A study was conducted to evaluate the influence of the purification of yeast cell wall (YCW) preparations on broiler performance and immunogenic and metabolic pathways under microbial challenge. A total of 240 (day old) chicks were distributed among two battery brooder units (48 pens; 5 birds/pen; 8 replicates/treatment). A basal starter diet was divided into 5 batches to create 6 dietary treatments; non-challenge (NCh-C) and challenge (Ch-C) controls, semi-purified YCW containing cytosol contents (SPYCW; 250 mg/kg), purified YCW (PYCW; 250 mg/kg), 50% purified beta-glucan (BG; 130 mg/kg), and 99.9% purified mannan-oligosaccharide (MOS; 53 mg/kg). All birds were immunocompromised with infectious bursal disease vaccine (10× the recommended dose) on day 10 and then all birds except NCh-C birds were challenged with Clostridium perfringens (Cp) (107 cfu/mL) via oral gavage on days 16 and 17. On day 21, tissue samples were collected from the jejunum and duodenum for analysis with chicken-specific, peptide arrays to study the influence of YCW supplementation on immune and metabolic kinase pathways. On day 16, SPYCW had significantly lower body weight (BW) and weight gain (WG) than other treatments except BG (P < 0.05). The productivity index (PI) was lower in SPYCW and BG than in NCh-C, Ch-C, and PYCW. On day 21, after the Cp challenge, NCh-C was higher than Ch-C, SPYCW, and BG in BW, WG, and PI (P = 0.03). The PI of PYCW was similar to NCh-C. The addition of purified YCW to the starter broiler diets influenced the immune and metabolic pathways in the gut. A total of 459 and 367 peptides in the duodenum and jejunum, respectively, were changed due to the Cp challenge. The YCW treatments had different degrees of influence on these peptides for both the duodenum and jejunum. These results suggest that relative purification of YCW and specific fractions of the YCW can influence broiler performance differently during microbial challenges and can alleviate the impact of these stressors.
This study evaluated egg production and quality variables of caged and free-range Hy-Line Brown laying hens fed soybean meal (SBM) and soybean-meal-free (SBMF) diets. Hens were randomly assigned to the same 2 dietary treatments within 3 location blocks. SBM and SBMF diets with equivalent calculated nutrient content were prepared based on Hy-Line Brown rearing guidelines. The SBMF diets utilized cottonseed meal, corn distillers dried grains with solubles, corn gluten meal, and wheat middlings in place of dehulled soybean meal. The experiment was conducted between August 2015 and January of 2016 within the TAMU Poultry Research Center and data analyzed over 6 consecutive 28-day periods. Data were analyzed as a split-plot with rearing systems designated whole plots and diets designated as subplots. Hens reared in the free-range rearing system peaked a couple of wk later than those hens within the more conventional indoor caged system, and cumulative production data were considerably more variable for hens raised in the free-range environment. Cumulative egg production, feed per dozen eggs and feed conversion ratio (g feed/g egg) were 92 ± 1.23 and 86 ± 1.84%, 1.45 ± 0.02 and 1.89 ± 0.05 kg, and 2.14 ± 0.04 and 2.77 ± 0.08 (P < 0.05), respectively, for the caged vs. free-range rearing systems. Cumulative egg weight, feed per dozen eggs, and feed conversion ratio were 59.9 ± 0.59 and 56.5 ± 0.60 g, 1.57 ± 0.04 and 1.77 ± 0.05 kg, and 2.24 ± 0.06 and 2.67 ± 0.08 kg (P < 0.05) for SBM and SBMF diets, respectively. Diet did not affect cumulative egg production (P > 0.05). With respect to egg quality, there were no differences in cumulative albumen height, Haugh unit, or breaking strength, but there was a significant rearing system by diet interaction for shell thickness, with the free-range hens averaging 40.77 ± 0.19 and 39.86 ± 0.31 μm (P < 0.05), respectively, for the hens fed SBM vs. SBMF diets. In conclusion, the results suggested free-range production is more variable than traditional closed-house cage systems based on standard errors, and SBMF diets containing cottonseed meal can be used in both caged and free-range production systems without affecting egg production, although one might see lower egg weights.
A 6-week broiler study was conducted to evaluate whether subjecting the intestinal microflora of broilers to the effect of weekly variations in feed ingredients could be ameliorated by the inclusion of yeast-derived feed additives: a yeast cell wall extract (YCW), live yeast culture (LY) or their combination (YCW + LY). Recent changes in ingredient prices have motivated producers to formulate diets not necessarily based primarily on corn and soya bean meal. Intestinal microflora in birds can vary significantly based on the ingredient composition of their diet, and the make-up of the flora can influence overall bird performance. Within the three nutrient phases of this study, birds were fed either a traditional corn-soya ingredient profile or a variable-ingredient regimen, which had weekly changes in the ingredient composition. There were consistent ameliorative effects of the yeast treatments in both the corn-soya and the variable-ingredient groups throughout all 6 weeks, with the YCW + LY combination showing a reduced effect when compared to either product fed alone. The effectiveness of YCW and LY on ameliorating the effects of weekly ingredient variations appeared most effective during the starter and grower phases, but was less significant during the sixth week.
Necrotic enteritis (NE) is one of the most common and costly diseases in the modern broiler industry, having an estimated economic impact of $6 billion dollars annually. Increasing incidents of NE have resulted from restrictions on the use of antibiotic feed additives throughout the broiler industry. As such, finding effective antibiotic alternatives has become a priority. In this study, an experimental model of NE was used, comprising a commercial infectious bursal disease virus vaccine and Clostridium perfringens ( C. perfringens ) inoculation. Yeast cells wall (YCW) components, β-glucan (BG), and mannoproteins (MPTs) were evaluated for their effects on disease development. Chicken-specific immunometabolic kinome peptide arrays were used to measure differential phosphorylation between control (uninfected), challenged (infected), and challenged and treated birds in duodenal, jejunal, and ileal tissues. Treatment groups included crude YCW preparation, BG, MPT, or BG+MPT as feed additives. Data analysis revealed kinome profiles cluster predominantly by tissue, with duodenum showing the greatest relative signaling and jejunum showing the greatest response to treatment. BG, MPT, and BG+MPT cluster together, separate from controls and challenge birds in each tissue. Changes in signaling resulting from the treatments were observed in cell growth and survival responses as well as immune responses. None of the treatments of disease challenge returned the profiles to control-like. This is attributable to immune modulation and metabolic effects of the treatments generating distinct profiles from control. Importantly, all the treatments are distinct from the challenge group despite being challenged themselves. Only BG+MPT treatment had a significant effect on bird weight gain compared with the NE challenge group, and this treatment had the greatest impact on gut tissue signaling in all segments. The signaling changes elicited by BG+MPT during an NE challenge were increased cell growth and survival signaling, reducing cell death, apoptosis and innate inflammatory responses, and generating compensatory signaling to reduce disease severity.
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