The arable ecosystem as battleground for emergence of new human pathogens

Overbeek, L.S. van; Doorn, J. van; Wichers, J.H.; Amerongen, A. van; Roermund, H.J.W. van; Willemsen, P.T.J.

doi:10.3389/fmicb.2014.00104

Cited by 62 publications

(66 citation statements)

References 189 publications

(229 reference statements)

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“…Sources of HPs in the production chain and factors contributing to the contamination of fruits and vegetables include for example the application of organic fertilizers such as animal manures, contaminated irrigation water, insect and animal vectors but also the use of contaminated seeds [7]. Enterobacteriaceae such as Erwinia, Serratia, and Pantoea belong to bacteria typically associated with the phyllosphere [8][9][10]. However, it is not completely understood how Salmonella persists in the plant environment and which environmental factors trigger its survival.…”

Section: Introductionmentioning

confidence: 99%

Interaction between Salmonella and Plants: Potential Hosts and Vectors for Human Infection

Fornefeld¹,

Schierstaedt²,

Jechalke³

et al. 2017

Current Topics in Salmonella and Salmonellosis

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Fruits and vegetables are important for a healthy diet. However, when eaten raw and contaminated with human pathogens (HPs) they may cause a disease outbreak. Contamination with HPs can occur along the entire farm-to-fork production chain and Salmonella enterica is one of the most common foodborne pathogens. A range of biotic and abiotic environmental factors can inluence the complex interactions between Salmonella and plants. Moreover, the outcome of experiments largely depends on the experimental design and parameters or methods employed, and on top, on the accompanying plant microbiome and the genetic equipment of the plant and the Salmonella strain. Particularly mobile genetic elements contribute to the diversiication and adaptation of Salmonella to the plant environment. So far, litle is known about the key processes and factors inluencing the atachment and potential internalization of Salmonella in plants and the plant speciic responses. It is therefore important to beter understand the ecology of Salmonella in the soil and plant environment, in order to propose practicable recommendations for prevention of foodborne diseases. This also requires improved sensitivity and speciicity of detection methods. In this chapter, we present the current knowledge, research needs, and methodology regarding the complex interactions between Salmonella and plants.

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Section: Introductionmentioning

confidence: 99%

Interaction between Salmonella and Plants: Potential Hosts and Vectors for Human Infection

Fornefeld¹,

Schierstaedt²,

Jechalke³

et al. 2017

Current Topics in Salmonella and Salmonellosis

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show abstract

“…Horizontal gene transfer (Baltrus 2013) between species can easily occur in a joint habitat such as the soil/manure/plant-rhizosphere interphase, which might confer an enhanced fitness to bacteria to live on plant as well as human hosts. In analogy to zoonosis (bacteria transmitted from animal to human), this new class of plant bacteria is termed "phytonosis" (Van Overbeek et al 2014). One of the most important threats of phytonosic bacteria are acquired genes for antibiotic resistance (Lipsitch et al 2002), known for being abundantly present in the bacterial community of the plant rhizosphere.…”

Section: Bacteriamentioning

confidence: 99%

Robust cropping systems to tackle pests under climate change. A review

Lamichhane¹,

Barzman²,

Booij³

et al. 2014

Agron. Sustain. Dev.

123

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Agriculture in the twenty-first century faces the challenge of meeting food demands while satisfying sustainability goals. The challenge is further complicated by climate change which affects the distribution of crop pests (intended as insects, plants, and pathogenic agents injurious to crops) and the severity of their outbreaks. Increasing concerns over health and the environment as well as new legislation on pesticide use, particularly in the European Union, urge us to find sustainable alternatives to pesticide-based pest management. Here, we review the effect of climate change on crop protection and propose strategies to reduce the impact of future invasive as well as rapidly evolving resident populations. The major points are the following: (1) the main consequence of climate change and globalization is a heightened level of unpredictability of spatial and temporal interactions between weather, cropping systems, and pests; (2) the unpredictable adaptation of pests to a changing environment primarily creates uncertainty and projected changes do not automatically translate into doom and gloom scenarios; (3) faced with uncertainty, policy, research, and extension should prepare for worst-case scenarios following a "no regrets" approach that promotes resilience vis-à-vis pests which, at the biophysical level, entails uncovering what currently makes cropping systems resilient, while at the organizational level, the capacity to adapt needs to be recognized and strengthened; (4) more collective approaches involving extension and other stakeholders will help meet the challenge of developing more robust cropping systems; (5) farmers can take advantage of Web 2.0 and other new technologies to make the exchange of updated information quicker and easier; (6) cooperationThe views expressed by Stephen R. H. Langrell are purely his own and may not in any circumstances be regarded as stating an official position of the European Commission.

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“…Microbes colonizing plant surfaces and interior areas are vital for plant health and productivity (Bonfante, 2010;Berendsen et al, 2012;Ferrara et al, 2012;Monteiro et al, 2012), but some of them could lead to disease development of plants (James and Olivares, 1998;Monteiro et al, 2012;Van Overbeek et al, 2014). Prior reports indicate that *Corresponding author.…”

Section: Introductionmentioning

confidence: 99%

“…Author(s) agree that this article remains permanently open access under the terms of the Creative Commons Attribution License 4.0 International License plant microbiome could be beneficial for human health through consumption of raw plants (Blaser et al, 2013;Van Overbeek et al, 2014). Therefore, understanding the microbial composition of plants may assist in the development of sustainable agriculture (Berg, 2009;Lugtenberg and Kamilova, 2009).…”

Section: Introductionmentioning

confidence: 99%

Diversity and distribution of endophytic bacterial community in the Noni (Morinda citrifolia L.) plant

Liu¹,

Li²,

Yao³

et al. 2015

Afr. J. Microbiol. Res.

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Noni (Morinda citrifolia L.) is a plant used by traditional cultures and also in modern health care products. Various chemical substances are derived from the plant and include, but are not limited to anthraquinone flavonol glycosides, iridoid glycosides, lipids glycosides and triterpenoids. Also commonly found on the plant are endophytic bacteria however, there are no reports on endophytic bacterial community of Noni. We collected samples from five sites of Noni plant (roots, branches, leaves, fruits and seeds) and performed 16S rDNA analysis. Results show that these five parts harbor a highly similar bacterial composition with the top four being Sphingomonas, Pseudomonas, Halomonas and Geobacillus. Sphingomonas and Pseudomonas were found to be widely distributed in plant endophytic biotope; while there are little reports on plant-associated Halomonas and Geobacillus, indicating distribution in the plant hosts. Unknown genus also is abundant in five sites of Noni, ranging from 26.70 to 33.66%, implicating necessity to reveal them. This study provides information on endophytic bacteria in the Noni for future analysis based on a metagenome strategy.

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The arable ecosystem as battleground for emergence of new human pathogens

Cited by 62 publications

References 189 publications

Interaction between Salmonella and Plants: Potential Hosts and Vectors for Human Infection

Interaction between Salmonella and Plants: Potential Hosts and Vectors for Human Infection

Robust cropping systems to tackle pests under climate change. A review

Diversity and distribution of endophytic bacterial community in the Noni (Morinda citrifolia L.) plant

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