The IMPACT OF MYCOTOXINS on the IMMUNE STATUS OF RUMINANTS Consequences on disease susceptibility and vaccine efficacy
Sabry El-khodary Professor of Internal Medicine, and vice dean for post graduate studies and research affairs, Faculty of Veterinary Medicine, Mansoura University, Egypt
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Numerous investigations have shown that, once ingested, mycotoxin-contaminated feed can induce harmful effects, such as hepatorenal toxicity, reproductive, cardiac, and neurotoxicity, as well as immunotoxicity in animals (Fang et al., 2022). When livestock ingests one or more mycotoxins, the effect on health can be acute, showing evident signs of disease or even causing death.
However, acute manifestation of mycotoxicosis is rare under farm conditions (Vieira et al., 2014).
The effects of mycotoxin ingestion are mainly chronic, leading to hidden disorders with reduced ingestion, productivity, and fertility (Fink-Gremmels, 2008). Such effects cause severe economic losses due to:
Clinical changes in animal growth Reduction in feed intake or complete anorexia Alteration in nutrient absorption and metabolism Effects on the endocrine system Suppression of the immune system
(Oswald et al., 2005; Storm et al., 2014a)
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The immunotoxic effects of MYCOTOXINS in ruminants Mycotoxins have been proved to have
Additionally, emerging evidence shows that
immunosuppressive effects depending on:
mycotoxins have the potential to induce cellular senescence, which is involved in their
The mycotoxin(s) involved
immunomodulatory effects (You et al., 2023).
The concentration
Hypoxia
The parameter studied
Immunosuppression
For example, aflatoxin B1 (AFB1) has immunotoxic consequences, such as the disruption of innate and acquired/adaptive immunity
(Meissonnier et al., 2008; Mohsenzadeh et al., 2016).
In ruminants, mycotoxins have been confirmed to induce oxidative stress, hypoxia, and immunosuppression.
Oxidative stress
Cellular senescence & immunomodulation
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In beef cattle, the impact of exposure to dietary mycotoxins on the metabolism is negligible (Roberts et al., 2021b). Nevertheless, studies on the effect of mycotoxins on drug efficacy in large animals are scarce, which may be due to the relative resistance to mycotoxins in ruminants in comparison to poultry.
Penicillium-derived toxins
P. roqueforti and P. paneum produce several secondary metabolites with immunosuppressive, antibacterial, and other not well-defined toxicological effects for animals (Storm et al.,
2008; Storm et al., 2014b).
Monascus ruber-derived toxins
Based on in vitro results, immunotoxic effects of citrinin have been documented at very high doses (Stec et al., 2008).
Fusarium-derived toxins
Fusarium-derived toxins, mainly deoxynivalenol (DON) and Fumonisin B1 (FB1), can drastically alter the defense mechanisms in the intestine, reducing epithelial integrity, cell proliferation and mucus production or increasing intestinal permeability, as well as the production of immunoglobulins and cytokines (Antonissen et al., 2014).
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For example, A. fumigatus produces several
Several metabolites from Fusarium fungi,
mycotoxins, including gliotoxin and
collectively known as Fusarium toxins,
tremorgens that are toxic to cattle.
have shown deleterious effects in
Gliotoxin, an immune suppressant, has been present in animals infected with
A. fumigatus (Bauer et al., 1989).
humans and livestock by targeting the immune and hepatic systems (Bondy and
Pestka, 2000b; Trenholm et al., 1984).
In an insect model, the role of gliotoxin in increasing the virulence of A. fumigatus has been demonstrated
(Reeves et al., 2004).
The impact of mycotoxins on the ruminant immune system In ruminants, AFB1, ochratoxin A (OTA), and DON are the three mycotoxins that have received the most scholarly attention and have been tested most routinely in clinical settings.
These mycotoxins have been found not only to suppress immune responses but also to induce inflammation and even increase susceptibility to pathogens (Sun et al., 2023a).
