Complete type III secretion system of a mesophilic Aeromonas hydrophila strain

We have investigated the existence and genetic organization of a functional type III secretion system (TTSS) in a mesophilic Aeromonas strain by initially using the Aeromonas hydrophila strain AH-3. We report for the first time the complete TTSS DNA sequence of an Aeromonas strain that comprises 35 genes organized in a similar disposition as that in Pseudomonas aeruginosa. Using several gene probes, we also determined the presence of a TTSS in clinical or environmental strains of different Aeromonas species: A. hydrophila, A. veronii, and A. caviae. By using one of the TTSS genes (ascV), we were able to obtain a defined insertion mutant in strain AH-3 (AH-3AscV), which showed reduced toxicity and virulence in comparison with the wild-type strain. Complementation of the mutant strain with a plasmid vector carrying ascV was fully able to restore the wild-type toxicity and virulence.     

Role of Gne and GalE in the virulence of Aeromonas hydrophila serotype O34

The mesophilic Aeromonas hydrophila AH-3 (serotype O34) strain shows two different UDP-hexose epimerases in its genome: GalE (EC 3.1.5.2) and Gne (EC 3.1.5.7). Similar homologues were detected in the different mesophilic Aeromonas strains tested. GalE shows only UDP-galactose 4-epimerase activity, while Gne is able to perform a dual activity (mainly UDP-N-acetyl galactosamine 4-epimerase and also UDP-galactose 4-epimerase). We studied the activities in vitro of both epimerases and also in vivo through the lipopolysaccharide (LPS) structure of A. hydrophila gne mutants, A. hydrophila galE mutants, A. hydrophila galE-gne double mutants, and independently complemented mutants with both genes. Furthermore, the enzymatic activity in vivo, which renders different LPS structures on the mentioned A. hydrophila mutant strains or the complemented mutants, allowed us to confirm a clear relationship between the virulence of these strains and the presence/absence of the O34 antigen LPS.     

Identification and Characterization of Putative Virulence Genes and Gene Clusters in Aeromonas hydrophila PPD134/91

Aeromonas hydrophila is a gram-negative opportunistic pathogen of animals and humans. The pathogenesis of A. hydrophila is multifactorial. Genomic subtraction and markers of genomic islands (GIs) were used to identify putative virulence genes in A. hydrophila PPD134/91. Two rounds of genomic subtraction led to the identification of 22 unique DNA fragments encoding 19 putative virulence factors and seven new open reading frames, which are commonly present in the eight virulence strains examined. In addition, four GIs were found, including O-antigen, capsule, phage-associated, and type III secretion system (TTSS) gene clusters. These putative virulence genes and gene clusters were positioned on a physical map of A. hydrophila PPD134/91 to determine their genetic organization in this bacterium. Further in vivo study of insertion and deletion mutants showed that the TTSS may be one of the important virulence factors in A. hydrophila pathogenesis. Furthermore, deletions of multiple virulence factors such as S-layer, serine protease, and metalloprotease also increased the 50% lethal dose to the same level as the TTSS mutation (about 1 log) in a blue gourami infection model. This observation sheds light on the multifactorial and concerted nature of pathogenicity in A. hydrophila. The large number of putative virulence genes identified in this study will form the basis for further investigation of this emerging pathogen and help to develop effective vaccines, diagnostics, and novel therapeutics.     

Molecular characterization of clinical isolates of Aeromonas species from Malaysia

Background

Aeromonas species are common inhabitants of aquatic environments giving rise to infections in both fish and humans. Identification of aeromonads to the species level is problematic and complex due to their phenotypic and genotypic heterogeneity.

Methodology/Principal Findings

Aeromonas hydrophila or Aeromonas sp were genetically re-identified using a combination of previously published methods targeting GCAT, 16S rDNA and rpoD genes. Characterization based on the genus specific GCAT-PCR showed that 94 (96%) of the 98 strains belonged to the genus Aeromonas. Considering the patterns obtained for the 94 isolates with the 16S rDNA-RFLP identification method, 3 clusters were recognised, i.e. A. caviae (61%), A. hydrophila (17%) and an unknown group (22%) with atypical RFLP restriction patterns. However, the phylogenetic tree constructed with the obtained rpoD sequences showed that 47 strains (50%) clustered with the sequence of the type strain of A. aquariorum, 18 (19%) with A. caviae, 16 (17%) with A. hydrophila, 12 (13%) with A. veronii and one strain (1%) with the type strain of A. trota. PCR investigation revealed the presence of 10 virulence genes in the 94 isolates as: lip (91%), exu (87%), ela (86%), alt (79%), ser (77%), fla (74%), aer (72%), act (43%), aexT (24%) and ast (23%).

