Sequence-level and dual-phase identification of Salmonella flagellum antigens by liquid chromatography-tandem mass spectrometry (LC-MS/MS).

Forty-three reference strains involving the 24 most common serovars of Salmonella enterica were examined by using a mass spectrometry-based H antigen typing platform (MS-H). The results indicate that MS-H can be used as a sensitive, rapid, and straightforward approach for the typing of Salmonella flagella at the molecular level without antiserum and phase inversion.

Shared genome analyses of notable listeriosis outbreaks, highlighting the critical importance of epidemiological evidence, input datasets and interpretation criteria.

The persuasiveness of genomic evidence has pressured scientific agencies to supplement or replace well-established methodologies to inform public health and food safety decision-making. This study of 52 epidemiologically defined Listeria monocytogenes isolates, collected between 1981 and 2011, including nine outbreaks, was undertaken (1) to characterize their phylogenetic relationship at finished genome-level resolution, (2) to elucidate the underlying genetic diversity within an endemic subtype, CC8, and (3) to re-evaluate the genetic relationship and epidemiology of a CC8-delimited outbreak in Canada in 2008. Genomes representing Canadian Listeria outbreaks between 1981 and 2010 were closed and manually annotated. Single nucleotide variants (SNVs) and horizontally acquired traits were used to generate phylogenomic models. Phylogenomic relationships were congruent with classical subtyping and epidemiology, except for CC8 outbreaks, wherein the distribution of SNV and prophages revealed multiple co-evolving lineages. Chronophyletic reconstruction of CC8 evolution indicates that prophage-related genetic changes among CC8 strains manifest as PFGE subtype reversions, obscuring the relationship between CC8 isolates, and complicating the public health interpretation of subtyping data, even at maximum genome resolution. The size of the shared genome interrogated did not change the genetic relationship measured between highly related isolates near the tips of the phylogenetic tree, illustrating the robustness of these approaches for routine public health applications where the focus is recent ancestry. The possibility exists for temporally and epidemiologically distinct events to appear related even at maximum genome resolution, highlighting the continued importance of epidemiological evidence.

Lineage specific recombination and positive selection in coding and intragenic regions contributed to evolution of the main Listeria monocytogenes virulence gene cluster.

The major virulence cluster of Listeria monocytogenes harbors six virulence genes that encode proteins critical for the intracellular life cycle of this human and animal pathogen. In this study, we determined the sequence (8709nt) of the virulence gene cluster (including the six main virulence genes) in 40 L. monocytogenes isolates from different source populations (human clinical cases, animal clinical cases, foods, and natural environments). An alignment of the full length cluster as well as individual gene alignments and alignments of intragenic regions were used for phylogenetic, recombination, and positive selection analyses. Initial phylogenetic analyses showed that the sequences represented two main clusters, consistent with previously defined L. monocytogenes phylogenetic lineages. The 40 sequences represented 25 distinct allelic types and the overall alignment included 592 polymorphic sites. Overall, our data show that (i) virulence genes in the main L. monocytogenes virulence gene cluster include highly conserved genes (i.e., hly and prfA) as well as diverse genes that appear to have evolved by positive selection (mpl, actA, and plcA), (ii) recombination has played an important role in the evolution of the virulence gene cluster, but is limited to lineage II isolates, and (iii) the promoter region driving the transcription of virulence genes transcribed early in intracellular infection (i.e., hly and plcA) has evolved by positive selection. The genes and intragenic regions in the L. monocytogenes virulence gene cluster thus have evolved independently, despite their close physical linkage, likely reflecting distinct selective pressures associated with expression and function of the proteins encoded in this region.

Genetic determinants and polymorphisms specific for human-adapted serovars of Salmonella enterica that cause enteric fever.

Salmonella enterica serovars Typhi, Paratyphi A, and Sendai are human-adapted pathogens that cause typhoid (enteric) fever. The acute prevalence in some global regions and the disease severity of typhoidal Salmonella have necessitated the development of rapid and specific detection tests. Most of the methodologies currently used to detect serovar Typhi do not identify serovars Paratyphi A or Sendai. To assist in this aim, comparative sequence analyses were performed at the loci of core bacterial genetic determinants and Salmonella pathogenicity island 2 genes encoded by clinically significant S. enterica serovars. Genetic polymorphisms specific for serovar Typhi (at trpS), as well as polymorphisms unique to human-adapted typhoidal serovars (at sseC and sseF), were observed. Furthermore, entire coding sequences unique to human-adapted typhoidal Salmonella strains (i.e., serovar-specific genetic loci rather than polymorphisms) were observed in publicly available comparative genomic DNA microarray data sets. These polymorphisms and loci were developed into real-time PCR, standard PCR, and liquid microsphere suspension array-based molecular protocols and tested for with a panel of clinical and reference subspecies I S. enterica strains. A proportion of the nontyphoidal Salmonella strains hybridized with the allele-specific oligonucleotide probes for sseC and sseF; but the trpS allele was unique to serovar Typhi (with a singular serovar Paratyphi B strain as an exception), and the coding sequences STY4220 and STY4221 were unique among serovars Typhi, Paratyphi A, and Sendai. These determinants provided phylogenetic data on the genetic relatedness of serovars Typhi, Paratyphi A, and Sendai; and the protocols developed might allow the rapid identification of these Salmonella serovars that cause enteric fever.