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Effects of dietary menhaden oil on growth and reproduction in gilts farrowed by sows that consumed diets containing menhaden oil during gestation and lactation

Published online by Cambridge University Press:  19 February 2019

R. C. Petrone
Affiliation:
Tidewater Agricultural Research and Extension Center, Virginia Tech, Suffolk, VA 23437, USA
K. A. Williams
Affiliation:
Tidewater Agricultural Research and Extension Center, Virginia Tech, Suffolk, VA 23437, USA
M. J. Estienne*
Affiliation:
Tidewater Agricultural Research and Extension Center, Virginia Tech, Suffolk, VA 23437, USA
*
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Abstract

In sows, n-3 fatty acids increase litter sizes, however, effects on gilt reproductive development have not been adequately studied. Moreover, not determined are effects of feeding n-3 fatty acids to sows on reproduction in offspring. The objective here was to determine effects of 4% dietary menhaden oil on growth and puberty in gilts farrowed by sows fed menhaden oil. Sows (n = 44) were assigned to: (1) control gestation and lactation diets, or (2) diets including menhaden oil. For primiparous sows only, total litter size and born alive were greater (P < 0.05) in females fed menhaden oil. Conversely, pigs from primiparous controls were heavier (P < 0.05) than pigs from primiparous sows fed menhaden oil (parity by diet interactions, P < 0.01). Diet did not affect (P > 0.20) other sow and litter characteristics. At weaning, 84 gilts from control- or menhaden oil sows were placed three gilts per pen and provided control diets or diets containing menhaden oil. Nursery and grow-finish feed intake and feed efficiency were similar (P > 0.21) for gilts from the different sows and weight gain was similar (P > 0.24) for gilts fed control or menhaden diets. Gilts fed menhaden oil tended to eat less in the nursery (1.18±0.08 kg v. 0.98±0.08 kg; P = 0.09) and overall (1.83±0.04 kg v. 1.72±0.04 kg; P = 0.06). Thus, overall feed to gain was greater (2.52±0.03 v. 2.33±0.03; P < 0.01) and nursery (2.12±0.04 v. 1.80±0.04; P = 0.10) and grow-finish (3.07±0.19 v. 2.58±0.19; P = 0.08) feed to gain tended to be greater, for control gilts. Age at puberty was greater (P = 0.02) for gilts from menhaden oil-fed sows (205.1±3.2 days) compared to gilts from controls (193.9±3.2 days) and tended to be greater (P = 0.09), for controls (203.5±3.2 days) compared to gilts fed menhaden oil (195.5±3.2 days). A tendency existed (P = 0.09) for greater follicular fluid in gilts fed menhaden oil, however, ovulation rate and ovarian, luteal and uterine weights were not affected by sow diet, gilt diet or the interaction (P > 0.23). Feeding gilts menhaden oil enhanced feed efficiency and hastened puberty onset. Gilts from sows consuming menhaden oil exhibited delayed puberty and retaining females from sows fed this feedstuff may be ill advised.

