Intra- and inter-species interactions within biofilms of important foodborne bacterial pathogens

Giaouris, Efstathios; Heir, Even; Desvaux, Mickaël; Hébraud, Michel; Møretrø, Trond; Langsrud, Solveig; Doulgeraki, Agapi I.; Nychas, George‐John E.; Kačániová, Miroslava; Czaczyk, Katarzyna; Ölmez, Hülya; Simões, Manuel

doi:10.3389/fmicb.2015.00841

Cited by 261 publications

(192 citation statements)

References 378 publications

(456 reference statements)

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“…Interaction with the Microbiome In many microbial systems, the relevant unit for many functions is neither a clone nor population but consortia living in close symbiotic association [54,55]. These microbiota fulfill a range of different functions, with defense against pathogens being among the most prominent in humans [56,57] and corals [58], but also oysters [59].…”

Section: Incorporating Higher Order Interactionsmentioning

confidence: 99%

Oysters and Vibrios as a Model for Disease Dynamics in Wild Animals

Roux

Wegner

Polz

2016

Trends in Microbiology

118

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Disease dynamics in the wild are influenced by a number of ecological and evolutionary factors not addressed by traditional laboratory-based characterization of pathogens. Here we propose the oyster, Crassostrea gigas, as a model for studying the interaction of the environment, bacterial pathogens, and the host in disease dynamics. We show that an important first step is to ask whether the functional unit of pathogenesis is a bacterial clone, a population, or a consortium in order to assess triggers of disease outbreaks and devise appropriate monitoring tools. Moreover, the development of specific-pathogen-free (SPF) oysters has enabled assessment of the infection process under natural conditions. Finally, recent results show the importance of microbial interactions and host genetics in determining oyster health and disease. Involvement of Vibrios in Oyster DiseaseVibrios are ubiquitous marine bacteria that are ecologically and metabolically diverse members of planktonic and animal-associated microbial communities [1,2]. They have been called 'opportuni-trophs ' [3] due to their high metabolic versatility and genetic variability coupled with chemotaxis and quorum sensing (see Glossary), all of which allow high colonization potential [4,5]. Vibrios encompass the ancient and well-studied human pathogen, Vibrio cholerae, as well as some less thoroughly characterized opportunistic pathogens capable of infecting humans, including Vibrio parahaemolyticus and Vibrio vulnificus [2]. Even less well understood are the consequences of Vibrio infections in other animals, including fish, coral, shrimp, and mollusks; however, infections in these organisms can have important environmental and economic consequences [6]. In particular, vibrios have been suggested to be responsible for repeated mortality outbreaks in oyster beds (Crassostrea gigas) in France that have resulted in losses of up to 80-100% of production (Box 1). However the onset and progression of disease in the wild has been difficult to follow in the past. Hence, it is often not clear whether vibrios isolated from diseased oysters are the causative agent, secondary opportunistic colonizers, or commensals [7].Vibrios appear to employ a diversity of molecular mechanisms to infect oysters, albeit our knowledge is based mainly on very few model strains. For example, infection with Vibrio tasmaniensis LGP32 [8] involves an intracellular phase in hemocytes, which are the oyster's immune-competent cells, and resistance to (i) antimicrobial peptides (AMPs), (ii) reactive oxygen species (ROS) and (iii) copper [9][10][11][12]. Vibrio aestuarianus, by [ 1 5 _ T D $ D I F F ] contrast, interacts with hemocytes extracellularly and inhibits their phagocytotic abilities [13,14]. A common theme, however, is that metalloproteases have been linked to toxicity in V. tasmaniensis, V. aestuarianus, Vibrio corallilyticus, and Vibrio tubiashi [13,15,16]. Nonetheless, the disruption of TrendsKnowledge of the genetic structure of the Vibrio population provides a framework for mapping d...