Conclusions/Significance

This study emphasizes the importance of using more than one method for the correct identification of Aeromonas strains. The sequences of the rpoD gene enabled the unambiguous identication of the 94 Aeromonas isolates in accordance with results of other recent studies. Aeromonas aquariorum showed to be the most prevalent species (50%) containing an important subset of virulence genes lip/alt/ser/fla/aer. Different combinations of the virulence genes present in the isolates indicate their probable role in the pathogenesis of Aeromonas infections.     

A molecular study on the prevalence and virulence potential of Aeromonas spp. recovered from patients suffering from diarrhea in Israel

Background

Species of the genus Aeromonas are native inhabitants of aquatic environments and have recently been considered emerging human pathogens. Although the gastrointestinal tract is by far the most common anatomic site from which aeromonads are recovered, their role as etiologic agents of bacterial diarrhea is still disputed. Aeromonas-associated diarrhea is a phenomenon occurring worldwide; however, the exact prevalence of Aeromonas infections on a global scale is unknown.

Methodology/Principal Findings

The prevalence and virulence potential of Aeromonas in patients suffering from diarrhea in Israel was studied using molecular methods. 1,033 diarrheal stools were sampled between April and September 2010 and Aeromonas species were identified in 17 (∼2%) patients by sequencing the rpoD gene. Aeromonas species identity and abundance was: A. caviae (65%), A. veronii (29%) and Aeromonas taiwanensis (6%). This is the first clinical record of A. taiwanensis as a diarrheal causative since its recent discovery from a wound infection in a patient in Taiwan. Most of the patients (77%) from which Aeromonas species were isolated were negative for any other pathogens. The patients ranged from 1 to 92 years in age. Aeromonas isolates were found to possess different virulence-associated genes: ahpB (88%), pla/lip/lipH3/apl-1 (71%), act/hlyA/aerA (35%), alt (18%), ast (6%), fla (65%), lafA (41%), TTSS ascV (12%), TTSS ascF-ascG (12%), TTSS-dependent ADP-ribosylating toxins aexU (41%) and aexT (6%) in various combinations. Most of the identified strains were resistant to beta-lactam antibiotics but susceptible to third-generation cephalosporin antibiotics.

Conclusions

Aeromonas may be a causative agent of diarrhea in patients in Israel and therefore should be included in routine bacteriological screenings.     

Phenotypic and Genetic Diversity of Aeromonas Species Isolated from Fresh Water Lakes in Malaysia

Gram-negative bacilli of the genus Aeromonas are primarily inhabitants of the aquatic environment. Humans acquire this organism from a wide range of food and water sources as well as during aquatic recreational activities. In the present study, the diversity and distribution of Aeromonas species from freshwater lakes in Malaysia was investigated using glycerophospholipid-cholesterol acyltransferase (GCAT) and RNA polymerase sigma-factor (rpoD) genes for speciation. A total of 122 possible Aeromonas strains were isolated and confirmed to genus level using the API20E system. The clonality of the isolates was investigated using ERIC-PCR and 20 duplicate isolates were excluded from the study. The specific GCAT-PCR identified all isolates as belonging to the genus Aeromonas, in agreement with the biochemical identification. A phylogenetic tree was constructed using the rpoD gene sequence and all 102 isolates were identified as: A. veronii 43%, A. jandaei 37%, A. hydrophila 6%, A. caviae 4%, A. salmonicida 2%, A. media 2%, A. allosaccharophila 1%, A. dhakensis 1% and Aeromonas spp. 4%. Twelve virulence genes were present in the following proportions—exu 96%, ser 93%, aer 87%, fla 83%, enolase 70%, ela 62%, act 54%, aexT 33%, lip 16%, dam 16%, alt 8% and ast 4%, and at least 2 of these genes were present in all 102 strains. The ascV, aexU and hlyA genes were not detected among the isolates. A. hydrophila was the main species containing virulence genes alt and ast either present alone or in combination. It is possible that different mechanisms may be used by each genospecies to demonstrate virulence. In summary, with the use of GCAT and rpoD genes, unambiguous identification of Aeromonas species is possible and provides valuable data on the phylogenetic diversity of the organism.     

