Diversité et plasticité des petits plasmides d'Aeromonas salmonicida ssp. salmonicida

Les plasmides confèrent aux bactéries qui les possèdent diverses fonctions pouvant accroître leurs chances de survie dans des environnements défavorables. C’est le cas d’Aeromonas salmonicida ssp. salmonicida, bactérie à l’origine de la furonculose chez les salmonidés. Elle possède trois petits plasmides (pAsa1, pAsa2 et pAsa3) qui sont cryptiques c’est-à-dire sans fonction connue. Pour compléter son plasmidome standard, s’ajoutent aux précédents, deux autres plasmides fréquemment retrouvés, pAsal1 et pAsa5, porteurs de gènes codant pour le système de sécrétion de type III, important facteur de virulence pour ce microorganisme. Enfin, ce ne sont pas moins de 17 plasmides porteurs de gènes de résistance aux antibiotiques et quatre supportant des facteurs de virulence qui ont été mis en évidence au cours des 30 dernières années pour cette bactérie. La propagation des gènes de résistance aux antibiotiques pose un problème dans le contexte vétérinaire puisqu’elle constitue, pour le moment, un obstacle au traitement efficace et durable contre la bactérie et conséquemment contre la furonculose. L’étude des petits plasmides d’A. salmonicida ssp. salmonicida s’inscrit dans cette démarche d’une meilleure connaissance de leur plasticité et de leur diversité. Ce projet a donc permis de mettre en évidence la présence de trois nouveaux petits plasmides : pAsa10, pAsaXI et pAsaXII. pAsa10 est la preuve supplémentaire que la propagation des gènes de résistance aux antibiotiques se poursuit, notamment par l’entremise du transposon Tn1721. L’analyse des séquences de pAsaXI et pAsaXII a permis de mettre en évidence des plasmides porteurs de nouvelles fonctionnalités pour A. salmonicida ssp. salmonicida, et des dérivés respectifs des plasmides cryptiques pAsa3 et pAsa2, très présents dans la bactérie, mais sans utilité apparente. Enfin, la haute capacité de transfert de ce microorganisme est encore démontrée, car ces plasmides sont identiques à d’autres retrouvés dans Shewanella baltica et Aeromonas bivalvium, respectivement.Plasmids confer to the bacteria that possess them various functions that increase their chances of survival in adverse environments. This is the case with Aeromonas salmonicida ssp. salmonicida, a bacterium which causes furunculosis in salmonids. It has three small plasmids (pAsa1, pAsa2 and pAsa3) that are cryptic that is to say without a known function. To supplement its standard plasmidome, two other frequently found plasmids, pAsal1 and pAsa5, which are carriers of genes coding for the type III secretion system, an important virulence factor of this microorganism. Finally, there are no less than 17 plasmids with genes coding for antibiotic resistance and 4 bearing virulence factors that have been demonstrated over the last 30 years for this bacterium. The spread of antibiotic resistance poses a problem in the veterinary context, since it is currently an obstacle to effective and sustainable treatment against the bacterium and consequently to furunculosis. The study of the small plasmids of A. salmonicida ssp. salmonicida is part of this process of a better knowledge of their plasticity and diversity. This project highlighted the presence of three new small plasmids: pAsa10, pAsaXI and pAsaXII. pAsa10 is a new evidence that propagation of antibiotic resistance genes continues, notably through the transposon Tn1721. The analysis of pAsaXI and pAsaXII sequences allowed to identify plasmids carrying new functionalities for A. salmonicida ssp. salmonicida, and derivatives of cryptic plasmids pAsa3 and pAsa2, respectively, very present in the bacterium but without apparent utility. Finally, the high transfer capacity of this microorganism is further demonstrated because these plasmids are identical to others found in Shewanella baltica and Aeromonas bivalvium, respectively

Variants of a genomic island in Aeromonas salmonicida subsp. salmonicida link isolates with their geographical origins

Aeromonas salmonicida subsp. salmonicida is a fish pathogen. Analysis of its genomic characteristics is required to determine the worldwide distribution of the various populations of this bacterium. Genomic alignments between the 01-B526 pathogenic strain and the A449 reference strain have revealed a 51-kb chromosomal insertion in 01-B526. This insertion (AsaGEI1a) has been identified as a new genomic island (GEI) bearing prophage genes. PCR assays were used to detect this GEI in a collection of 139 A. salmonicida subsp. salmonicida isolates. Three forms of this GEI (AsaGEI1a, AsaGEI1b, AsaGEI2a) are now known based on this analysis and the sequencing of the genomes of seven additional isolates. A new prophage (prophage 3) associated with AsaGEI2a was also discovered. Each GEI appeared to be strongly associated with a specific geographic region. AsaGEI1a and AsaGEI2a were exclusively found in North American isolates, except for one European isolate bearing AsaGEI2a. The majority of the isolates bearing AsaGEI1b or no GEI were from Europe. Prophage 3 has also a particular geographic distribution and was found only in North American isolates. We demonstrated that A. salmonicida subsp. salmonicida possesses unsuspected elements of genomic heterogeneity that could be used as indicators to determine the geographic origins of isolates of this bacterium.Keywords : Bacteria, Genomics-functional genomics-comparative genomics; Furunculosis; Aeromonas salmonicida; Fish pathogen; Genomic island; Geographical distributio

