Department of Animal Science, North Carolina State University, Raleigh 27695, USA.
J Anim Sci. 2010 Mar;88(3):1009-16. doi: 10.2527/jas.2008-1730. Epub 2009 Nov 20.
Although concerns over the environmental impact of excess P in the excreta from pig production and governmental regulations have driven research toward reducing dietary supplementation of P to swine diets for over a decade, recent dramatic increases in feed costs have further motivated researchers to identify means to further reduce dietary P supplementation. We have demonstrated that genetic background impacts P utilization in young pigs and have identified genetic polymorphisms in several target genes related to mineral utilization. In this study, we examined the impact of a SNP in the calcitonin receptor gene (CALCR) on P utilization in growing pigs. In Exp. 1, 36 gilts representing the 3 genotypes identified by this CALCR SNP (11, 12, and 22) were fed a P-adequate (PA) or a marginally P-deficient (approximately 20% less available P; PD) diet for 14 wk. As expected, P deficiency reduced plasma P concentration, bone strength, and mineral content (P < 0.05). However, the dietary P deficiency was mild enough to not affect the growth performance of these pigs. A genotype x dietary P interaction (P < 0.05) was observed in measures of bone integrity and mineral content, with the greatest reduction in bone strength and mineral content due to dietary P deficiency being associated with the allele 1. In Exp. 2, 168 pigs from a control line and low residual feed intake (RFI) line were genotyped for the CALCR SNP and fed a PA diet. As expected, pigs from the low RFI line consumed less feed but also gained less BW when compared with the control line (P < 0.05). Although ADFI did not differ between genotypes, pigs having the 11 genotype gained less BW (P < 0.05) than pigs having the 12 or 22 genotypes. Pigs of the 11 and 12 genotypes had bones that tolerated greater load when compared with animals having the 22 genotype (P < 0.05). A similar trend was observed in bone modulus and ash % (P < 0.10). These data are supportive of the association of this CALCR SNP with bone integrity and its response to dietary P restriction. Although the allele 1 is associated with greater bone integrity and mineral content during adequate P nutrition, it is also associated with the greatest loss in bone integrity and mineral content in response to dietary P restriction. Understanding the underlying genetic mechanisms that regulate P utilization may lead to novel strategies to produce more environmentally friendly pigs.
虽然人们对猪生产排泄物中过量磷对环境的影响以及政府法规感到担忧,这促使研究人员在过去十年中致力于减少猪日粮中磷的添加量,但最近饲料成本的大幅上涨进一步促使研究人员寻找进一步减少日粮磷添加量的方法。我们已经证明遗传背景会影响小猪对磷的利用,并在与矿物质利用相关的几个靶基因中发现了遗传多态性。在这项研究中,我们研究了降钙素受体基因(CALCR)中的 SNP 对生长猪磷利用的影响。在实验 1 中,36 头代表该 CALCR SNP 确定的 3 种基因型(11、12 和 22)的母猪被喂食磷充足(PA)或磷轻度缺乏(大约 20%的可利用磷缺乏;PD)日粮 14 周。正如预期的那样,磷缺乏降低了血浆磷浓度、骨强度和矿物质含量(P<0.05)。然而,这种饮食磷缺乏程度不足以影响这些猪的生长性能。在骨骼完整性和矿物质含量的测量中观察到基因型 x 饮食磷的相互作用(P<0.05),由于饮食磷缺乏导致的骨强度和矿物质含量的最大降低与等位基因 1 相关。在实验 2 中,来自对照系和低残余饲料摄入量(RFI)系的 168 头猪被 CALCR SNP 基因型,并喂食 PA 日粮。正如预期的那样,与对照系相比,低 RFI 系的猪消耗的饲料更少,但体重增加也更少(P<0.05)。尽管基因型之间的 ADFI 没有差异,但具有 11 基因型的猪比具有 12 或 22 基因型的猪体重增加更少(P<0.05)。与具有 22 基因型的动物相比,具有 11 和 12 基因型的猪的骨骼能够承受更大的载荷(P<0.05)。在骨模量和灰分百分比(P<0.10)中也观察到类似的趋势。这些数据支持该 CALCR SNP 与骨骼完整性及其对饮食磷限制的反应之间的关联。尽管等位基因 1 与充足磷营养下更大的骨骼完整性和矿物质含量相关,但它也与饮食磷限制下骨骼完整性和矿物质含量的最大损失相关。了解调节磷利用的潜在遗传机制可能会导致产生更环保的猪的新策略。