Analysis of the interaction of Aeromonas caviae, A. hydrophila and A. sobria with mucins

Aeromonas species are known to be involved in human gastrointestinal diseases. These organisms colonize the gastrointestinal tract. Aeromonas hydrophila, A. caviae, and A. sobria have been demonstrated microscopically to adhere to animal cell lines that express mucous receptors, but quantitative studies of adherence to mucosal components such as mucin have not been published to date. Purified bovine submaxillary gland, hog gastric mucin, and fish skin mucin were used as a model to study mucin-binding activity among A. caviae, A. hydrophila, and A. sobria strains. Our findings revealed that binding of radiolabeled and enzyme-conjugated mucins to Aeromonas cells varied depending on the labeling procedure. The highest binding was observed when the three mucin preparations were labeled with horseradish peroxidase. Binding of the various horseradish peroxidase-labeled mucins by A. caviae, A. hydrophila, and A. sobria cells is a common property among Aeromonas species isolated from human infections, diseased fish, and from environmental sources. The proportion of Aeromonas strains which bind the various horseradish peroxidase-labeled mucins was significantly higher for A. hydrophila than for A. caviae and A. sobria. Bacterial cell-surface extracts containing active mucin-binding components recognized the horseradish peroxidase-labeled mucins. The molecular masses of the mucin-binding proteins were estimated by SDS-PAGE and Western blot as follows: A. caviae strain A4812 (95 and 44 kDa); A. hydrophila strain 48748 (97, 45, 33 and 22 kDa); and A. sobria strain 48739 (95 and 43 kDa). Mucin interaction with Aeromonas cells was also studied in terms of growth in mucin-rich media. The culture conditions greatly influence the expression of A. hydrophila mucin-binding activity.     

Suicide Plasmid-Dependent IS1-Element Untargeted Integration into Aeromonas veronii bv. sobria Generates Brown Pigment-Producing and Spontaneous Pelleting Mutant

Foodborne Gram-negative pathogens belonging to the genus Aeromonas are variable in harboring insertion sequence (IS) elements that play an important role in the generation of dysfunctional relatives of known genes. Using suicide plasmids carrying an IS1-element, untargeted integration is a common problem during experimental trials to generate specific mutations by homologous recombination. In this work, different strains of Aeromonas veronii bv. sobria (AeG1 and ATCC 9071T), A. hydrophila ATCC 19570, and A. sobria ATCC 43979T are examined for acquisition of IS1-element from pYAK1 suicide plasmid. It was found that untargeted integration of IS1-element is encountered only in ATCC 9071T strain. Such untargeted integration generates a novel brown pigment-producing and spontaneous pelleting (BP⁺SP⁺) mutant. Furthermore, BP⁺SP⁺ mutant strain secretes significantly higher quantity of PilF homologous protein than the wild-type strain and displays an enhanced protein tyrosine phosphorylation activity. Thus, current work shows that Aeromonas spp. strains are variable in their susceptibility for suicide plasmid-dependent IS1-element untargeted integration as well as the susceptible strain is changed to mimic pigment-producing and spontaneous pelleting strains that are naturally occurring among heterogeneous group of foodborne aeromonads.     

Sequence Analysis of Amplified DNA Fragments Containing the Region Encoding the Putative Lipase Substrate-Binding Domain and Genotyping of Aeromonas hydrophila

DNA fragments were amplified by PCR from all tested strains of Aeromonas hydrophila, A. caviae, and A. sobria with primers designed based on sequence alignment of all lipase, phospholipase C, and phospholipase A1 genes and the cytotonic enterotoxin gene, all of which have been reported to have the consensus region of the putative lipase substrate-binding domain. All strains showed lipase activity, and all amplified DNA fragments contained a nucleotide sequence corresponding to the substrate-binding domain. Thirty-five distinct nucleotide sequence patterns and 15 distinct deduced amino acid sequence patterns were found in the amplified DNA fragments from 59 A. hydrophila strains. The deduced amino acid sequences of the amplified DNA fragments from A. caviae and A. sobria strains had distinctive amino acids, suggesting a species-specific sequence in each organism. Furthermore, the amino acid sequence patterns appear to differ between clinical and environmental isolates among A. hydrophila strains. Some strains whose nucleotide sequences were identical to one another in the amplified region showed an identical DNA fingerprinting pattern by repetitive extragenic palindromic sequence-PCR genotyping. These results suggest that A. hydrophila, and also A. caviae and A. sobria strains, have a gene encoding a protein with lipase activity. Homologs of the gene appear to be widely distributed in Aeromonas strains, probably associating with the evolutionary genetic difference between clinical and environmental isolates of A. hydrophila. Additionally, the distinctive nucleotide sequences of the genes could be attributed to the genotype of each strain, suggesting that their analysis may be helpful in elucidating the genetic heterogeneity of Aeromonas.     