The Role for the Small Cryptic Plasmids As Moldable Vectors for Genetic Innovation in Aeromonas salmonicida subsp. salmonicida

In Aeromonas salmonicida subsp. salmonicida, a bacterium that causes fish disease, there are two types of small plasmids (<15 kbp): plasmids without known function, called cryptic plasmids, and plasmids that bear beneficial genes for the bacterium. Four among them are frequently detected in strains of A. salmonicida subsp. salmonicida: pAsa1, pAsa2, pAsa3, and pAsal1. The latter harbors a gene which codes for an effector of the type three secretion system, while the three others are cryptic. It is currently unclear why these cryptic plasmids are so highly conserved throughout strains of A. salmonicida subsp. salmonicida. In this study, three small plasmids, named pAsa10, pAsaXI and pAsaXII, are described. Linked to tetracycline resistance, a partial Tn1721 occupies half of pAsa10. A whole Tn1721 is also present in pAsa8, another plasmid previously described in A. salmonicida subsp. salmonicida. The backbone of pAsa10 has no relation with other plasmids described in this bacterium. However, the pAsaXI and pAsaXII plasmids are derivatives of cryptic plasmids pAsa3 and pAsa2, respectively. pAsaXI is identical to pAsa3, but bears a transposon with a gene that encodes for a putative virulence factor. pAsaXII, also found in Aeromonas bivalvium, has a 95% nucleotide identity with the backbone of pAsa2. Like pAsa7, another pAsa2-like plasmid recently described, orf2 and orf3 are missing and are replaced in pAsaXII by genes that encode a formaldehyde detoxification system. These new observations suggest that transposons and particularly Tn1721 are frequent and diversified in A. salmonicida subsp. salmonicida. Moreover, the discovery of pAsaXI and pAsaXII expands the group of small plasmids that are derived from cryptic plasmids and have a function. Although their precise roles remain to be determined, the present study shows that cryptic plasmids could serve as moldable vectors to acquire mobile elements such as transposons. Consequently, they could act as key agents of the diversification of virulence and adaptive traits of Aeromonas salmonicida subsp. salmonicida

Diversity and homogeneity among small plasmids of Aeromonas salmonicida subsp. salmonicida linked with geographical origin

Furunculosis, which is caused by Aeromonas salmonicida subsp. salmonicida, is a major salmonid disease in fish farms worldwide. Several plasmids found in this bacterium confer phenotypes such drug resistance and virulence. Small plasmids (pAsa1, pAsa2, pAsa3, and pAsal1) related to ColE1- and ColE2-type replicons are usually present in its normal plasmidome. In the present study, with the objective to investigate if these plasmids display particularities related to the origin of the isolates bearing them, a total of 153 isolates, including 78 new and 75 previously described, were analyzed for the presence of small plasmids by PCR and DNA restriction fragment profiling. A geographical dichotomy between Canadian and European isolates for their propensity to do not have pAsa3 or pAsal1 was found. In addition, the genotyping analysis led to the identification of two European isolates harboring an unusual pAsal1. An investigation by next-generation sequencing (NGS) of these two isolates shed light on two pAsal1 variants (pAsal1C and pAsal1D). As with pAsal1B, another pAsal1 variant previously described, these two new variants bore a second insertion sequence (ISAS5) in addition to the usual ISAS11. The characterization of these variants suggested that they could predominate over the wild-type pAsal1 in stressful conditions such as growth at temperatures of 25°C and above. To obtain a comprehensive portrait of the mutational pressure on small plasmids, 26 isolates whose DNA had been sequenced by NGS were investigated. pAsa3 and pAsal1 were more prone to mutations than pAsa1 and pAsa2, especially in the mobA gene, which encodes a relaxase and a primase. Lastly, the average copy number of each plasmid per cell was assessed using raw sequencing data. A clear trend with respect to the relative proportion per cell of each plasmid was identified. Our large-scale study revealed a geographical dichotomy in small plasmid repertoire in addition to a clear trend for pAsa3 and pAsal1 to be more frequently altered. Moreover, we present the discovery of two new variants of pAsal1: pAsal1C and pAsal1D

