Influence of Physiological State, Prolonged Dry Storage, and Passage through Simulated Digestion on the Survival and Gene Expression of Salmonella enterica sv. Tennessee

Aviles, Bryan

04 June 2012

Salmonella enterica serotypes have been linked to outbreaks associated with low water activity foods. The ability of biofilm forming pathogens, such as Salmonella, to survive thermal and chemical processes is improved; it is unclear if biofilms will also improve survival to desiccation and gastric stresses. The purpose of this study was to quantify the effect of physiological state (planktonic versus biofilm) and prior exposure to desiccation on Salmonella survival and gene expression after passage through an in-vitro digestion model. Cells of Salmonella enterica serotype Tennessee were deposited onto membranes for planktonic cells or on glass beads to create biofilms. The cells were subsequently dried at room temperature and stored in dried milk powder (aw = 0.3) for up to 30 days. Salmonella survival was quantified by serial dilution onto brilliant green agar before desiccation, after desiccation, after 1-day storage and after 30-day storage. At each sampling both physiological states were tested for survival through a simulated gastrointestinal system. RNA was extracted at the identical time points and relative gene expression determined for genes associated with stress response (rpoS, otsB), virulence (hilA, hilD, invA, sipC) and a housekeeping gene 16S rRNA using quantitative real-time PCR. The physiological state and length of storage effected the survival and gene expression of Salmonella within the desiccated milk powder environment and after passage through an in-vitro digestion system (p<0.05). Larger numbers of S. Tennessee were recovered by plate counts for biofilm cells, compared to planktonic cells. However, the numbers of 16S rRNA gene copies were not significantly different suggesting entry of S. Tennessee into a viable but non-culturable state. Prolonged storage in dry milk powder was not associated with increased cross-protection to gastric stress. Increased expression of stress response genes rpoS and otsB correlated with survival, indicating cross protection of low water activity and acid stress. Increased expression of virulence-associated genes was seen in cells exposed to short periods of dry storage, suggesting an increased virulence potential. / Master of Science in Life Sciences

in vitro digestion

stress response

virulence

16S rDNA

biofilms

low moisture

desiccation stress

Salmonella enterica

Viable but non-culturable

Transcriptional regulation and physiological importance of the kdp-system from the halophilic archaeon Halobacterium salinarum

Kixmüller, Dorthe

03 April 2012

The high affinity, ATP-dependent K+ uptake system KdpFABC of Halobacterium salinarum, is highly induced under K+ limitation. In contrast to the well-characterized Kdp system in Escherichia coli, in which the kdpFABC genes are transcriptionally regulated by the sensor kinase/response regulator system KdpD/KdpE, transcriptional regulation of the kdp genes in H. salinarum was unknown due to the absence of halobacterial homologues of KdpD/KdpE. Furthermore, the physiological relevance of the KdpFABC K+ uptake system of H. salinarum was puzzling, since hypersaline habitats usually comprise K+ concentrations which do not induce kdp expression. In order to analyze the regulation of kdp gene expression, it was essential to gain information about the transcriptional unit(s) involved. Northern blotting, primer extension analysis and real-time RT-PCR revealed the presence of a polycistronic leaderless kdpFABCQ transcript with a putative kdp terminator or at least a potential mRNA processing site downstream of kdpQ. Furthermore, promoter truncation studies verified the so far only predicted basal transcription elements together with an upstream-located operator sequence. Since deletions of this putative operator sequence did not lead to a constitutive expression, a further component has to be involved in the regulation of the kdpFABCQ genes. However, truncation and scanning mutagenesis analyses of the kdp promoter as well as translational fusions of a halophilic beta-galactosidase to the kdp promoter excluded an additional regulatory element up- or downstream of the basal transcription elements and in the kdp-coding region. These results lead to speculations of multiple basal transcription factors to be involved. Furthermore, an inducible expression vector (shuttle vector) was constructed based on the promoter of the kdpFABCQ operon due to its, K+-sensitive features. Inducible expression systems are yet not available for H. salinarum. The resulting, replicating vector pKIX is functional and enables a K+-dependent expression from the kdp promoter with rather high induction ratios of 50-fold. Expression levels could further be improved by plasmid- and additional chromosomally encoded kdpQ and mutations generated in the kdp promoter. Since transcript levels from pKIX were found to be independent of differential target genes, the general application of pKIX as an inducible expression system is strongly supported and pKIX could, thus, be made accessible to the scientific community. To decipher the physiological relevance of the halobacterial Kdp system, H. salinarum was encountered to desiccation stress and salt crystal (halite) entombment. Halite crystals grown under non-inducing K+ concentrations with entombed strains of H. salinarum and H. salinarum deleted in the kdpFABCQ genes revealed a significantly reduced survival rate of the deletion strain upon recultivation. Additionally, a kdpFABCQ-inducing desiccation stress could already be determined on agar plates under non-limiting K+ concentrations. Furthermore, the cell morphology of H. salinarum entrapped in halite crystals resembled that of H. salinarum grown under K+-limiting conditions. Therefore, the Kdp system promotes survival of H. salinarum under desiccation stress. Furthermore, the Kdp system could be identified as at least one of the systems important for long-term survival of H. salinarum in halite.

Halobacterium

Halobacterium salinarum

H. salinarum

halophile

halophil

archaea

archaeon

kdp

kdpFABC

kdpFABCQ

kdp-System

ATP

Kalium

Kaliumaufnahme

K+

Halit

Salzkristall

Austrocknung

Trockenstress

transkriptionelle Regulation

Genexpression

pKIX

induzierbarer Expressionsvektor

Expressionsvektor

kdpQ

Kdp Komplex

halobacterial

halophilic

kdpFABC genes

kdp-system

high-affinity

ATP-dependent

potassium

potassium pump

K+ uptake

desiccation

desiccation stress

halite

salt crystal

long-term survival

transcriptional regulation

gene expression

inducible expression vector

expression vector

Kdp complex

ddc:570