<Emphasis Type="Italic">Aeromonas</Emphasis> and <Emphasis Type="Italic">Plesiomonas</Emphasis> species from scarlet ibis (<Emphasis Type="Italic">Eudocimus ruber</Emphasis>) and their environment: monitoring antimicrobial susceptibility and virulence

The present study aimed at evaluating the role of captive scarlet ibises (Eudocimus ruber) and their environment as reservoirs of Aeromonas spp. and Plesiomonas spp., and analyzing the in vitro antimicrobial susceptibility and virulence of the recovered bacterial isolates. Thus, non-lactose and weak-lactose fermenting, oxidase positive Gram-negative bacilli were recovered from cloacal samples (n = 30) of scarlet ibises kept in a conservational facility and from water samples (n = 30) from their environment. Then, the antimicrobial susceptibility, hemolytic activity and biofilm production of the recovered Aeromonas spp. and Plesiomonas shigelloides strains were assessed. In addition, the virulence-associated genes of Aeromonas spp. were detected. Ten Aeromonas veronii bv. sobria, 2 Aeromonas hydrophila complex and 10 P. shigelloides were recovered. Intermediate susceptibility to piperacillin-tazobactam and cefepime was observed in 2 Aeromonas spp. and 1 P. shigelloides, respectively, and resistance to gentamicin was observed in 4 P. shigelloides. The automated susceptibility analysis revealed resistance to piperacillin-tazobactam and meropenem among Aeromonas spp. and intermediate susceptibility to gentamicin among P. shigelloides. All Aeromonas isolates presented hemolytic activity, while 3 P. shigelloides were non-hemolytic. All Aeromonas spp. and 3/10 P. shigelloides were biofilm-producers, at 28 °C, while 10 Aeromonas spp. and 6/10 P. shigelloides produced biofilms, at 37 °C. The most prevalent virulence genes of Aeromonas spp. were asa1 and ascV. Scarlet ibises and their environment harbour potentially pathogenic bacteria, thus requiring monitoring and measures to prevent contamination of humans and other animals.     

Distribution of Virulence Factors and Molecular Fingerprinting of Aeromonas Species Isolates from Water and Clinical Samples: Suggestive Evidence of Water-to-Human Transmission

