High-Zinc Supplementation of Weaned Piglets Affects Frequencies of Virulence and Bacteriocin Associated Genes Among Intestinal Escherichia coli Populations

Johanns, V.; Epping, Lennard; Semmler, Torsten; Ghazisaeedi, Fereshteh; Lübke‐Becker, Antina; Pfeifer, Yvonne; Eichhorn, Inga; Merle, Roswitha; Bethe, Astrid; Walther, Birgit; Wieler, Lothar H.

doi:10.3389/fvets.2020.614513

Cited by 6 publications

(6 citation statements)

References 92 publications

(113 reference statements)

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“…Various (mainly) negative, as well as positive, correlations between free ions or protein-bound zinc and numbers of different bacterial taxa or groups in the GIT were reported by [ 18 ], while seemingly similar Zn fractions between groups have been associated with different microbial profiles [ 16 ] or apparent fractional differences between groups associated with relatively similar gut microbiological parameters [ 20 ]. Excess Zn has been reported to be negatively correlated with the occurrence of enteric E. coli pathotypes, which could at least partially explain the associated reduction in diarrhea, but seemingly increases the carriage of virulence-associated genes within the intestinal E. coli populations [ 23 ], and has been proposed to slow the decline in fecal shedding of an administered Salmonella serovar [ 24 ].…”

Section: Zinc Copper and Manganese Influences On Intestinal Healthmentioning

confidence: 99%

“…In weaned pigs, Højberg et al [ 23 ] reported that 175 mg/kg dietary Cu (from CuSO 4 ) reduced lactic acid bacteria counts in the stomach, and coliforms in the cecum and the colon, while Namkung et al [ 40 ] found the GI microbiota diversity to be reduced with 250 mg/kg additional Cu. A lower microbiota diversity is often considered undesirable, although often a feature of antimicrobial supplementation, but the reduction in the putative beneficial lactic acid bacteria was surprising.…”

Section: Zinc Copper and Manganese Influences On Intestinal Healthmentioning

confidence: 99%

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Recent Advances in Understanding the Influence of Zinc, Copper, and Manganese on the Gastrointestinal Environment of Pigs and Poultry

Broom

Monteiro²,

Piñon³

2021

Animals

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Zinc, copper, and manganese are prominent essential trace (or micro) minerals, being required in small, but adequate, amounts by pigs and poultry for normal biological functioning. Feed is a source of trace minerals for pigs and poultry but variable bioavailability in typical feed ingredients means that supplementation with low-cost oxides and sulphates has become common practice. Such trace mineral supplementation often provides significant ‘safety margins’, while copper and zinc have been supplemented at supra-nutritional (or pharmacological) levels to improve health and/or growth performance. Regulatory mechanisms ensure that much of this oversupply is excreted by the host into the environment, which can be toxic to plants and microorganisms or promote antimicrobial resistance in microbes, and thus supplying trace minerals more precisely to pigs and poultry is necessary. The gastrointestinal tract is thus central to the maintenance of trace mineral homeostasis and the provision of supra-nutritional or pharmacological levels is associated with modification of the gut environment, such as the microbiome. This review, therefore, considers recent advances in understanding the influence of zinc, copper, and manganese on the gastrointestinal environment of pigs and poultry, including more novel, alternative sources seeking to maintain supra-nutritional benefits with minimal environmental impact.

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Section: Zinc Copper and Manganese Influences On Intestinal Healthmentioning

confidence: 99%

Section: Zinc Copper and Manganese Influences On Intestinal Healthmentioning

confidence: 99%

Recent Advances in Understanding the Influence of Zinc, Copper, and Manganese on the Gastrointestinal Environment of Pigs and Poultry

Broom

Monteiro²,

Piñon³

2021

Animals

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“…These studies are complicated by the fact that many pathogens of concern are opportunists and do not necessarily cause infection at the time of exposure or transmission. Therefore, colonisation, virulence potential linked to AMR and heavy metal resistance and potential for gene transfer, as well as relevance to human infection should also be considered as an end point for epidemiological studies (in addition to infection) as part of overarching One Health‐based studies (Hernando‐Amado et al., 2019; Findlay et al., 2020; Johanns et al., 2020).…”

Section: Assessmentmentioning

confidence: 99%

Role played by the environment in the emergence and spread of antimicrobial resistance (AMR) through the food chain