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Section: Incorporating Higher Order Interactionsmentioning

confidence: 99%

Oysters and Vibrios as a Model for Disease Dynamics in Wild Animals

Roux

Wegner

Polz

2016

Trends in Microbiology

118

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“…Therefore, most studies on biofilms are conducted using either bacteria collected from environmental biofilms or laboratory strains in laboratory models (Giaouris et al 2015). Biofilms produced at the laboratory are more or less relevant for the environments they are meant to mimic with respect to a range of factors such as materials, microbiota, temperatures, nutrients, sanitation regimes, and the dynamics for all these factors.…”

Section: Introductionmentioning

confidence: 99%

Microbiota formed on attached stainless steel coupons correlates with the natural biofilm of the sink surface in domestic kitchens

et al. 2016

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Stainless steel coupons are frequently used in biofilm studies in the laboratory, as this material is commonly used in the food industry. The coupons are attached to different surfaces to create a "natural" biofilm to be studied further in laboratory trials. However, little has been done to investigate how well the microbiota on such coupons represents the surrounding environment. The microbiota on sink wall surfaces and on new stainless steel coupons attached to the sink wall for 3 months in 8 domestic kitchen sinks was investigated by nextgeneration sequencing (MiSeq) of the 16S rRNA gene derived from DNA and RNA (cDNA), and by plating and identification of colonies. The mean number of colony-forming units was about 10-fold higher for coupons than sink surfaces, and more variation in bacterial counts between kitchens was seen on sink surfaces than coupons. The microbiota in the majority of biofilms was dominated by Moraxellaceae (genus Moraxella/Enhydrobacter) and Micrococcaceae (genus Kocuria). The results demonstrated that the variation in the microbiota was mainly due to differences between kitchens (38.2%), followed by the different nucleic acid template (DNA vs RNA) (10.8%), and that only 5.1% of the variation was a result of differences between coupons and sink surfaces. The microbiota variation between sink surfaces and coupons was smaller for samples based on their RNA than on their DNA. Overall, our results suggest that new stainless steel coupons are suited to model the dominating part of the natural microbiota of the surrounding environment and, furthermore, are suitable for different downstream studies.Key words: microbiota, stainless steel coupons, sink surface, domestic kitchens. Résumé :Les études sur les biofilms utilisent couramment des coupons en acier inoxydable en laboratoire puisque ce matériau est répandu dans l'industrie alimentaire. Ces coupons sont attachés à diverses surfaces afin de créer un biofilm « naturel » aux fins d'études plus approfondies en laboratoire. Or, on s'est peu demandé à quel point la microflore retrouvée sur de tels coupons est représentative de l'environnement avoisinant. On a examiné la microflore de nouveaux coupons d'acier inoxydable attachés à la paroi de l'évier pendant trois mois, ainsi que celle des parois de l'évier comme telles, au moyen du séquençage de prochaine génération (MiSeq) du gène de l'ARNr 16S issu d'ADN et d'ARN (ADNc), et par ensemencement et identification des colonies. Le nombre moyen d'unités formant colonies était environ 10 fois plus élevé sur les coupons que sur les surfaces de l'évier, et on a observé davantage de variations des numérations bactériennes selon les cuisines dans le contexte des surfaces d'éviers que des coupons. La microflore de la majorité des biofilms était dominée par les Moraxellaceae (genre Moraxella/ Enhydrobacter) et les Micrococcaceae (genre Kocuria). Les résultats ont démontré que la variation de la microflore était principalement attribuable aux différences entre les cuisines (38,2 %), suivie par les ...

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“…According to the literature, 80-90% of hospital biofilms-related infections involve this species [12]. S. aureus is part of the human skin microbiota and becomes opportunistic in host immunosuppression situations, when it expresses its pathogenicity [13]. This species may colonize the surface of different medical devices such as implants, catheters, syringes, prostheses and artificial valves [14].…”

Section: Introductionmentioning

confidence: 99%

Biofilm: An Important Bacterial Feature Still to Deal With

Novais

Abreu

Castro

2016

Journal of Life Sciences Research

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Currently, the bacterial infections are one of the main causes of death worldwide and a public health problem for most governments. In this scenario, virulence factors are of importance, including the capacity of forming biofilm. The ability of producing biofilms is directly involved in bacterial pathogenicity and hugely worse the risk of death due to a bacterial infection. This feature allows the bacteria to colonize different surfaces (e.g. Medical devices), and causes several complications, especially in nosocomial infections. This work reviewed biolfim producing mechanisms, the relation with resistance process and the problems associated to biofilms-affected-medical devices.

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Intra- and inter-species interactions within biofilms of important foodborne bacterial pathogens

Cited by 261 publications

References 378 publications

Oysters and Vibrios as a Model for Disease Dynamics in Wild Animals

Oysters and Vibrios as a Model for Disease Dynamics in Wild Animals

Microbiota formed on attached stainless steel coupons correlates with the natural biofilm of the sink surface in domestic kitchens

Biofilm: An Important Bacterial Feature Still to Deal With

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