Type
Research Article
Copyright
© The Animal Consortium 2019 

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References

Albert, B, Vickers, M, Gray, C, Reynolds, C, Derraik, J, Cameron-Smith, D and Hofman, P 2015. Supplementation with oxidized fish oil in pregnancy markedly increases neonatal mortality in male rat offspring. International Journal of Pediatric Endocrinology 2015 (suppl. 1), 041.CrossRefGoogle Scholar
Brazle, AE, Johnson, BJ, Webel, SK, Rathbun, TJ and Davis, DL 2009. Omega-3 fatty acids in the gravid pig uterus as affected by maternal supplementation with omega-3 fatty acids. Journal of Animal Science 87, 9941002.CrossRefGoogle ScholarPubMed
Cools, A, Maes, D, Papadopoulos, G, Vandermeiren, J-A, Meyer, E, Demeyere, K, De Smet, S and Janssens, GPJ 2011. Dose-response effect of fish oil substitution in parturition feed on erythrocyte membrane characteristics, and sow performance. Journal of Animal Physiology and Animal Nutrition 95, 125136.CrossRefGoogle ScholarPubMed
Dugan, ME, Vahmani, P, Turner, TD, Mapiye, C, Juarez, M, Prieto, N, Beaulieu, AD, Zijlstra, RT, Patience, JF and Aalhus, JL 2015. Pork as a source of omega-3 (n-3) fatty acids. Journal of Clinical Medicine 4, 19992011.CrossRefGoogle ScholarPubMed
Eastwood, L, Leterme, P and Beaulieu, AD 2014. Changing the omega-6 to omega-3 fatty acid ratio in sow diets alters serum, colostrum, and milk fatty acid profiles, but has minimal impact on reproductive performance. Journal of Animal Science 92, 55675582.CrossRefGoogle ScholarPubMed
Estienne, MJ and Harper, AF 2010. Type of accommodation during gestation affects growth performance and reproductive characteristics of gilt offspring. Journal of Animal Science 88, 400407.CrossRefGoogle ScholarPubMed
Estienne, MJ, Harper, AF and Estienne, CE 2006. Effects of dietary supplementation with omega-3 polyunsaturated fatty acids on some reproductive characteristics in gilts. Reproductive Biology 6, 231241.Google ScholarPubMed
Estienne, MJ, Harper, AF, Horsley, BR, Estienne, CE and Knight, JW 2001. Effects of P.G. 600 on the onset of estrus and ovulation rate in gilts treated with Regu-mate. Journal of Animal Science 79, 27572761.CrossRefGoogle ScholarPubMed
Huber, L-A, Hooda, S, Fisher-Heffernan, RE, Karrow, NA and de Lange, CFM 2018. Effect of reducing the ration of omega-6-to-omega-3 fatty acids in diets of low protein quality on nursery pig growth performance and immune response. Journal of Animal Science 96, 43484359.CrossRefGoogle Scholar
Innis, SM 2005. Essential fatty acid transfer and fetal development. Placenta 26 (suppl.), S70S75.CrossRefGoogle ScholarPubMed
Laws, J, Litten, JC, Laws, A, Lean, IJ, Dodds, PF and Clarke, L 2009. Effect of type and timing of oil supplements to sows during pregnancy on the growth performance and endocrine profile of low and normal birth weight offspring. British Journal of Nutrition 101, 240249.CrossRefGoogle ScholarPubMed
Li, Q, Brendemuhl, JH, Jeong, KC and Badinga, L 2014. Effects of dietary omega-3 polyunsaturated fatty acids on growth and immune response of weanling pigs. Journal of Animal Science and Technology 56, 7.CrossRefGoogle Scholar
Lin, J, Barb, RC, Kraeling, RR and Rampacek, GB. 2001. Developmental changes in the long form leptin receptor and related neuropeptide gene expression in the pig brain. Biology of Reproduction 64, 16141618.CrossRefGoogle Scholar
Mateo, RD, Carroll, JA, Hyun, Y, Smith, S and Kim, SW 2009. Effect of dietary supplementation of n-3 fatty acids and elevated concentrations of dietary protein on the performance of sows. Journal of Animal Science 87, 948959.CrossRefGoogle ScholarPubMed