Koutsoumanis¹,

Allende²,

Álvarez‐Ordóñez³

et al. 2021

EFS2

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The role of food-producing environments in the emergence and spread of antimicrobial resistance (AMR) in EU plant-based food production, terrestrial animals (poultry, cattle and pigs) and aquaculture was assessed. Among the various sources and transmission routes identified, fertilisers of faecal origin, irrigation and surface water for plant-based food and water for aquaculture were considered of major importance. For terrestrial animal production, potential sources consist of feed, humans, water, air/dust, soil, wildlife, rodents, arthropods and equipment. Among those, evidence was found for introduction with feed and humans, for the other sources, the importance could not be assessed. Several ARB of highest priority for public health, such as carbapenem or extended-spectrum cephalosporin and/or fluoroquinolone-resistant Enterobacterales (including Salmonella enterica), fluoroquinolone-resistant Campylobacter spp., methicillin-resistant Staphylococcus aureus and glycopeptide-resistant Enterococcus faecium and E. faecalis were identified. Among highest priority ARGs bla CTX-M , bla VIM , bla NDM , bla OXA-48like , bla OXA-23 , mcr, armA, vanA, cfr and optrA were reported. These highest priority bacteria and genes were identified in different sources, at primary and post-harvest level, particularly faeces/manure, soil and water. For all sectors, reducing the occurrence of faecal microbial contamination of fertilisers, water, feed and the production environment and minimising persistence/recycling of ARB within animal production facilities is a priority. Proper implementation of good hygiene practices, biosecurity and food safety management systems is very important. Potential AMR-specific interventions are in the early stages of development. Many data gaps relating to sources and relevance of transmission routes, diversity of ARB and ARGs, effectiveness of mitigation measures were identified. Representative epidemiological and attribution studies on AMR and its effective control in food production environments at EU level, linked to One Health and environmental initiatives, are urgently required.

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“…A detailed analysis of 179 Escherichia coli genomes obtained from piglets after completion of a Zn oxide feeding trial demonstrated that genes and operons associated with virulence and bacteriocin production, as well as enterotoxigenic, enteropathogenic, and Shiga toxin-producing pathotypes were less abundant in high Zn-supplemented animals [ 66 ]. In enteropathogenic Escherichia coli , exposure to Zn was shown to reduce expression of virulence factors and reduced bacterial adhesion to the cells.…”

Section: Zn and Microbiota Upon Exposure To Toxic And Infectious Agentsmentioning

confidence: 99%

Gut Microbiota as a Mediator of Essential and Toxic Effects of Zinc in the Intestines and Other Tissues

Skalny

Aschner

Lei

et al. 2021

IJMS

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The objective of the present study was to review the existing data on the association between Zn status and characteristics of gut microbiota in various organisms and the potential role of Zn-induced microbiota in modulating systemic effects. The existing data demonstrate a tight relationship between Zn metabolism and gut microbiota as demonstrated in Zn deficiency, supplementation, and toxicity studies. Generally, Zn was found to be a significant factor for gut bacteria biodiversity. The effects of physiological and nutritional Zn doses also result in improved gut wall integrity, thus contributing to reduced translocation of bacteria and gut microbiome metabolites into the systemic circulation. In contrast, Zn overexposure induced substantial alterations in gut microbiota. In parallel with intestinal effects, systemic effects of Zn-induced gut microbiota modulation may include systemic inflammation and acute pancreatitis, autism spectrum disorder and attention deficit hyperactivity disorder, as well as fetal alcohol syndrome and obesity. In view of both Zn and gut microbiota, as well as their interaction in the regulation of the physiological functions of the host organism, addressing these targets through the use of Zn-enriched probiotics may be considered an effective strategy for health management.

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High-Zinc Supplementation of Weaned Piglets Affects Frequencies of Virulence and Bacteriocin Associated Genes Among Intestinal Escherichia coli Populations

Cited by 6 publications

References 92 publications

Recent Advances in Understanding the Influence of Zinc, Copper, and Manganese on the Gastrointestinal Environment of Pigs and Poultry

Recent Advances in Understanding the Influence of Zinc, Copper, and Manganese on the Gastrointestinal Environment of Pigs and Poultry

Role played by the environment in the emergence and spread of antimicrobial resistance (AMR) through the food chain

Gut Microbiota as a Mediator of Essential and Toxic Effects of Zinc in the Intestines and Other Tissues

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