Direct identification of Photobacterium damselae subspecies piscicida by PCR-RFLP analysis

Fish photobacteriosis-The importance of rapid and accurate identification of Photobacterium damselae subsp. piscicida

MALDI-TOF MS was tested for the identification of Photobacterium damselae subsp. piscicida on isolates grown on two media, cultured at three incubation times and applied on the target plate by the direct sample spotting (DS), by the on-target extraction (OTE) and by the full extraction (FE) method, in triplicates. The identification of samples grown on blood agar (BA) outperformed identification on tryptic soya agar (TSA) by 0.64% for DS and OTE. The OTE gave the highest scores in both culture media, all incubation times and replicates. Reliable 24-hr species identification was 61.54%, 84.61% and 53.85% for samples grown on TSA and identified by DS, OTE and FE, respectively. For isolates grown on BA, they were 76.92%, 96.15% and 30.77%, respectively. When identified by OTE, the 48-hr identification was 93.58%, but for 72 hr declined to 71.79%. The reliable identification with the highest score from the first measurement was 100% only for OTE from BA (24 hr), whereas OTE from TSA gave 84.61% (24 hr), 76.92% (48 hr) and 84.61% (72 hr). The reliable MALDI-TOF MS identification of Ph. damselae subsp. piscicida is incubation time, media, target plate preparation and replicate-dependent.

Development of a real-time PCR assay for rapid detection and quantification of Photobacterium damselae subsp. piscicida in fish tissues

The availability of a rapid and accurate method for the diagnosis of Photobacterium damselae subsp. piscicida (Phdp), able to discriminate its strictly correlated subsp. damselae (Phdd), formally known as Vibrio damsela, is essential for managing fish pasteurellosis outbreaks in farmed fish. A single-step, high-sensitivity real-time PCR assay for simultaneous detection and quantification of P. damselae was designed targeting partial of the sequence of the bamB gene and tested for specificity and sensitivity on laboratory-generated samples as well as on experimentally infected seabream tissue samples. With a limit of detection (LOD) of one copy in pure bacterial DNA, the sensitivity was higher than all methods previously reported. Validation in target and non-target bacterial species proved the assay was able to discriminate Phdd-Phdp subspecies from diverse hosts/geographical origins and between non-target species. In addition, two SNPs in the target amplicon region determine two distinctive qPCR dissociation curves distinguishing between Phdp-Phdd. This is the first time that a molecular method for P. damselae diagnosis combines detection, quantification and subspecies identification in one step. The assay holds the potential to improve the knowledge of infection dynamics and the development of better strategies to control an important fish disease.

Photobacteriosis: prevention and diagnosis

Photobacteriosis or fish pasteurellosis is a bacterial disease affecting wild and farm fish. Its etiological agent, the gram negative bacterium Photobacterium damselae subsp. piscicida, is responsible for important economic losses in cultured fish worldwide, in particular in Mediterranean countries and Japan. Efforts have been focused on gaining a better understanding of the biology of the pathogenic microorganism and its natural hosts with the aim of developing effective vaccination strategies and diagnostic tools to control the disease. Conventional vaccinology has thus far yielded unsatisfactory results, and recombinant technology has been applied to identify new antigen candidates for the development of subunit vaccines. Furthermore, molecular methods represent an improvement over classical microbiological techniques for the identification of P. damselae subsp. piscicida and the diagnosis of the disease. The complete sequencing, annotation, and analysis of the pathogen genome will provide insights into the pathogen laying the groundwork for the development of vaccines and diagnostic methods.

High mortality of juvenile gilthead sea bream (Sparus aurata) from photobacteriosis is associated with alternative macrophage activation and anti-inflammatory response: results of gene expression profiling of early responses in the head kidney

The halophilic bacterium Photobacterium damselae subsp. piscicida (Phdp) represents a substantial health problem for several fish species in aquaculture. Bacteria that reside free and inside phagocytes cause acute and chronic forms of photobacteriosis. Infections of juveniles rapidly kill up to 90-100% fish. Factors underlying failure of the immune protection against bacteria remain largely unknown. The reported study used a transcriptomic approach to address this issue. Juvenile sea breams (0.5 g) were challenged by immersion in salt water containing 2.89 × 10(8) CFU of a virulent Phdp and the head kidney was sampled after 24- and 48-h. Analyses were performed using the second version of a 44 k oligonucleotide DNA microarray that represents 19,734 sea bream unique transcripts and covers diverse immune pathways. Expression changes of selected immune genes were validated with qPCR. Results suggested rapid recognition of the pathogen, as testified by up-regulation of lectins and antibacterial proteins (bactericidal permeability-increasing protein lectins, lysozyme, intracellular and extracellular proteases), chemokines and chemokine receptors. Increased expression of proteins involved in iron and heme metabolism also could be a response against bacteria that are dependent on iron. However, negative regulators of immune/inflammatory response were preponderant among the up-regulated genes. A remarkable finding was the increased expression of IL-10 in concert with up-regulation of arginase I and II and proteins of the polyamine biosynthesis pathway that diverts the arginine flux from the production of reactive nitrogen species. Such expression changes are characteristic for alternatively activated macrophages that do not develop acute inflammatory responses. Immune suppression can be induced by the host to reduce tissue damages or by the pathogen to evade host response.

