Fumonisins: A Neglected Problem in Silage for Cattle

Even though ruminants are still considered less sensitive to FUM, there is evidence that FUM, alone or in combination with other Fusarium mycotoxins, have a hepatotoxic effect as well as impair immune functions in ruminants.

• Hepatic lesions: Hepatic injury and mild morphologic alterations was induced in Holstein calves that were fed corn containing 440 ppm FUM (Baker & Rottinghaus 1999). Beef calves that received 148 ppm for 31 days showed similar symptoms (Osweiler et al., 1993).
• Increased liver enzymes: In several studies, diets contaminated with FUM led to an increase in the liver enzymes aspartate amino transferase (AST) as well as gamma-glutamyl transpeptidase (GGT).  AST and GGT levels in the blood can be used to detect chronic, subacute or acute liver diseases and an elevation of these two liver enzymes can be associated with fatty liver syndrome in ruminants. The increase of these liver enzymes was detected in the calves in the aforementioned study (Baker & Rottinghaus 1999) but also in dairy cows receiving 100 ppm dietary FUM (Diaz et al., 2000), dairy cows receiving a combination of 994 ppb FUM and 733 ppb deoxynivalenol (DON) (Gallo et al., 2020) as well as beef cattle receiving 3.5 ppm FUM and 1.7 ppm DON in combination (Duringer et al., 2020). The elevated levels of these liver enzymes are a sign of liver damage caused by FUM ingestion.
• Immune system:  In the aforementioned study from Gallo et al. (2020) the combination of FUM and DON led to a decrease in ceruloplasmin, hinting at a weaker immune function. Furthermore, specific genes that are responsible for immune activation were downregulated in animals that received the FUM plus DON treatment. With these set of conditions, the animal is more sensitive and defenseless to latent or environmental infections.

Besides the possible hepatotoxicity and immune function impairment, FUM can become a significant risk factor for productivity loss.

• Milk production: In the study from Diaz et al. (2000) the animals ingesting 100 ppm dietary FUM produced  significantly  less milk (FUM cows 24.2 kg/cow/day vs. control cows 31.2 kg/cow/day). Even lower concentrations, like those used in the study from Gallo et al. (2020), caused a 1.34 kg loss of milk production per day in the treated animals.
• Milk quality: Besides the loss of milk quantity, milk quality parameters such as the milk coagulation properties were significantly reduced in the animals that received FUM plus DON (Gallo et al, 2020).
• Weight gain: Angus beef steers on a high grain diet received a total mixed ration contaminated with 3.5 ppm FUM and 1.7 ppm DON for 21 days (Duringer et al., 2020). Control animals received a diet free of mycotoxin contamination. The animals that received FUM in combination with DON showed a significantly worse daily weight gain in comparison to the control animals. Despite being 2 kg heavier on average at the start of the 21 period, the treated animals ended up 14 kg lighter on average than the control animals.

Conclusion
Fumonisins can’t be overlooked and pose a risk that requires testing and assessment in efficient beef and dairy farming.

References

Baker, D. C. & G. E. Rottinghaus (1999) Chronic experimental fumonisin intoxication of calves. Journal of Veterinary Diagnostic Investigation: Official Publication of The American Association Of Veterinary Laboratory Diagnosticians, Inc, 11, 289-292.

Caloni, F., Spotti, M., Auerbach, H., den Camp, H. O., Gremmels, J. F., & Pompa, G. (2000). In vitro metabolism of fumonisin B1 by ruminal microflora. Veterinary Research Communications, 24(6), 379-387.

Custódio, L., Prados, L. F., Yiannikouris, A., Holder, V., Pettigrew, J., Kuritza, L., ... & Siqueira, G. R. (2019). Mycotoxin contamination of diets for beef cattle finishing in feedlot. Revista Brasileira de Zootecnia, 48.

Diaz, D. E., B. A. Hopkins, L. M. Leonard, W. M. Hagler, Jr. & L. W. Whitlow (2000) Effect of Fumonisin on lactating dairy cattle. Journal Of Dairy Science, 83, 1171.