties of these models, we consider the factors that determine the response to antibiotic-mediated selection. In one model, heteroresistance is progressive, with each resistant state sequentially generating a higher resistance level. In the other model, heteroresistance is non-progressive, with a susceptible population directly generating populations with different resistance levels. The conditions where resistance will ascend in the progressive model are narrower than those of the non-progressive model. The rates of reversion from the resistant to the sensitive states are critically dependent on the transition rates and the fitness cost of resistance. Our results demonstrate that the standard test used to identify heteroresistance is insufficient. The predictions of our models are consistent with empirical results. Our results demand a reevaluation of the definition and criteria employed to identify heteroresistance. We recommend that the definition of heteroresistance should include a consideration of the rate of return to susceptibility.

The ICU environment contributes to the endemicity of the "Serratia marcescens complex" in the hospital setting.

Serratia marcescens is an opportunistic pathogen historically associated with sudden outbreaks in intensive care units (ICUs) and the spread of carbapenem-resistant genes. However, the ecology of S. marcescens populations in the hospital ecosystem remains largely unknown. We combined epidemiological information of 1,432 Serratia spp. isolates collected from sinks of a large ICU that underwent demographic and operational changes (2019-2021) and 99 non-redundant outbreak/non-outbreak isolates from the same hospital (2003-2019) with 165 genomic data. These genomes were grouped into clades (1-4) and subclades (A and B) associated with distinct species: Serratia nematodiphila (1A), S. marcescens (1B), Serratia bockelmannii (2A), Serratia ureilytica (2B), S. marcescens/Serratia nevei (3), and S. nevei (4A and 4B). They may be classified into an S. marcescens complex (SMC) due to the similarity between/within subclades (average nucleotide identity >95%-98%), with clades 3 and 4 predominating in our study and publicly available databases. Chromosomal AmpC ß-lactamase with unusual basal-like expression and prodigiosin-lacking species contrasted classical features of Serratia. We found persistent and coexisting clones in sinks of subclades 4A (ST92 and ST490) and 4B (ST424), clonally related to outbreak isolates carrying blaVIM-1 or blaOXA-48 on prevalent IncL/pB77-CPsm plasmids from our hospital since 2017. The distribution of SMC populations in ICU sinks and patients reflects how Serratia species acquire, maintain, and enable plasmid evolution in both "source" (permanent, sinks) and "sink" (transient, patients) hospital patches. The results contribute to understanding how water sinks serve as reservoirs of Enterobacterales clones and plasmids that enable the persistence of carbapenemase genes in healthcare settings, potentially leading to outbreaks and/or hospital-acquired infections.IMPORTANCEThe "hospital environment," including sinks and surfaces, is increasingly recognized as a reservoir for bacterial species, clones, and plasmids of high epidemiological concern. Available studies on Serratia epidemiology have focused mainly on outbreaks of multidrug-resistant species, overlooking local longitudinal analyses necessary for understanding the dynamics of opportunistic pathogens and antibiotic-resistant genes within the hospital setting. This long-term genomic comparative analysis of Serratia isolated from the ICU environment with isolates causing nosocomial infections and/or outbreaks within the same hospital revealed the coexistence and persistence of Serratia populations in water reservoirs. Moreover, predominant sink strains may acquire highly conserved and widely distributed plasmids carrying carbapenemase genes, such as the prevalent IncL-pB77-CPsm (pOXA48), persisting in ICU sinks for years. The work highlights the relevance of ICU environmental reservoirs in the endemicity of certain opportunistic pathogens and resistance mechanisms mainly confined to hospitals.

The pearl jubilee of microcin J25: thirty years of research on an exceptional lasso peptide.

