Bioaccessibility of iron from soil is increased by silage fermentation.

High dietary Fe can negatively affect absorption of other minerals and cause tissue damage through the production of free radicals. Cattle are often exposed to high dietary Fe, and soil ingestion may represent a major dietary source of Fe. Iron in soil is often found in the ferric form bound in insoluble complexes; however, exposure to an acidic environment similar to that occurring during silage fermentation may cause this Fe to be reduced to the more soluble ferrous form. To test this theory, a 2 x 2 x 3 factorial arrangement examining time, level, and type of soil addition to greenchop was used. Factors included 2 times of soil addition (before or after ensiling), 2 levels of soil inclusion (1 and 5% contamination, wet basis) and 3 types of soil (Cecil clay loam, 3.4% Fe; Georgeville silt loam, 4.3% Fe; and Dyke clay loam, 6.9% Fe). In addition, greenchop with no soil added was ensiled to serve as a control. Fresh corn greenchop was mixed with the appropriate type and level of soil and tightly packed in experimental silos. Fermentation was allowed to proceed for 90 d before silos were opened and silage was freeze-dried and ground. To simulate contamination after ensiling, each soil type was added to control silage at the 2 levels of inclusion. Addition of soil to greenchop before ensiling resulted in greater amounts of water soluble Fe compared with soil addition after ensiling, suggesting that Fe-soil binding properties were altered by ensiling. To test the potential bioaccessibility of Fe during ruminant digestion, an enzymatic in vitro system was modified to simulate ruminal, abomasal, and intestinal digestion. The presence of soil, regardless of time of addition, type, or inclusion level, resulted in greater soluble or bioaccessible Fe concentrations after all 3 phases when compared with control silage. Ensiling further increased soluble Fe concentrations after each phase when compared with silage contaminated with soil after ensiling. In addition, dialyzable Fe concentration (15,000 Da molecular weight cut off) following intestinal phase simulation was greater due to ensiling. Iron that becomes soluble during the intestinal phase may be available to the animal for absorption, and ensiling resulted in increased concentrations of potentially bioavailable Fe. These results suggest that soil contamination of harvested feeds before ensiling may represent a major source of bioavailable Fe in the diets of cattle.

[1]  S. Bellis,et al.  Hyposialylation Regulates α4β1 Integrin Binding to VCAM‐1 , 2008 .

[2]  J. Spears,et al.  Impact of copper deficiency in cattle on proteins involved in iron metabolism , 2008 .

[3]  J. C. Burns,et al.  Afternoon harvest increases readily fermentable carbohydrate concentration and voluntary intake of gamagrass and switchgrass baleage by beef steers. , 2007, Journal of animal science.

[4]  Prasad N. Paradkar,et al.  Comparison of mammalian cell lines expressing distinct isoforms of divalent metal transporter 1 in a tetracycline-regulated fashion. , 2006, The Biochemical journal.

[5]  M. Garrick,et al.  Iron Imports. II. Iron uptake at the apical membrane in the intestine. , 2005, American journal of physiology. Gastrointestinal and liver physiology.

[6]  P. Sharp The molecular basis of copper and iron interactions , 2004, Proceedings of the Nutrition Society.

[7]  M. Núñez,et al.  DMT1, a physiologically relevant apical Cu1+ transporter of intestinal cells. , 2003, American journal of physiology. Cell physiology.

[8]  E. Depeters,et al.  Variability in the Chemical Composition of Seventeen Selected By-Product Feedstuffs Used by the California Dairy Industry , 2000 .

[9]  D. Whitehead Micronutrient cations: iron, manganese, zinc, copper and cobalt , 2000 .

[10]  D. Whitehead Nutrient elements in grassland: soil-plant-animal relationships. , 2000 .

[11]  D. Gibb,et al.  Nutrient Requirements of Beef Cattle, 7th ed , 1997 .

[12]  Michael V. Ruby,et al.  Estimation of lead and arsenic bioavailability using a physiologically based extraction test , 1996 .

[13]  J. Spears,et al.  Effect of dietary copper, iron, and molybdenum on growth and copper status of beef cows and calves. , 1994, Journal of animal science.

[14]  B. Rafferty,et al.  Soil and radiocaesium contamination of winter fodders , 1994 .

[15]  J. Spears,et al.  Comparison of copper lysine and copper sulfate as copper sources for ruminants using in vitro methods. , 1993, Journal of dairy science.

[16]  C. W. Hunt,et al.  Effects of hybrid and ensiling with and without a microbial inoculant on the nutritional characteristics of whole-plant corn. , 1993, Journal of animal science.

[17]  C. Davis,et al.  Varying levels of manganese and iron affect absorption and gut endogenous losses of manganese by rats. , 1992, The Journal of nutrition.

[18]  S. Tamminga,et al.  Solubility of mineral elements present in ruminant feeds , 1990, The Journal of Agricultural Science.

[19]  C. Ribble,et al.  Assessment of the role of manganese in congenital joint laxity and dwarfism in calves. , 1990, Annales de recherches veterinaires. Annals of veterinary research.

[20]  J. T. Tanner,et al.  Comparison of in vitro, animal, and clinical determinations of iron bioavailability: International Nutritional Anemia Consultative Group Task Force report on iron bioavailability. , 1989, The American journal of clinical nutrition.

[21]  B. Cottyn,et al.  The use of an enzymatic technique to predict digestibility, metabolizable and net energy of compound feedstuffs for ruminants , 1986 .

[22]  J. Nocek,et al.  Characterization of Soyhull Fiber Digestion by In Situ and In Vitro Enzymatic Procedures , 1984 .

[23]  J. Rooke,et al.  The release of mineral elements from grass silages incubated in sacco in the rumens of Jersey cattle , 1983 .

[24]  W. R. Humphries,et al.  The influence of dietary iron and molybdenum on copper metabolism in calves , 1983, British Journal of Nutrition.

[25]  D. Veira,et al.  EFFECT OF DIETARY PROTEIN ON THE SOLUBILITIES OF MANGANESE, COPPER, ZINC AND IRON IN THE RUMEN AND ABOMASUM OF SHEEP , 1981 .

[26]  D. Miller,et al.  A comparison of in vivo and in vitro methods for determining availability of iron from meals. , 1981, The American journal of clinical nutrition.

[27]  W. Healy In vitro Studies on the effects of soil on elements in ruminal, “duodenal”, and ileal liquors from sheep , 1972 .

[28]  A. Z. Palmer,et al.  Influence of dietary iron and phosphorus on performance, tissue mineral composition and mineral absorption in steers. , 1971, Journal of animal science.

[29]  A. Z. Palmer,et al.  Influence of graded levels of dietary iron, as ferrous sulfate, on performance and tissue mineral composition of steers. , 1969, Journal of animal science.

[30]  J. M. A. Tilley,et al.  A TWO-STAGE TECHNIQUE FOR THE IN VITRO DIGESTION OF FORAGE CROPS , 1963 .