A two-step feeding of calcium salts of fish oil improves reproductive performance in Holstein cows

Aim of study: To examine the effects of a biphasic schedule of feeding n-3 fatty acids on dairy cows.Area of the study: Isfahan, Iran.Materials and methods: 140 lactating Holstein cows were allotted at calving into two groups of 70 animals and received one of two dietary treatments: 1) saturated fatty acids (SFA, containing 80% palmitic acid) or 2) calcium salt of fish oil (CSFO, containing 16% eicosapentaenoic acid (EPA) + docosahexaenoic acid (DHA)), with an n-6/n-3 FA ratio of approximately 7 for SFA and 5 for CSFO treatments. The dietary supplements were fed to the respective groups at 240 g/head.day from 0 to 21 days in milk, and 120 g/head.day from 22 to 150 days in milk. Milk yield was recorded biweekly and milk composition was evaluated monthly. The concentration of FA in the milk and blood was determined on d-90 of the experiment in 10 cows randomly selected from each group. Reproductive indices were recorded until d-150.Main results: The CSFO supplementation did not affect average milk yield, milk composition or milk somatic cell count (SCC); however, in some weeks it decreased milk SCC (p<0.05). Plasma concentrations of palmitic acid and n-3 FA as well as milk fat concentration of EPA and DHA increased in the CSFO-fed cows (p<0.05). Feeding the CSFO decreased open days (100 vs 119 days, p<0.05), service per conception and all service conception rates (p<0.05).Research highlights: The implementation of a two-stage feeding program of n-3 FA improved reproductive variables and reduced milk SCC in dairy cows

Expression of microRNA and microRNA processing machinery genes during early quail (Coturnix japonica) embryo development

Wondim, Dr. Dessie Salilew/0000-0002-8756-0865WOS: 000319314800023PubMed: 23436530MicroRNA (miRNA) are small regulatory RNA molecules that are implicated in regulating and controlling a wide range of physiological processes including cell division, differentiation, migration, apoptosis, morphogenesis, and organogenesis. The aim of this study was to determine the expression pattern of 32 miRNA and 18 miRNA processing machinery genes during somite formation in quail embryos. The embryos were collected at stages HH (Hamburger and Hamilton) 4, 6, and 9 of embryo development (19, 24, and 30 h of incubation, respectively). Total RNA including miRNA was isolated from 4 groups of embryos (each group consisting of 6 to 8 embryos) were collected at each of the 3 stages (19, 24, and 30 h). The expression pattern of candidate miRNA and miRNA processing machinery genes was performed using quantitative real-time PCR. The results demonstrated that 7 miRNA (let-7a, mir-122, mir-125b, mir-10b, P < 0.01; let-7b, mir-26a, and mir-126, P < 0.05) were differentially expressed during early quail embryo development. In addition, the expression profile of 18 miRNA processing machinery genes was not significantly increased at 30 h of incubation compared with both 19 and 24 h. Our results suggest that machinery genes for miRNA biogenetic pathways are functional, and hence, miRNA may be involved in the regulation of early quail development. These 7 differentially expressed miRNA are suggested to play critical roles in quail embryo somite formation