Covering: 1992 up to 2023Since their discovery, lasso peptides went from peculiarities to be recognized as a major family of ribosomally synthesized and post-translationally modified peptide (RiPP) natural products that were shown to be spread throughout the bacterial kingdom. Microcin J25 was first described in 1992, making it one of the earliest known lasso peptides. No other lasso peptide has since then been studied to such an extent as microcin J25, yet, previous review articles merely skimmed over all the research done on this exceptional lasso peptide. Therefore, to commemorate the 30th anniversary of its first report, we give a comprehensive overview of all literature related to microcin J25. This review article spans the early work towards the discovery of microcin J25, its biosynthetic gene cluster, and the elucidation of its three-dimensional, threaded lasso structure. Furthermore, the current knowledge about the biosynthesis of microcin J25 and lasso peptides in general is summarized and a detailed overview is given on the biological activities associated with microcin J25, including means of self-immunity, uptake into target bacteria, inhibition of the Gram-negative RNA polymerase, and the effects of microcin J25 on mitochondria. The in vitro and in vivo models used to study the potential utility of microcin J25 in a (veterinary) medicine context are discussed and the efforts that went into employing the microcin J25 scaffold in bioengineering contexts are summed up.

Membrane computing simulation of sexually transmitted bacterial infections in hotspots of individuals with various risk behaviors.

The epidemiology of sexually transmitted infections (STIs) is complex due to the coexistence of various pathogens, the variety of transmission modes derived from sexual orientations and behaviors at different ages and genders, and sexual contact hotspots resulting in network transmission. There is also a growing proportion of recreational drug users engaged in high-risk sexual activities, as well as pharmacological self-protection routines fostering non-condom practices. The frequency of asymptomatic patients makes it difficult to develop a comprehensive approach to STI epidemiology. Modeling approaches are required to deal with such complexity. Membrane computing is a natural computing methodology for the virtual reproduction of epidemics under the influence of deterministic and stochastic events with an unprecedented level of granularity. The application of the LOIMOS program to STI epidemiology illustrates the possibility of using it to shape appropriate interventions. Under the conditions of our basic landscape, including sexual hotspots of individuals with various risk behaviors, an increase in condom use reduces STIs in a larger proportion of heterosexuals than in same-gender sexual contacts and is much more efficient for reducing Neisseria gonorrhoeae than Chlamydia and lymphogranuloma venereum infections. Amelioration from diagnostic STI screening could be instrumental in reducing N. gonorrhoeae infections, particularly in men having sex with men (MSM), and Chlamydia trachomatis infections in the heterosexual population; however, screening was less effective in decreasing lymphogranuloma venereum infections in MSM. The influence of STI epidemiology of sexual contacts between different age groups (<35 and ≥35 years) and in bisexual populations was also submitted for simulation.IMPORTANCEThe epidemiology of sexually transmitted infections (STIs) is complex and significantly influences sexual and reproductive health worldwide. Gender, age, sexual orientation, sexual behavior (including recreational drug use and physical and pharmacological protection practices), the structure of sexual contact networks, and the limited application or efficiency of diagnostic screening procedures create variable landscapes in different countries. Modeling techniques are required to deal with such complexity. We propose the use of a simulation technology based on membrane computing, mimicking in silico STI epidemics under various local conditions with an unprecedented level of detail. This approach allows us to evaluate the relative weight of the various epidemic drivers in various populations at risk and the possible outcomes of interventions in particular epidemiological landscapes.

Boosting Fitness Costs Associated with Antibiotic Resistance in the Gut: On the Way to Biorestoration of Susceptible Populations.

The acquisition and expression of antibiotic resistance implies changes in bacterial cell physiology, imposing fitness costs. Many human opportunistic pathogenic bacteria, such as those causing urinary tract or bloodstream infections, colonize the gut. In this opinionated review, we will examine the various types of stress that these bacteria might suffer during their intestinal stay. These stresses, and their compensatory responses, probably have a fitness cost, which might be additive to the cost of expressing antibiotic resistance. Such an effect could result in a disadvantage relative to antibiotic susceptible populations that might replace the resistant ones. The opinion proposed in this paper is that the effect of these combinations of fitness costs should be tested in antibiotic resistant bacteria with susceptible ones as controls. This testing might provide opportunities to increase the bacterial gut stress boosting physiological biomolecules or using dietary interventions. This approach to reduce the burden of antibiotic-resistant populations certainly must be answered empirically. In the end, the battle against antibiotic resistance should be won by antibiotic-susceptible organisms. Let us help them prevail.

