First isolation of Francisella halioticida strains from blue mussel (Mytilus edulis) in Normandy, France.

Mass mortality events affecting the blue mussels Mytilus edulis have been observed in France since 2014. The DNA of the bacterium Francisella halioticida, reported as pathogen of giant abalone (Haliotis gigantea) and Yesso scallop (Mizuhopecten yessoensis) has been detected recently in mussels from areas suffering mortalities. Isolation of this bacterium was attempted from individuals collected during mortality events. Identification was performed by 16S rRNA gene sequencing, real-time specific PCR and MALDI-ToF using spectra produced from the strain 8472-13A isolated from diseased Yesso scallop in Canada. Five isolates were identified as F. halioticida by real-time specific PCR and 16S rRNA sequencing. MALDI-ToF allowed the direct identification of four isolates (FR22a,b,c,d) which had 100% identity on the 16S rRNA gene with the known strains. On the other hand, one isolate (FR21) was not recognized by MALDI-ToF and had 99.9% identity on the 16S rRNA gene. The FR22 isolates showed difficult growth and required media optimization, which was not the case with the FR21 isolate. For these reasons, it was hypothesized that two type strains are present on French coasts, named FR21 and FR22. The FR21 isolate was selected for phenotypic analysis (growth curve, biochemical characteristics, electron microscopy), phylogenetic analysis and an experimental challenge. This isolate showed distinct differences compared to published F. halioticida strains, both at phenotypic and genotypic levels. Experimental infections of adult mussels led to 36% mortalities in 23 days following intramuscular injection with 3 × 107 CFU while a lower dose (3 × 103 CFU) did not lead to significant mortalities. In the context of this study, the strain FR21 was not virulent towards adult mussels.

Detection of the protistan parasite, Haplosporidium costale in Crassostrea gigas oysters from the French coast: A retrospective study.

The parasite Haplosporidium costale is known to infect and cause mortality in the oyster Crassostrea virginica in the USA. Decades after its first description in the 1960s, this parasite was detected in Crassostrea gigas in the USA and China. However, it presented a low prevalence and no mortality was associated with it. More recently, in 2019, H. costale was detected in France in a batch of moribund oysters. In order to observe how long this parasite has been present on French coasts, from Normandy to Thau lagoon, a retrospective investigation was conducted on 871 adult and spat oyster batches from 2004 to 2020. To allow rapid detection on a large panel of samples, a real-time PCR for the H. costale actin gene was developed. This method allowed the detection of H. costale DNA in adults from 2005 and in spat from 2008. The H. costale prevalence in spat appeared higher than in adults over the years studied, 14.59 % compared to 6.50 %, respectively. All samples presenting positive results were then sequenced on two targets, H. costale rRNA and actin genes. The actin gene sequencing highlighted the presence of two H. costale strains. Adult C. gigas as well as spat batches coming from hatcheries and DNA controls from C. virginica all presented with the Profile 1 H. costale strain. The Profile 2 H. costale strain was detected only in C. gigas spat coming from natural sources. These observations suggest a correlation between the origin of oysters and H. costale strains which may have been caused by commercial imports between Japan, USA and France back to the 1970s. Over the positive samples studied, only few batches (n = 3) suffered mortalities which could be hypothesized to be caused by H. costale, all presenting the Profile 1 H. costale strain.

Development of a semi-quantitative PCR assay for the detection of Francisella halioticida and its application to field samples.

The current study describes the development and application of a TaqMan® real-time PCR assay for the detection of the bacterium Francisella halioticida. Previously, detection of F. halioticida is relied on bacterial culture and conventional PCR; however, the real-time PCR provides many advantages because it is faster, less labour-intensive and reduces the risk of cross-contamination. DNA samples from mussels collected in April 2020 from seven sites in northern Brittany (France) were tested using the newly developed real-time PCR assay. The objective was to screen for the presence of F. halioticida during spring mortality events. The bacterium was detected in 71.4% of the samples tested and was present at all sites except for Saint-Brieuc and Mont-Saint-Michel, two sites which were not concerned by mortality at the time of sampling. Less than a month later, Saint-Brieuc was affected by unusual mortalities and F. halioticida was detected in almost all mussels (81.25%). The findings from this study provide further evidence indicating that F. halioticida may be contributing to mussel mortalities; however, a direct causal relationship has not yet been established. The real-time PCR assay developed in this study allows for rapid, specific and sensitive detection of F. halioticida which should prove useful for future studies concerning the involvement of this bacterium with shellfish mortalities.

Development and Validation of a Quantitative PCR Method for Equid Herpesvirus-2 Diagnostics in Respiratory Fluids.

The protocol describes a quantitative RT-PCR method for the detection and quantification of EHV-2 in equine respiratory fluids according to the NF U47-600 norm. After the development and first validation step, two distinct characterization steps were performed according to the AFNOR norm: (a) characterization of the qRT-PCR assay alone and (b) characterization of the whole analytical method. The validation of the whole analytical method included the portrayal of all steps between the extraction of nucleic acids and the final PCR analysis. Validation of the whole method is very important for virus detection by qRT-PCR in order to get an accurate determination of the viral genome load. Since the extraction step is the primary source of loss of biological material, it may be considered the main source of error of quantification between one protocol and another. For this reason, the AFNOR norm NF-U-47-600 recommends including the range of plasmid dilution before the extraction step. In addition, the limits of quantification depend on the source from which the virus is extracted. Viral genome load results, which are expressed in international units (IU), are easier to use in order to compare results between different laboratories. This new method of characterization of qRT-PCR should facilitate the harmonization of data presentation and interpretation between laboratories.