A total of 227 isolates of Aeromonas obtained from different geographical locations in the United States and different parts of the world, including 28 reference strains, were analyzed to determine the presence of various virulence factors. These isolates were also fingerprinted using biochemical identification and pulse-field gel electrophoresis (PFGE). Of these 227 isolates, 199 that were collected from water and clinical samples belonged to three major groups or complexes, namely, the A. hydrophila group, the A. caviae-A. media group, and the A. veronii-A. sobria group, based on biochemical profiles, and they had various pulsotypes. When virulence factor activities were examined, Aeromonas isolates obtained from clinical sources had higher cytotoxic activities than isolates obtained from water sources for all three Aeromonas species groups. Likewise, the production of quorum-sensing signaling molecules, such as N-acyl homoserine lactone, was greater in clinical isolates than in isolates from water for the A. caviae-A. media and A. hydrophila groups. Based on colony blot DNA hybridization, the heat-labile cytotonic enterotoxin gene and the DNA adenosine methyltransferase gene were more prevalent in clinical isolates than in water isolates for all three Aeromonas groups. Using colony blot DNA hybridization and PFGE, we obtained three sets of water and clinical isolates that had the same virulence signature and had indistinguishable PFGE patterns. In addition, all of these isolates belonged to the A. caviae-A. media group. The findings of the present study provide the first suggestive evidence of successful colonization and infection by particular strains of certain Aeromonas species after transmission from water to humans.Aeromonas species cause both intestinal and extraintestinal infections (25, 33, 78), and the latter include septicemia, cellulitis, wound infections, urinary tract infections, hepatobiliary tract infections, soft tissue infections, and, occasionally, meningitis and peritonitis (25, 30, 78). In immunocompromised children, these pathogens can cause even more severe forms of infections, such as hemolytic-uremic syndrome (HUS) and necrotizing fasciitis (3, 23), although detailed studies are needed to establish such associations. Worldwide, the rate of isolation of Aeromonas from diarrheic stools has been reported to be as high as 10.8%, compared to 2.1% for healthy controls (25, 37, 78). An increased rate of isolation of Aeromonas species was reported in flood water samples during Hurricane Katrina in New Orleans (58), and skin and soft tissue infections caused by Aeromonas species were among the most common infections in the survivors of the 2004 tsunami in southern Thailand (28). In particular, Aeromonas salmonicida causes fish infections that result in huge economical losses in the fishing industry (6, 22). The ability of aeromonads, as well as other bacteria, to survive in chlorinated water when they are in biofilms and their resistance to multiple antibiotics are major public health concerns (46).Aeromonas-related gastroenteritis remains somewhat controversial (24, 36). There have been a number of well-described cases and a few documented outbreaks, but whether all aeromonad fecal isolates from symptomatic persons are the actual causes of diarrheal disease is still questionable. One theory for this conundrum was posed in 2000 by two of us, who suggested that only specific subsets of Aeromonas strains within and between species are actually pathogenic for humans (38). This highlights the importance of developing accurate biotyping, molecular fingerprinting, and virulence factor analysis methods for differentiating environmental and clinical aeromonads from one another and for comparing them (38).Of the 19 currently recognized Aeromonas species, A. hydrophila, A. caviae, and A. veronii biovar sobria are the most common species known to cause the majority of human infections, and they account for more than 85% of all clinical isolates (34). The pathogenesis of Aeromonas infections is multifactorial, as aeromonads produce a wide variety of virulence factors, including hemolysins, cytotonic and cytotoxic enterotoxins, proteases, lipases, leucocidins, endotoxin, adhesions, and an S layer, that act in concert to cause disease in the host (12-14, 50, 51). The cytotoxic enterotoxin Act, which has some similarities to aerolysin (31), is one of the most significant virulence factors in diarrheal isolate SSU of A. hydrophila and was first characterized in our laboratory (12). Act is secreted by the type II secretion system (T2SS) and has hemolytic, cytotoxic, and enterotoxic activities (12). In addition, our laboratory recently sequenced and characterized two other secretion systems, T3SS and T6SS, that were found to contribute to the virulence of A. hydrophila SSU (66, 67, 72). We recently characterized an effector of the T3SS, which was designated AexU, and found that it was associated with ADP ribosylation of host cell proteins, a rounded phenotype in HeLa cells, inhibition of phagocytosis, induction of apoptosis, and mouse mortality (66, 67). In recent studies, we also investigated the role of two T6SS-associated effectors, the valine-glycine repeat G (VgrG) family of proteins and hemolysin-coregulated protein (Hcp), in the virulence of A. hydrophila (71, 72). We demonstrated that VgrG1 of A. hydrophila had actin-ADP ribosylation activity that induced host cell cytotoxicity (71). Based on the model for T6SS, the VgrG1 protein must assemble with the highly homologous VgrG2 and VgrG3 proteins to form a cell-puncturing device to deliver effector proteins into the host cells (59). We also obtained evidence that expression of the hcp gene in HeLa cells led to their apoptosis, and animals immunized with recombinant Hcp were protected from subsequent challenge with a lethal dose of wild-type A. hydrophila SSU (72).In addition, cytotonic enterotoxins (e.g., Alt [heat labile] and Ast [heat stable]) were identified in a diarrheal A. hydrophila SSU isolate (14, 63) that induced fluid secretion in the ligated small intestinal loops of animals (47). More recently, we identified some additional virulence factor-encoding and regulatory genes, such as the enolase, hlyA (hemolysin), gidA (glucose-inhibited division A), vacB (virulence-associated protein B), dam (DNA adenine methyltransferase), and tagA (ToxR-regulated lipoprotein) genes, which modulated the virulence of A. hydrophila SSU (19-21, 57, 62, 64). The production of such a wide array of virulence factors by Aeromonas species is indicative of their potential to cause severe diseases in humans. These virulence factor-encoding genes might be differentially expressed in Aeromonas species depending on the environmental conditions, such as water or the human host.A cell-to-cell signaling system, known as quorum sensing (QS), might play an important role in sensing physiological conditions and helping bacteria express the virulence genes at an appropriate time under the appropriate conditions. Thus far, at least three QS circuits have been identified in Gram-negative bacteria, and they were designated LuxRI (autoinducer 1 [AI-1]), LuxS (AI-2), and AI-3 (epinephrine/norepinephrine). All of these QS systems were detected in our SSU clinical strain of A. hydrophila, and we recently demonstrated that N-acyl homoserine lactone (AHL) (AI-1) and AI-2-mediated QS controlled the virulence of A. hydrophila SSU (40, 43). Further, we observed decreased production of N-acyl homoserine lactones when we deleted two major virulence factor-encoding genes, the act gene and the gene encoding an outer membrane protein (aopB), an important component of the T3SS (65), from A. hydrophila SSU. Likewise, we observed that N-acyl homoserine lactone production was also modulated by regulatory genes, such as dam and gidA, in A. hydrophila SSU (18). Thus, differential expression of genes might also be an important factor in the pathogenesis of Aeromonas species.The presence of any virulence gene in strains of Aeromonas isolated from water should be carefully scrutinized, as such genes could be expressed better in a human host, which could lead to devastating outcomes. In addition, it is possible that in the environment certain Aeromonas clones may predominate and cause human diseases more frequently than other clones. Thus, it is important to determine the clonal variation of a range of Aeromonas species isolated from various sources and identify predominant clones by a polyphasic approach that includes biochemical phenotyping, virulence marker detection, and molecular fingerprinting techniques.In the present study, we compared 199 Aeromonas isolates, 146 of which were from water sources and 53 of which were from human patients with diarrhea in the Unites States. In addition, 28 reference and classical strains that were obtained from various culture collections and/or were isolated from specimens obtained in diverse geographical areas of the world, including water and clinical specimens, were also characterized. All isolates were biochemically identified to the phenospecies group level, examined for the presence of a set of 11 virulence factors by using DNA colony blot hybridization, and fingerprinted by using pulsed-field gel electrophoresis (PFGE). Some of the virulence factors selected, including T6SS effectors, were also examined by using functional assays. Our data provide the first suggestive evidence of water-to-human transmission, i.e., of successful colonization and infection by particular strains of certain Aeromonas species.     