Bacteriostatic cells instead of bacteriostatic antibiotics?

This year we commemorate the centennial of the birth of the mature concept of bacteriostasis by John W. Churchman at Cornell University Medical School. The term bacteriostasis has primarily been applied to antibiotics (bacteriostatic antibiotics). In this Opinion paper, we are revisiting this concept by suggesting that bacteriostasis essentially reflects a distinct cellular status (or "cell variant") characterized by the inability to be killed as a consequence of an antibiotic-induced stress impacting on bacterial physiology/metabolism (growth). Note that the term "bacteriostasis" should not be associated only with antimicrobials but with many stressful conditions. In that respect, the drug promotion of bacteriostasis might resemble other types of stress-induced cellular differentiation, such as sporulation, in which spores can be considered "bacteriostatic cells" or perhaps as persister bacteria, which can become "normal cells" again when the stressful conditions have abated.IMPORTANCEThis year we commemorate the centennial of the birth of the mature concept of bacteriostasis by John W. Churchman at Cornell University Medical School. The term bacteriostasis has primarily been applied to antibiotics (bacteriostatic antibiotics). In this Opinion paper, we are revisiting this concept by suggesting that some antibiotics are drugs that induce bacteria to become bacteriostatic. Cells that are unable to multiply, thereby preventing the antibiotic from exerting major lethal effects on them, are a variant ("different") type of cells, bacteriostatic cells. Note that the term "bacteriostasis" should not be associated only with antimicrobials but with many stressful conditions. In that respect, the drug promotion of bacteriostasis might resemble other types of stress-induced cellular differentiation, such as sporulation, in which spores can be considered "bacteriostatic cells" or perhaps as persister bacteria, which can become "normal cells" again when the stressful conditions have abated.

Detección de genes de virulencia en cepas de Enterococcus faecalis susceptibles y resistentes a aminoglucósidos / Detection of virulence genes in aminoglycoside susceptible and resistant Enterococcus faecalis

Background: Enterococcus spp. is an important cause of nosocomial infections A number of virulence factors that may enhance its ability to colonize have been described. Enterococcus is capable of acquiring resistance genes, including high-level resistance (HLR) to aminoglycoside antibiotics. Aim: to investigate the prevalence of genes encoding virulence factors in aminoglycosides susceptible and resistant E. faecalis. Materials and Methods: A total of 80 E. faecalis isolates from clinical (n: 52) and poultry samples (n: 28) were included in this study. Bacterial identification was performed by biochemical tests and phenotypificationwas done using the Phene-PlateTM system. Susceptibility to different antimicrobial agents was determined by the agar dilution method. Virulence genes aceI, agg, gelE and efaA were detected by multiplex PCR. Results: All isolates were susceptible to vancomycin and ampicillin. HLR to gentamicin (13.5%) and streptomycin (9.6%) was detected only in clinical isolates. The phenotyping revealed a great diversity of PhP-types, but only one clone with 7 strains of similar characteristics was found. The efaA gen was detected in 100% of the isolates. aceI gene was present in 94.2% and 75%, agg gene in 73.1%, and 67.9%, and gelE gene in 57.5% and 28.6% of the clinical and chicken isolates, respectively. Only 6 strains with HLR to aminoglycosides, belonging to the same phenotype, had the aceI, agg, gelE and efaA genes. Conclusions: E. faecalis with virulence genes and HLR to aminoglycosides were isolated from clinical and chicken samples in Antofagasta. More studies will be necessary to establish an association.