Moreira, F, Cheuiche, ZMG, Rizzoto, G, Santos, MQ, Schuch, MS, Flach, MJ, Gasperin, BG, Bianchi, I and Lucia, T Jr. 2016. Metabolic and reproductive parameters in prepubertal gilts after omega-3 supplementation in the diet. Animal Reproduction Science 170, 178183.CrossRefGoogle ScholarPubMed
National Research Council (NRC) 2012. Nutrient requirements of swine, 11th revised edition. National Academy Press, Washington, DC, USA.Google Scholar
O’Gorman, CW, Gonzales, E, Eaton, MD, Collard, KA., Reyna, M, Laurenze, JC, Stanko, RL, Keisler, DH, Carroll, JA and Garcia, MR 2007. Fetal exposure to maternal stress influences leptin receptor gene expression during development and age at puberty in gilts. Journal of Animal Science 85 (suppl. 2), 13.Google Scholar
Perez Rigau, A, Lindemann, MD, Kornegay, ET, Harper, AF and Watkins, BA 1995. Role of dietary lipids on fetal tissue fatty acid composition and fetal survival in swine at 42 days of gestation. Journal of Animal Science 73, 13721380.CrossRefGoogle ScholarPubMed
Qian, H, Barb, CR, Compton, MM, Hausman, GJ, Azain, MJ, Kraeling, RR and Baile, CA 1999. Leptin mRNA expression and serum leptin concentrations as influenced by age, weight, and estradiol in pigs. Domestic Animal Endocrinology 16, 135143.CrossRefGoogle ScholarPubMed
Rooke, JA, Sinclair, AG, Edwards, SA, Cordoba, R, Pkiyach, S, Penny, PC, Penny, P, Finch, AM and Horgan, GW 2001. The effect of feeding salmon oil throughout pregnancy on pre-weaning mortality of piglets. Animal Science 73, 489500.CrossRefGoogle Scholar
Santillan, ME, Vincenti, LM, Martini, AC, de Cuneo, MF, Ruiz, RD, Mangeaud, A and Stutz, G 2010. Developmental and neurobehavioral effects of perinatal exposure to diets with different omega-6:omega-3 ratios in mice. Nutrition 26, 423431.CrossRefGoogle ScholarPubMed
Siemelink, M, Verhoef, A, Dormans, JA, Span, PN and Piersma, AH. 2002. Dietary fatty acid composition during pregnancy and lactation in the rat programs growth and glucose metabolism in the offspring. Diabetologia 45, 397403.Google ScholarPubMed
Smit, MN, Patterson, JL, Webel, SK, Spencer, JD, Cameron, AC, Dyck, MK, Dixon, WT and Foxcroft, GR 2013. Responses to n-3 fatty acid (LCPUFA) supplementation of gestating gilts, and lactating and weaned sows. Animal 7, 784792.CrossRefGoogle ScholarPubMed
Smits, RJ, Luxford, BG, Mitchell, M and Nottle, MB 2011. Sow litter size is increased in the subsequent parity when lactating sows are fed diets containing n-3 fatty acids from fish oil. Journal of Animal Science 89, 27312738.CrossRefGoogle ScholarPubMed
Smits, RJ, Luxford, BG, Mitchell, M and Nottle, MB 2013. Embryo survival, but not first-parity litter size, is increased when gilts are fed diets supplemented with omega-3 fatty acids from fish oil. Animal Production Science 53, 5766.CrossRefGoogle Scholar
Tanghe, S and De Smet, S 2013. Does sow reproduction and piglet performance benefit from the addition of n-3 polyunsaturated fatty acids to the maternal diet? The Veterinary Journal 197, 560569.CrossRefGoogle ScholarPubMed
Tsoulis, MW, Chang, PE, Moore, CJ, Chan, KA, Gohir, W, Petrik, JJ, Vickers, MH, Conner, KL and Sloboda, DM 2016. Maternal high-fat diet-induced loss of fetal oocytes is associated with compromised follicle growth in adult rat offspring. Biology of Reproduction 94, 94.CrossRefGoogle Scholar
United States Pork Center of Excellence (USPCE) 2010. National swine nutrition guide. USPCE, Ames, IA, USA.Google Scholar
Wilkinson, SJ, Downing, JA, Thomson, PC and Newman, RE 2013. Dietary fatty acids affect the growth, body composition and performance of post-weaning gilt progeny. Animal Production Science 54, 339346.Google Scholar