Aeromonas hydrophila and Aeromonas veronii Predominate among Potentially Pathogenic Ciprofloxacin- and Tetracycline-Resistant Aeromonas Isolates from Lake Erie

Members of the genus Aeromonas are ubiquitous in nature and have increasingly been implicated in numerous diseases of humans and other animal taxa. Although some species of aeromonads are human pathogens, their presence, density, and relative abundance are rarely considered in assessing water quality. The objectives of this study were to identify Aeromonas species within Lake Erie, determine their antibiotic resistance patterns, and assess their potential pathogenicity. Aeromonas strains were isolated from Lake Erie water by use of Aeromonas selective agar with and without tetracycline and ciprofloxacin. All isolates were analyzed for hemolytic ability and cytotoxicity against human epithelial cells and were identified to the species level by using 16S rRNA gene restriction fragment length polymorphisms and phylogenetic analysis based on gyrB gene sequences. A molecular virulence profile was identified for each isolate, using multiplex PCR analysis of six virulence genes. We demonstrated that Aeromonas comprised 16% of all culturable bacteria from Lake Erie. Among 119 Aeromonas isolates, six species were identified, though only two species (Aeromonas hydrophila and A. veronii) predominated among tetracycline- and ciprofloxacin-resistant isolates. Additionally, both of these species demonstrated pathogenic phenotypes in vitro. Virulence gene profiles demonstrated a high prevalence of aerolysin and serine protease genes among A. hydrophila and A. veronii isolates, a genetic profile which corresponded with pathogenic phenotypes. Together, our findings demonstrate increased antibiotic resistance among potentially pathogenic strains of aeromonads, illustrating an emerging potential health concern.     

