Evaluation of pre-PCR processing approaches for enumeration of Salmonella enterica in naturally contaminated animal feed.

AIMS: Three pre-PCR processing strategies for the detection and/or quantification of Salmonella in naturally contaminated soya bean meal were evaluated. METHODS AND RESULTS: Methods included: (i) flotation-qPCR [enumeration of intact Salmonella cells prior to quantitative PCR (qPCR)], (ii) MPN-PCR (modified most probable number method combined with qPCR) and (iii) qualitative culture enrichment PCR. The limit of quantification was 1·8 × 10(2) CFU g(-1) (flotation-qPCR) and 0·02 MPN g(-1) (MPN-PCR). Fifteen naturally contaminated Salmonella positive soya bean meal samples from one lot were analysed in parallel with the three methods, using 2·5, 50 and 25 g of feed, respectively, resulting in detection of Salmonella in 6, 15 and 9 bags. Enumeration resulted in 1·8 × 10(2) -7·8 × 10(3) CFU g(-1) (flotation-qPCR) and 0·024 to >5·2 MPN g(-1) (MPN-PCR). CONCLUSIONS: Except for differences in methodology, results obtained with the three techniques could be due to the presence of nonculturable Salmonella and/or a heterogeneous distribution of Salmonella in the material. SIGNIFICANCE AND IMPACT OF THE STUDY: The evaluated methods provide different possibilities to assess the prevalence of Salmonella in feed, together with the numbers of culturable, as well as nonculturable cells, and can be applied to generate data to allow more accurate quantitative microbial risk assessment for Salmonella in the feed chain.

Novel form of ClpB/HSP100 protein in the cyanobacterium Synechococcus.

Synechococcus sp. strain PCC 7942 has a second clpB gene that encodes a 97-kDa protein with novel features. ClpBII is the first ClpB not induced by heat shock or other stresses; it is instead an essential, constitutive protein. ClpBII is unable to complement ClpBI function for acquired thermotolerance. No truncated ClpBII version is normally produced, unlike other bacterial forms, while ectopic synthesis of a putative truncated ClpBII dramatically decreased cell viability.

The ATP-dependent Clp protease is essential for acclimation to UV-B and low temperature in the cyanobacterium Synechococcus.

ClpP is the proteolytic subunit of the ATP-dependent Clp protease in eubacteria, mammals and plant chloroplasts. Cyanobacterial ClpP protein is encoded by a multigene family, producing up to four distinct isozymes. We have examined the importance of the first ClpP protein (ClpP1) isolated from the cyanobacterium Synechococcus sp. PCC 7942 for acclimation to ecologically relevant UV-B and low-temperature regimens. When the growth light of 50 mumol photons m-2 s-1 was supplemented with 0.5 W m-2 UV-B for 8 h, the constitutive level of ClpP1 rose eightfold after an initial lag of 1 h. Wild-type cells readily acclimated to this UV-B level, recovering after the initial stress to almost the same growth rate as that before UV-B exposure. Growth of a clpP1 null mutant (delta clpP1), however, was severely inhibited by UV-B, being eight times slower than the wild type after 8 h. In comparison, ClpP1 content increased 15-fold in wild-type cultures shifted from 37 degree C to 25 degree C for 24 h. Wild-type cultures readily acclimated to 25 degree C after 24 h, whereas the delta clpP1 strain did not and eventually lost viability with prolonged cold treatment. During acclimation to either UV-B or cold, photosynthesis in the wild type was initially inhibited upon the shift but then recovered. Photosynthesis in delta clpP1 cultures, however, was more severely inhibited by the stress treatment and failed to recover. Acclimation was also monitored by examining the exchange of photosystem II reaction centre D1 proteins that occurs in wild-type Synechococcus during conditions of excitation stress. During both cold and UV-B shifts, wild-type cultures replaced the acclimative form of D1 (D1:1) with the alternative D1 form 2 (D1:2) within the first hours. Once acclimated to either 25 degree C or 0.5 W m-2 UV-B, D1:2 was exchanged back for D1:1. In delta clpP1 cultures, this second exchange between D1 forms did not occur, with D1:2 remaining the predominant D1 form. Our results demonstrate that the ATP-dependent Clp protease is an essential component of the cold and UV-B acclimation processes of Synechococcus.

Inactivation of the clpP1 gene for the proteolytic subunit of the ATP-dependent Clp protease in the cyanobacterium Synechococcus limits growth and light acclimation.

ClpP functions as the proteolytic subunit of the ATP-dependent Clp protease in eubacteria, mammals and plant chloroplasts. We have cloned a clpP gene, designated clpP1, from the cyanobacterium Synechococcus sp. PCC 7942. The monocistronic 591 bp gene codes for a protein 80% similar to one of four putative ClpP proteins in another cyanobacterium, Synechocystis sp. PCC 6803. The constitutive ClpP1 content in Synechococcus cultures was not inducible by high temperatures, but it did rise fivefold with increasing growth light from 50 to 175 micromol photons m(-2) s(-1). A clpP1 inactivation strain (delta clpP1) exhibited slower growth rates, especially at the higher irradiances, and changes in the proportion of the photosynthetic pigments, chlorophyll a and phycocyanin. Many mutant cells (ca. 35%) were also severely elongated, up to 20 times longer than the wild type. The stress phenotype of delta clpP1 when grown at high light was confirmed by the induction of known stress proteins, such as the heat shock protein GroEL and the alternate form of PSII reaction center D1 protein, D1 form 2. ClpP1 content also rose significantly during short-term photoinhibition, but its loss in delta clpP1 did not exacerbate the extent of inactivation of photosynthesis, nor affect the inducible D1 exchange mechanism, indicating ClpP1 is not directly involved in D1 protein turnover.