Antecedentes: Enterococcus spp. es una causa importante de infecciones nosocomiales, tanto en Chile como internacional. Se han descrito una serie de factores de virulencia en este microorganismo, que pueden, por ejemplo, aumentar su habilidad para colonizar. Enterococcus tiene capacidad de adquirir genes de resistencia, entre ellos la resistencia de alto nivel (RAN) a los antimicrobianos aminoglucósidos. Objetivo: Investigar la prevalencia de genes de virulencia en cepas de E. faecalis susceptibles y resistentes a aminoglucósidos. Material y Métodos: Un total de 80 cepas de E. faecalis aisladas de muestras clínicas (n: 52) y pollos (n: 28) se incluyeron en este estudio. La identificación se hizo por pruebas bioquímicas y se tipificaron por el sistema Phene-PlateMR. La susceptibilidad a diferentes antimicrobianos fue realizada por test de dilución en agar. Los genes de virulencia aceI, agg, gelE y efaA fueron investigados por RPC múltiple. Resultados: Todas las cepas de E. faecalis fueron susceptibles a vancomicina y ampicilina. Un 13,5% de las cepas clínicas presentaron resistencia de alto nivel a gentamicina y 9,6% a estreptomicina. La tipificación reveló una gran diversidad de fenotipos, pero se encontró un clon con 7 cepas de características similares. El gen efaA estaba presente en 100% de las cepas, gen aceI en 94,2 y 75%, gen agg 73,1 y 67,9% y gen gelE 57,5 y 28,6% de las cepas clínicas y de pollos, respectivamente. Seis cepas con resistencia de alto nivel a aminoglucósidos, que pertenecían a un mismo fenotipo exhibieron los genes efaA, aceI, agg y gelE juntos. Conclusiones: Cepas de E. faecalis que albergan genes de virulencia y con resistencia de alto nivel a aminoglucósidos fueron aisladas de muestras clínicas y de pollos en Antofagasta. Se requieren mayores estudios para establecer una asociación entre estos factores.

Bacterias con alta tasa de mutación: los riesgos de una vida acelerada / High mutation rate bacteria: Risks of a high-speed life

El proceso evolutivo de un ser vivo se acelera cuanto mayor sea su capacidad para producir variabilidad genética, bien por mutación, bien por recombinación.Sin embargo, cuanto mayor sea esta capacidad, mayor también será el riesgo de acumular mutaciones deletéreas. La variabilidad genética es, por tanto, un proceso altamente regulado, de tal manera que las bacterias tienden a mantener una baja tasa de mutación. En diferentes poblaciones bacterianas analizadas hay siempre un porcentaje variable de cepas con una tasa de mutación superior a la frecuencia modal del resto de la población. Existe una relación directa entre la proporción de cepas que mutan y el grado de estrés del ambiente. Así, en los procesos infecciosos crónicos, en los que el tratamiento antibiótico es constante durante períodos prolongados, se observan los mayores porcentajes de bacterias que mutan, cercano al 50 por ciento de la población. Esta selección positiva de bacterias que mutan es debida al enorme potencial que presentan para desarrollar resistencia antibiótica (100 veces superior a una bacteria normal). Esta capacidad ha sido explotada, en algunos centros de investigación, como un modelo natural de evolución acelerada para predecir la facilidad con la que determinadas variantes resistentes pueden aparecer, saber qué posiciones serán las más susceptibles a los cambios y cuál será el costo para la bacteria. El laboratorio de microbiología debe hacer un esfuerzo por detectar estas cepas mutadoras antes de que desarrollen mecanismos de resistencia e induzcan el fracaso terapéutico

The potential of producing genetic variability, eitherby mutation or by recombination, is the driving for-ce of evolution in a living organism. Geneticvariability is a quite regulated process in which bac-teria tend to maintain a low mutation rate. However,a variable proportion of bacteria with a highermutation rate than that of the modal is alwayspresent in any population. Moreover, a direct rela-tionship exists between the proportion of mutatorstrains and environmental stress. In chronicinfectious diseases, due to prolonged antibioticregimens, nearly 50% of the population may berepresented by mutating bacteria. Such a positiveselection is due to the capacity of this type of strainsto develop antibiotic resistance (100 fold higherthan normal bacteria) This trait has been used asan accelerated-evolution model to predict the easeof certain resistant variants to emerge as well asto infer which targets are more prone to bemodified and the concomitant cost that suchvariability would imply to the organism.The Microbiology laboratory might then doan effort to detect mutating strains before theappearance of resistance mechanisms that maylead to therapeutic failures.Keywords: evolution, genetic recombination,mutagenesis, bacterial drug resistance.Fecha de recepción