Genomic study of polyhydroxyalkanoates producing Aeromonas hydrophila 4AK4

The complete genome of Gram-negative Aeromonas hydrophila 4AK4 that has been used for industrial production of poly(3-hydroxybutyrate-co-3-hydroxyhexanoate) was sequenced and annotated. Its chromosome is 4,527,993 bp in size encoding 4,272 genes, including 28 rRNA genes and 104 tRNA genes. Comparative analysis indicated that genome of A. hydrophila 4AK4 was similar to that of the A. hydrophila ATCC 7966^T, an intensively studied aeromonad for its pathogenicity related to its genomic information. Genes possibly coming from other species or even other genus were identified in A. hydrophila 4AK4. A large number of putative virulent genes were predicted. However, a cytotonic enterotoxin (Ast) is absent in A. hydrophila 4AK4, allowing the industrial strain to be different from other A. hydrophila strains, indicating possible reduced virulence of strain 4AK4, which is very important for industrial fermentation. Genes involved in polyhydroxyalkanoate (PHA) metabolism were predicted and analyzed. The resulting genomic information is useful for improved production of PHA via metabolic engineering of A. hydrophila 4AK4.     

Interaction of Aeromonas Strains with Lactic Acid Bacteria via Caco-2 Cells

The genus Aeromonas includes some species that have now been identified as human pathogens of significant medical importance. We investigated the ability of 13 selected Aeromonas strains belonging to nine species isolated from clinical cases (n = 5), environmental waters (n = 5), and fish (n = 3) to adhere to and translocate Caco-2 cells in the absence and presence of two lactic acid bacteria (LAB), i.e., Lactobacillus acidophilus and Bifidobacterium breve. Aeromonas isolates were also assessed for their cytotoxicity, the presence of virulence genes, and hemolysin production. Among the clinical isolates, one strain of Aeromonas veronii biovar veronii and two strains of Aeromonas hydrophila carried cytotoxin (act), heat-labile toxin (alt), hemolysin (hlyA), and aerolysin (aerA) genes, were cytotoxic to Vero cells, produced hemolysin, and showed higher adherence to Caco-2 cells. In contrast, this was seen in only one environmental strain, a strain of A. veronii biovar sobria. When Aeromonas strains were coinoculated with LAB onto Caco-2 cells, their level of adhesion was reduced. However, their rate of translocation in the presence of LAB increased and was significantly (P < 0.05) higher among fish strains. We suggest that either the interaction between Aeromonas and LAB strains could have a detrimental effect on the Caco-2 cells, allowing the Aeromonas to translocate more readily, or the presence of the LAB stimulated the Aeromonas strains to produce more toxins and/or increase their translocation rate.     

Virulence Diversity among Bacteremic Aeromonas Isolates: Ex Vivo,Animal, and Clinical Evidences

Background

The objective of this study was to compare virulence among different Aeromonas species causing bloodstream infections.

Methodology/Principal Findings

Nine of four species of Aeromonas blood isolates, including A. dhakensis, A. hydrophila, A. veronii and A. caviae were randomly selected for analysis. The species was identified by the DNA sequence matching of rpoD. Clinically, the patients with A. dhakensis bacteremia had a higher sepsis-related mortality rate than those with other species (37.5% vs. 0%, P = 0.028). Virulence of different Aeromonas species were tested in C. elegans, mouse fibroblast C2C12 cell line and BALB/c mice models. C. elegans fed with A. dhakensis and A. caviae had the lowest and highest survival rates compared with other species, respectively (all P values <0.0001). A. dhakensis isolates also exhibited more cytotoxicity in C2C12 cell line (all P values <0.0001). Fourteen-day survival rate of mice intramuscularly inoculated with A. dhakensis was lower than that of other species (all P values <0.0001). Hemolytic activity and several virulence factor genes were rarely detected in the A. caviae isolates.

Conclusions/Significance

Clinical data, ex vivo experiments, and animal studies suggest there is virulence variation among clinically important Aeromonas species.     