Expansion of the pRAS3 Plasmid Family in Aeromonas salmonicida subsp. salmonicida and Growing Evidence of Interspecies Connections for These Plasmids

Aeromonas salmonicida subsp. salmonicida is a pathogenic bacterium responsible for furunculosis in salmonids. Following an outbreak of furunculosis, the infection can be treated with antibiotics, but it is common to observe ineffective treatment due to antibiotic resistance. This bacterium has a wide variety of plasmids responsible for this resistance. Among them, pRAS3 carries a tetracycline resistance gene. Several variants of this plasmid have been discovered over the years (pRAS3-3432 and pRAS3.1 to 3.4). During the present study, two new variants of the plasmid pRAS3 were identified (pRAS3.5 and pRAS3-3759) in strains of A. salmonicida subsp. salmonicida. Plasmid pRAS3-3759, which has been found in many strains from the same region over the past three years, has an additional genetic element identical to one found in pRAS3-3432. This genetic element was also found in Chlamydia suis, a swine pathogen. In this study, we analyzed the bacteria’s resistance to tetracycline, the number of copies of the plasmids, and the growth of the strains that carry five of the pRAS3 variants (pRAS3.3 to 3.5, pRAS3-3432, and pRAS3-3759). The results show no particular trend despite the differences between the plasmids, except for the resistance to tetracycline when analyzed in an isogenic background. Blast analysis also revealed the presence of pRAS3 plasmids in other bacterial species, which suggests that this plasmid family has widely spread. This study once again highlights the ability of A. salmonicida subsp. salmonicida to adapt to furunculosis antibiotic treatments, and the still-growing family of pRAS3 plasmids

Host Dependent-Transposon for a Plasmid Found in <i>Aeromonas salmonicida</i> subsp. <i>salmonicida</i> That Bears a <i>catB3</i> Gene for Chloramphenicol Resistance

Plasmids that carry antibiotic resistance genes occur frequently in Aeromonas salmonicida subsp. salmonicida, an aquatic pathogen with severe consequences in salmonid farming. Here, we describe a 67 kb plasmid found in the A. salmonicida subsp. salmonicida Strain SHY15-2939 from Quebec, Canada. This new plasmid, named pAsa-2939 and identified by high throughput sequencing, displays features never found before in this bacterial species. It contains a transposon related to the Tn21 family, but with an unusual organization. This transposon bears a catB3 gene (chloramphenicol resistance) that has not been detected yet in A. salmonicida subsp. salmonicida. The plasmid is transferable by conjugation into Aeromonas hydrophila, but not into Escherichia coli. Based on PCR analysis and genomic sequencing (Illumina and PacBio), we determined that the transposon is unstable in A. salmonicida subsp. salmonicida Strain SHY15-2939, but it is stable in A. hydrophila trans-conjugants, which explains the chloramphenicol resistance variability observed in SHY15-2939. These results suggest that this bacterium is likely not the most appropriate host for this plasmid. The presence of pAsa-2939 in A. salmonicida subsp. salmonicida also strengthens the reservoir role of this bacterium for antibiotic resistance genes, even those that resist antibiotics not used in aquaculture in Québec, such as chloramphenicol

Host Dependent-Transposon for a Plasmid Found in Aeromonas salmonicida subsp. salmonicida That Bears a catB3 Gene for Chloramphenicol Resistance

Plasmids that carry antibiotic resistance genes occur frequently in Aeromonas salmonicida subsp. salmonicida, an aquatic pathogen with severe consequences in salmonid farming. Here, we describe a 67 kb plasmid found in the A. salmonicida subsp. salmonicida Strain SHY15-2939 from Quebec, Canada. This new plasmid, named pAsa-2939 and identified by high throughput sequencing, displays features never found before in this bacterial species. It contains a transposon related to the Tn21 family, but with an unusual organization. This transposon bears a catB3 gene (chloramphenicol resistance) that has not been detected yet in A. salmonicida subsp. salmonicida. The plasmid is transferable by conjugation into Aeromonas hydrophila, but not into Escherichia coli. Based on PCR analysis and genomic sequencing (Illumina and PacBio), we determined that the transposon is unstable in A. salmonicida subsp. salmonicida Strain SHY15-2939, but it is stable in A. hydrophila trans-conjugants, which explains the chloramphenicol resistance variability observed in SHY15-2939. These results suggest that this bacterium is likely not the most appropriate host for this plasmid. The presence of pAsa-2939 in A. salmonicida subsp. salmonicida also strengthens the reservoir role of this bacterium for antibiotic resistance genes, even those that resist antibiotics not used in aquaculture in Qu&eacute;bec, such as chloramphenicol