It is theorized that, with in the development of mycosis, mycotoxins produced by the invading fungi can suppress immunity, therefore increasing their infectivity (Whitlow and Hagler Jr, 2010).
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Leukocytes and differential leukocytic count
In a 3-week experimental case of mycotoxicosis in
RNA-Seq analysis has revealed 217 differentially
steers, there was leukocytosis with lymphocytosis,
expressed genes between treatment- and
monocytosis and neutropenia. However, 1.7 mg
control-fed steers, with mycotoxin exposure broadly
of DON and 3.5 mg of fumonisins (FUM) per kg of
leading to down-regulation of annotated features.
total ration were insufficient to cause significant cytotoxic effects on circulating mononuclear
Downregulated genes from treatment-fed
leukocytes in these animals (Roberts et al., 2021b).
steers indicates that iron utilization may be adversely affected by DON/
The same authors added that the phagocytic capacity of granulocytes from all the steers was substantially reduced by week 5, whereas monocyte activity began to decline even earlier in the study.
FUM exposure (Roberts et al., 2021b). Previous studies have shown alterations in cellular oxygen transport mechanisms by in vitro administration of fumonisins
(Osweiler et al., 1993; Yin et al., 1996). In an experimental study, mycotoxins have shown to reduce phagocytic activity in
In a study with control-fed steers, CD8+ lymphocytes decreased during the first two weeks of the treatment
finishing-stage steers, regardless of prior mycotoxin exposure (Roberts et al., 2021a).
period, while treatment-fed animals (DON and FUM) had significantly higher CD4-CD8+ lymphocyte populations during week 2 (Roberts et al., 2021b). It has been concluded that bovine cells are more sensitive to DON than those from other livestock species (Novak et al., 2018). However, their effect on body condition or growth status was not been formally evaluated (Pestka, 2008).
It has been suggested that the CD4:CD8 ratio could be a candidate biomarker of early DON exposure in beef cattle, which may be attenuated by co-occurring fumonisin toxicity (Taranu et al., 2010).
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Inflammatory Response, Neutrophil Chemotaxis and Immunoglobulins
In an experimental study in finishing steers, exposure to DON/FUM induced upregulation of inflammatory response times at days 7 and 21, along with neutrophil chemotaxis times at day 7 (Roberts et al., 2021a).
The same authors found that early mycotoxin exposure was accompanied with a numerical increase in neutrophil abundance, but at the same time, functional assays showed a slight decrease in granulocyte phagocytosis and oxidative burst. Additionally, immunoglobulin-related pathways were enriched in animals exposed to DON/FUM on day 21.
The effects of DON on laboratory animal immunoglobulin levels have been previously reviewed (Bondy and Pestka, 2000a), showing alterations in immunoglobulin production in a class-dependent manner. However, disruptions to antibody production are an important nonlinear toxicological outcome in cattle (Dänicke et al., 2018). DIA and DAVID analysis tools revealed the effects of dietary mycotoxin treatments on the beef cattle transcriptome, showing consistent inhibition of focal adhesion, ECM signaling and PI3K-Akt signaling
In pigs, mycotoxin exposure inhibits lymphocyte proliferation and alters cytokine production.
pathways (Roberts et al., 2021a).
In vitro studies have demonstrated a suppressive effect of aflatoxins (AF) on inflammatory cytokine levels in cattle (Kurtz and Czuprynski, 1992).
Specifically, AFB1 increases the synthesis of IFN-gamma, a Th1 cytokine involved in the cell mediated immune response, and decreases IL-4 synthesis, a Th2 cytokine involved in the humoral response (Pierron et al., 2016).
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Significant changes in some coagulation factors in the extrinsic pathway in the intoxicated lambs and prothrombin time determination could be used as an indicator of aflatoxicosis in lambs (Fernández et al., 1995).
