Cross-protective effect of acid adaptation on ethanol tolerance in Salmonella Enteritidis

Cross protection can undermine the effectiveness of control measures on foodborne pathogens,and therefore brings major implications for food safety.In this work,the capacity of Salmonella Enteritidis to mount ethanol tolerance following acid adaptation was characterized by analysis of cell viability and cell membrane property.It was observed that preadaptation to pH 4.5 significantly(P<0.05)increased the tolerance of log-phase cells to ethanol;in contrast,stationary-phase cells displayed reduced ethanol tolerance after acid adaptation.However,acid adaptation did not cause cell leakage and morphological change in both log-phase and stationary-phase S.Enteritidis.Fatty acid analysis further revealed that the amount of C_(14:0),C_(17:0 cyclo) and C_(19:0 cyclo) fatty acids was increased,while that of C_(16:1ω7c) and C_(18:1ω7c) fatty acids was decreased,respectively,in response to acid adaptation,regardless of bacterial growth phase.Notably,acid adaptation significantly(P<0.05)increased the proportion of C_(16:0) fatty acid in log-phase cells,but this effect did not occur in stationary-phase cells.Moreover,exogenous addition of C_(16:0) fatty acid to stationary-phase acid-adapted cultures was able to enhance bacterial ethanol tolerance.Taken together,C_(16:0) fatty acid is involved in the growth-phase-dependent protective effect of acid adaptation on ethanol tolerance in S.Enteritidis.

EoPHR2,a Phosphate Starvation Response Transcription Factor,Is Involved in Improving Low-Phosphorus Stress Resistance in Eremochloa ophiuroides

As a macronutrient,Phosphorus(P)takes many roles in plant growth and development.It should be significant to explore the molecular mechanism of low-phosphorus stress response of plants.Phosphate starvation response(PHR)transcription factors play important roles in response to phosphorus deficiency stress in plants.In this study,we isolated a gene related to the plant phosphorus signaling system from the acid-soil-resistant centipedegrass(Eremochloa ophiuroides[Munro]Hack.),termed EoPHR2.The subcellular localization of EoPHR2 protein was observed to be nuclear located.The expression patterns of EoPHR2 in different tissues and Al/Pi-stress conditions were analyzed by qRT-PCR,they suggested a potential role in response to the multiple-stress under acid soil adversity.Based on the functional identification through transgenic plants,we found that(1)EoPHR2 is involved in the Pi-signaling pathway,and(2)overexpression of EoPHR2 mimics Pi-starvation signalling resulting on enhanced roots whether under Pi-deficiency stress or not.In conclusion,EoPHR2 transcription factor plays a role in response to the multiple stresses under acid soil conditions,improving the low-phosphorus stress resistance of Eremochloa ophiuroides.