Abstract
Abstract The objectives of my dissertation research are to develop strategies to increase the efficiency of finishing beef production by optimizing the site and extent of starch digestion, improving flaking quality and consistency, and reducing methane emissions. Post-flaking sampling and handling techniques such as sifting steam-flaked corn samples with a sieve (P < 0.01), air equilibration time (P < 0.01), and storage temperature during shipping (P < 0.01) all influenced enzymatic starch availability of steam-flaked corn. Inducing starch retrogradation of steam-flaked corn decreased the rate (P < 0.01), but not the extent (P = 0.80), of ruminal dry matter degradation and thus, energetic efficiency was predicted to increase by up to 3.4% because of increased postruminal flow and digestion of starch in the small intestine. If producing steam-flaked corn is not feasible for smaller capacity feedlots, finely ground corn has a similar ruminal starch solubility to steamflaked corn (38.1% vs. 44.4, respectively, P > 0.05), suggesting an alternative processing method to increase feeding value in finishing diets. Duodenal infusion of glucoamylase (fungal origin) increased (P = 0.02) small intestinal starch disappearance in steers, while duodenal infusion of porcine α-amylase did not (P = 0.41), supporting the hypothesis that small intestinal carbohydrases are the primary hydrolytic limit to small intestinal starch digestion. Comparative sequencing analyses revealed a missing region of the stalk region of the sucrase-isomaltase protein sequence (AA 47-60) which is important for intracellular sorting of the sucrase subunit to the apical membrane. The absence of this region of the protein likely explains the absence of intestinal sucrase activity and quantitative limitations of starch digestion in the ruminant small intestine. Feeding decoquinate with Yucca schidigera extract for 7-d decreased (P < 0.01) ruminal acetate proportion and tended to increase ruminal (P = 0.08) propionate proportion, suggesting potential for hydrogen shifts which could contribute to reductions in methane emissions with longer feeding periods. The findings of my dissertation research provide: 1) post-flaking sampling and handling recommendations for commercial feedlots and laboratories to improve estimates of starch availability and flaking consistency, 2) a mechanistic target (sucrase-isomaltase) for limitations in small intestinal starch digestion, 3) practical feeding strategies to shift the site of starch digestion to the small intestine to increase feed efficiency (retrogradation), 4) new processing alternatives for small feedlot producers (fine ground corn inclusion), and 5) new information on how combinations of feed additives could potentially decrease methane production in feedlot cattle.
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