Quantitative trait loci for resistance to fish pasteurellosis in gilthead sea bream (Sparus aurata)

Fish pasteurellosis is a bacterial disease causing important losses in farmed fish, including gilthead sea bream, a teleost fish of great relevance in marine aquaculture. We report in this study a QTL analysis for resistance to fish pasteurellosis in this species. An experimental population of 500 offspring originating from eight sires and six dams in a single mass-spawning event was subjected to a disease challenge with Photobacterium damselae subsp. piscicida (Phdp), the causative agent of fish pasteurellosis. A total of 151 microsatellite loci were genotyped in the experimental population, and half-sib regression QTL analysis was carried out on two continuous traits, body length at time of death and survival, and for two binary traits, survival at day 7 and survival at day 15, when the highest peaks of mortality were observed. Two significant QTLs were detected for disease resistance. The first one was located on linkage group LG3 affecting late survival (survival at day 15). The second one, for overall survival, was located on LG21, which allowed us to highlight a potential marker (Id13) linked to disease resistance. A significant QTL was also found for body length at death on LG6 explaining 5-8% of the phenotypic variation.

Differential diagnosis of Perkinsus species by polymerase chain reaction-restriction fragment length polymorphism assay

Perkinsosis is an infection of marine molluscs caused by the protistan parasites of the genus Perkinsus, which has been classified by the OIE as a disease that warrants notification. In the present study, we have applied a molecular genetic approach to develop an optional method for the specific identification of Perkinsus species. A species-specific polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) assay of the rRNA ITS region was developed to identify and distinguish among Perkinsus species. A taxonomic key was established that allows successful identification of Perkinsus species using a single restriction enzyme (Rsa I) to discriminate P. chesapeaki and P. marinus or by a combination of two endonucleases (Rsa I plus Hinf I) to discriminate P. olseni and P. mediterraneus. In order to validate the RFLP assay, the PCR products were cloned and sequenced, and its phylogenetic affinity was determined. Phylogenetic analysis confirmed the specific identification carried out by RFLPs. Herein is the first report of P. olseni in Manila clams from the NW Adriatic Sea (Italy), which we identified by employing this method. The PCR-RFLP assay herein described may be useful to provide accurate, rapid and inexpensive identification of Perkinsus species, and may aid in ongoing epizooetiological studies and diseases control programmes.

Full-length sequence and expression analysis of Toll-like receptor 9 in the gilthead seabream (Sparus aurata L.)

Toll-Like Receptors (TLRs) have recently emerged as key sensors of invading microbes, acting through recognition of pathogen-associated molecular patterns. It has been demonstrated that TLR9 is involved in the recognition of unmethylated CpG motifs in mice, humans, and pigs. We report here the full-length sequence of TLR9 cDNA in the gilthead sea bream (Sparus aurata L.). The predicted protein (1063 amino acids) was similar to mammalian TLR9s, showing 21 leucine-rich repeats in the extracellular region and a typical Toll/IL-1R (TIR) domain in the intracellular region. Comparative analysis of TLR9 sequences indicated that critical residues for ligand-binding are conserved across vertebrate lineages, although evidence of functional divergence was observed. Analysis of the genomic structure of sea bream TLR9 gene revealed the presence of two intervening sequences. Retention of the second intron produced an alternatively spliced mRNA (TLR9B) showing differential expression among tissues or developmental stages compared to the wild-type isoform (TLR9A). RT-PCR analysis indicated a broad expression of TLR9A, especially in immune-related organs (spleen, head-kidney) and mucosal-epithelial barriers (gills, gut, skin). Using quantitative Real-Time RT-PCR, no statistically significant variation was observed for TLR9 mRNAs expression in the spleen of experimentally infected animals compared to healthy controls. Comparing sequence and expression profile of sea bream TLR9 with mammalian TLR9s suggested that the main function of TLR9 might be conserved across vertebrates, although species-specific features are present (modulation of ligand-binding specificity, alternative splicing).