Comparison of phenotypical and genetic identification of Aeromonas strains isolated from diseased fish

Phenotypicaly identified Aeromonas strains (n=119) recovered mainly from diseased fish were genetically re-identified and the concordance between the results was analysed. Molecular characterization based on the GCAT genus specific gene showed that only 90 (75.6%) strains belonged to the genus Aeromonas. The 16S rDNA-RFLP method identified correctly most of the strains with the exception of a few that belonged to A. bestiarum, A. salmonicida or A. piscicola. Separation of these 3 species was correctly assessed with the rpoD gene sequences, which revealed that 5 strains with the RFLP pattern of A. salmonicida belonged to A. piscicola, as did 1 strain with the pattern of A. bestiarum. Correct phenotypic identification occurred in only 32 (35.5%) of the 90 strains. Only 14 (21.8%) of the 64 phenotypically identified A. hydrophila strains belonged to this species. However, coincident results were obtained in 88% (15/17) of the genetically identified A. salmonicida strains. Phenotypic tests were re-evaluated on the 90 genetically characterized Aeromonas strains and there were contradictions in the species A. sobria for a number of previously published species-specific traits. After genetic identification, the prevailing species were A. sobria, A. salmonicida, A. bestiarum, A. hydrophila, A. piscicola and A. media but we could also identify a new isolate of the recently described species A. tecta. This work emphasizes the need to rely on the 16S rDNA-RFLP method and sequencing of housekeeping genes such as rpoD for the correct identification of Aeromonas strains.     

Aeromonas piscicola sp. nov., isolated from diseased fish

Four Aeromonas strains (S1.2^T, EO-0505, TC1 and TI 1.1) isolated from moribund fish in Spain showed a restriction fragment length polymorphism (RFLP) pattern related to strains of Aeromonas salmonicida and Aeromonas bestiarum but their specific taxonomic position was unclear. Multilocus sequence analysis (MLSA) of housekeeping genes rpoD, gyrB, recA and dnaJ confirmed the allocation of these isolates to an unknown genetic lineage within the genus Aeromonas with A. salmonicida, A. bestiarum and Aeromonas popoffii as the phylogenetically nearest neighbours. Furthermore, a strain biochemically labelled as Aeromonas hydrophila (AH-3), showing a pattern of A. bestiarum based on 16S rDNA-RFLP, also clustered with the unknown genetic lineage. The genes rpoD and gyrB proved to be the best phylogenetic markers for differentiating these isolates from their neighbouring species. Useful phenotypic features for differentiating the novel species from other known Aeromonas species included their ability to hydrolyze elastin, produce acid from l-arabinose and salicin, and their inability to produce acid from lactose and use l-lactate as a sole carbon source. A polyphasic approach using phenotypic characterization, phylogenetic analysis of the 16S rRNA gene and of four housekeeping genes, as well as DNA–DNA hybridization studies and an analysis of the protein profiles by MALDI-TOF-MS, showed that these strains represented a novel species for which the name Aeromonas piscicola sp. nov. is proposed with isolate S1.2^T (=CECT 7443^T, =LMG 24783^T) as the type strain.     

Phenotypic variation and morphological changes in starved denitrifying Aeromonas hydrophila

In this study, an Aeromonas hydrophila identified as a denitrifying bacterium by PCR detection of nitrate reductase (narG) and nitrite reductase (nirK) genes was incubated in seawater microcosms for 8 months at room temperature and at 4 °C. A study of the phenotypic variation demonstrated that A. hydrophila becomes gelatinase-positive after the incubation in sea water. We noted that starved A. hydrophila becomes unable to produce leucine arylamidase, and that the starved strain appears to grow more slowly. Indeed, we also observed a severe decrease in cellular aggregation of Aeromonas after incubation. In addition, atomic force micrographs revealed a reduction in cell size.     

Biochemical characteristics and genetic diversity of <Emphasis Type="Italic">Vibrio</Emphasis> spp. and <Emphasis Type="Italic">Aeromonas hydrophila</Emphasis> strains isolated from the Lac of Bizerte (Tunisia)

This study characterized the phenotypic and genetic properties of Vibrio spp. and Aeromonas hydrophila strains isolated from seawater and mussels (Mytilus edulis and Crassostrea gigas) cultured in mollusc farm localized in the lac of Bizerte. The 37 strains (31 strains of V. alginolyticus, one strain of V. fluvialis, one strain of V. parahaemolyticus and four strains of A. hydrophila) typed by enterobacterial repetitive intergenic consensus PCR (ERIC-PCR) showed a high polymorphism. Most of the isolates were resistant to at least two antimicrobial agents. All the tested strains were resistant to ampicillin. PCR was used to detect the presence of eight Vibrio cholerae virulence genes in the genome of the Vibrio spp. isolates. The results showed a wide dissemination of these genes in the genome of all Vibrio spp. isolates tested. Differentiation of these strains with the ERIC 2-PCR technique revealed no association between the presence of virulence genes and a particular fingerprinting pattern.