DON, nivalenol (NIV), zearalenone (ZEN), and FB1 have been proven to modulate the secretory mucins MUC5AC and MUC5B, as well as total mucin-like glycoprotein secretion, all of which are essential components of host mucosal immunity (Wan et al., 2014).
Susceptibility to infection and failure of vaccination
Mycotoxin exposure can affect the infection
Mycotoxin-associated increased susceptibility
severity of some pathogens, including
to infection has been documented in
bacteria, viruses, and parasites. Their specific
experimental and natural conditions.
mechanisms of action include three aspects: In calves, exposure to AFs has shown to Mycotoxin exposure directly promotes the
increase susceptibility to Shiga toxin-producing
proliferation of pathogenic microorganisms.
Escherichia coli (STEC) (Baines et al., 2013a).
Mycotoxins induce toxicity, destroying the
Alteration of lymphocyte proliferation and
integrity of the mucosal barrier and promoting
cytokine production may explain vaccine
an inflammatory response, thereby increasing
failures that have been observed in vivo.
the susceptibility of the host to infections. The presence of mycotoxins in the feed may Mycotoxins reduce the activity of some specific
lead to a decline in vaccinal immunity and to
immune cells and induce immune suppression,
the occurrence of disease even in properly
resulting in reduced host resistance.
vaccinated flocks (Pierron et al., 2016).
(Sun et al., 2023a)
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Synergistic effects between viruses and mycotoxins have been extensively studied in swine (Gan et
al., 2022; Gan et al., 2018) and the outcomes of the ingestion of mycotoxin-contaminated feed are increased susceptibility to infectious diseases, reactivation of chronic infection and a decreased vaccine efficacy (Pierron et al., 2016).
However, in another experiment, results indicate that a decline in the average daily gain was the most sensitive indicator of aflatoxicosis in lambs, showing that the altered immune response could render the animals more susceptible to infectious diseases (Fernández et al., 2000).
Exposing calves to 1–3 ppb of AF and 50–350 ppb of FUM facilitated STEC-associated outbreaks. In addition, in vitro inclusion of 0.02 ppb of AF in the growth media of STECs resulted in higher cytotoxin production and cytotoxicity, highlighting the role of mycotoxins in STEC pathogenesis (Baines et al., 2013b).
An experiment carried out by Dzidic et al. (2010) indicated that sheep fed 300 mg of mycophenolic acid/sheep/day from contaminated silage did not show any immunodepression effects.
In other studies, cattle exposed to mycotoxin mixtures were colonized by two or more STECs, suggesting that mycotoxins facilitate co-infection (Baines et
al., 2011a; Baines et al., 2011b).
In lambs, experimental aflatoxicosis revealed that albumin and alfa-globulin levels were lower for intoxicated lambs than in the control group. Although beta-globulin concentrations did not change, increases in gamma-globulins levels in dosed lambs were observed throughout the experiment. These results suggest that AF cause a failure in the lambs’ acquired immunity by decreasing antibody production and altering serum proteins (Fernández et al., 1997).
In contrast, Penicillium-derived toxins, such as citrinin, OTA, patulin, mycophenolic acid, penicillic acid (or a combination of one of these mycotoxins with OTA) could inhibit activity of macrophages up to 25%, thus confirming immunomodulatory properties of these mycotoxins and the possible increase of disease susceptibility in cattle consuming contaminated diets (Oh et al., 2013).
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Although mycotoxins have been confirmed to modulate the effects of bacteria within animals and increase their virulence, it has also been suggested that strains of L. acidophilus CIP 76.13T and L. delbrueckii subsp. bulgaricus CIP 101027T may be included in feed to reduce mycotoxin contamination (Ragoubi et al., 2021).
As mycotoxin exposure can be detrimental to certain intestinal microbial populations, the use of beneficial bacteria can alleviate these effects. For example, Lactobacillus is a critical genus for detoxifying OTA in vivo (Guerre, 2020; Jin et al., 2021; Sun et al., 2023b).
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