RESUMO
Salmonella enterica Typhimurium DT104 (S. Typhimurium DT104) is an important foodborne pathogen that is associated with poultry and poultry products. Currently, there is very little information on the underlying molecular mechanisms that allow DT104 to survive and propagate in poultry meat and the poultry processing environment. The current study assessed the global gene expression of DT104 in ground chicken extract (GCE) compared to brain heart infusion (BHI) medium using RNA-Seq technology. DT104 was grown to the early stationary phase (ESP), inoculated into GCE or BHI, and then re-grown to the log phase before RNA was extracted and transcripts were quantified by RNA-Seq. Gene expression for DT104 grown in GCE was then compared to that of DT104 grown in BHI for samples grown to the ESP. Growth in GCE resulted in the up-regulated expression of genes related to translation, carnitine metabolism (23-283-fold change), and cobalamin (vitamin B12) biosynthesis (14-fold change). In particular, the presence of carnitine in chicken meat, and thus, in GCE, which lacks carbohydrates, may allow Salmonella to utilize this compound as a carbon and nitrogen source. This study demonstrates that RNA-Seq data can provide a comprehensive analysis of DT104 gene expression in a food model for poultry products. This study also provides additional evidence for the importance of metabolic adaptation in the ability of S. enterica to successfully adapt to and occupy niches outside of its host and provides potential targets that could be used to develop intervention strategies to control Salmonella in poultry.
RESUMO
Salmonella is a Gram-negative, rod-shaped, facultative anaerobic, and non-spore-forming bacterium that belongs to the family of Enterobacteriaceae and is the causative agent for typhoid/paratyphoid fever and salmonellosis. Salmonella causes the highest amount of foodborne illness among bacteria at 15.5 cases per 100,000 and causes an estimated 410,000 antibiotic-resistant infections each year in the U.S. The use of antibiotics has been a staple in poultry production for the prevention of diseases and growth promotion for the last 70 years. Due to the over-and misusage of antibiotics, there has been an emerging public health crisis. Salmonella is developing resistance and may render antibiotics inoperative in a foodborne outbreak. Poultry, when not handled properly, is a major carrier and transmitter of Salmonella, causing human illness and fatality. This review summarizes the major Salmonella outbreaks over the past three decades, the prevalence of Antimicrobial Resistant (AMR) Salmonella related to poultry, and the control measures being implemented to reduce and prevent AMR Salmonella in poultry.
RESUMO
Growth models are predominately used in the food industry to estimate the potential growth of selected microorganisms under environmental conditions. The growth kinetics, cellular morphology, and antibiotic resistance were studied throughout the life cycle of Salmonella Typhimurium. The effect of the previous life cycle phase [late log phase (LLP), early stationary phase (ESP), late stationary phase (LSP), and early death phase (EDP)] of Salmonella after reinoculation in brain heart infusion broth (BHI), ground chicken extract (GCE), and BHI at pH 5, 7, and 9 and salt concentrations 2, 3, and 4% was investigated. The growth media and previous life cycle phase had significant effects on the lag time (λ), specific growth rate (µ max), and maximum population density (Y max). At 2 and 4% salt concentration, the LLP had the significantly (p < 0.05) fastest µ max (1.07 and 0.69 log CFU/ml/h, respectively). As the cells transitioned from the late log phase (LLP) to the early death phase (EDP), the λ significantly (p < 0.05) increased. At pH 5 and 9, the EDP had a significantly (p < 0.05) lower Y max than the LLP, ESP, and LSP. As the cells transitioned from a rod shape to a coccoid shape in the EDP, the cells were more susceptible to antibiotics. The cells regained their resistance as they transitioned back to a rod shape from the EDP to the log and stationary phase. Our results revealed that growth kinetics, cell's length, shape, and antibiotic resistance were significantly affected by the previous life cycle phase. The results of this study also demonstrate that the previous life cycle should be considered when developing growth models of foodborne pathogens to better ensure the safety of poultry and poultry products.
RESUMO
Listeria monocytogenes was recently found to enter a long-term-survival (LTS) phase, which may help explain its persistence in natural environments and within food processing plants. The purpose of this study was to investigate the effects of initial cell density, initial pH and type of broth (fresh vs. spent) on the transition of L. monocytogenes to the LTS phase and model the change in viable population density with time. Initial cell density (~10(6)-~10(10)CFU/ml) and initial pH (5.36-6.85) both significantly affected the transition of L. monocytogenes to the LTS phase (P<0.001) with initial cell density being the main determining factor. In contrast, type of broth did not significantly affect cell density change during the transition of stationary-phase cells at high initial density to the LTS phase (P>0.05). After 30-d incubation no significant differences in cell densities were observed between either type of broth or between any of the initial cell density/pH treatment combinations (P>0.05), where the mean viable cell density was 4.3±1.1×10(8)CFU/ml. L. monocytogenes responded to viable cell density in accordance with the logistic equation during transition to the LTS phase. The Agr quorum-sensing system does not appear to play a role in the transition to the LTS phase. Further research is needed to better understand the control mechanisms utilized by L. monocytogenes as it transitions to a coccoid, resistant and stable density state in the LTS phase.