Effects of different amylose to amylopectin ratios in starter feed on the development of ruminal epithelium in pre-weaned lambs

doi:10.11686/cyxb2017396

Abstract

Abstract: The objective of this study was to investigate the effects of different amylose to amylopectin ratio in starter feed on the development of the ruminal epithelium in pre-weaned lambs. Twenty-four 10-day-old lambs were divided into three groups, and were fed on iso-starch diets containing cassava starch (CS, n=8), maize starch (MS, n=8), and pea starch (PS, n=8). The lambs were separated from their mothers from 4:00-19:00 every day and placed in individual pens. The lambs received starter feed with different amylose-to-amylopectin ratios (CS, MS, and PS) ad libitum. Lambs were fed with their mothers’ milk for 1 h at fixed times (6:30, 10:30, and 15:30) during this period. All lambs received oat hay and water ad libitum. The lambs were slaughtered at 56 days old. Part of the ruminal tissue sample was used for morphological observations. Another part of the ruminal tissue sample was used to extract RNA to quantify the mRNA levels of various genes. Compared with the MS and PS diets, the CS diet significantly (P<0.001) increased the length and surface of rumen papillae in lambs. The rumen papillae of lambs were significantly wider (P=0.001) in CS and MS group than in the PS group. The thickness of different strata of the rumen epithelium in lambs was measured. The stratum corneum was significantly thicker in the CS and PS groups (P<0.001) than in the MS group. The stratum granulosum was significantly thicker in the CS and MS groups (P<0.001) than in the PS group. The total strata, stratum spinosum, and basale of the rumen epithelium were significantly thicker in the CS group (P<0.001) than in the MS and PS groups. The qRT-PCR results showed that different amylose to amylopectin ratios in the starter feed significantly affected the transcript levels of CDK2 and CDK6 (CS>MS>PS, P<0.001); the transcript levels of cyclin A and CDK4 were significantly higher in the CS group (P<0.05) than in the PS group. The transcript level of cyclin D1 was significantly lower in the CS group (P=0.012) than in the PS group. The transcript level of IGF-1 was significantly higher in the CS group (P<0.001) than in the MS and PS groups. The transcript levels of IGF-1R were significantly higher in the CS and MS groups (P=0.001) than in the PS group. These results indicated that a high amylopectin ratio in starch in starter feed promoted ruminal epithelial growth, which was associated with up-regulated expressions of IGF-1 and cell cycle protein in pre-weaned lambs. The results of this study have important significance for formulating appropriate nutritional strategies for lambs.

Key words: starch, ruminal epithelia, cell proliferation, insulin-like growth factor-1, lamb

SUN Da-ming, LI Hong-wei, MAO Sheng-yong, LIU Jun-hua. Effects of different amylose to amylopectin ratios in starter feed on the development of ruminal epithelium in pre-weaned lambs[J]. Acta Prataculturae Sinica, 2018, 27(8): 197-203.

References

[1] Liu T, Li F D, Wang W M, et al . Effects of starter feeding on rumen papilla genes expression involved in cellular growth and morphology in hu lamb at different ages. Acta Veterinaria et Zootechnica Sinica, 2016, (12): 2441-2449.
刘婷, 李发弟, 王维民, 等. 不同日龄补饲开食料对湖羊羔羊瘤胃形态及表皮生长相关基因表达的影响. 畜牧兽医学报, 2016, 47(12): 2441-2449.
[2] Heinrichs A J, Heinrichs B S. A prospective study of calf factors affecting first-lactation and lifetime milk production and age of cows when removed from the herd. Journal of Dairy Science, 2011, 94(1): 336-341.
[3] Oates C G. Towards an understanding of starch granule structure and hydrolysis. Trends in Food Science & Technology, 1997, 8(11): 375-382.
[4] Stevnebo A, Seppala A, Harstad O M, et al . Ruminal starch digestion characteristics in vitro of barley cultivars with varying amylose content. Animal Feed Science and Technology, 2009, 148(2): 167-182.
[5] Ren W, Zhao F F, Zhang A Z, et al . Gastrointestinal tract development in fattening lambs fed diets with different amylose to amylopectin ratios. Canadian Journal of Animal Science, 2016, 96(3): 425-433.
[6] Ghoorchi T, Lund P, Larsen M, et al . Assessment of the mobile bag method for estimation of in vivo starch digestibility. Animal, 2013, 7(2): 265-271.
[7] Moharrery A, Larsen M, Weisbjerg M R. Starch digestion in the rumen, small intestine, and hind gut of dairy cows-a meta-analysis. Animal Feed Science and Technology, 2014, 192: 1-14.
[8] Lesmeister K E, Heinrichs A J. Effects of corn processing on growth characteristics, rumen development, and rumen parameters in neonatal dairy calves. Journal of Dairy Science, 2004, 87(10): 3439-3450.
[9] Steele M A, Croom J, Kahler M, et al . Bovine rumen epithelium undergoes rapid structural adaptations during grain-induced subacute ruminal acidosis. American Journal of Physiology-Regulatory, Integrative and Comparative Physiology, 2011, 300(6): 1515-1523.
[10] Chomczynski P, Sacchi N. Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Analytical Biochemistry, 1987, 162(1): 156-159.
[11] Wang A, Gu Z, Heid B, et al . Identification and characterization of the bovine G protein-coupled receptor GPR41 and GPR43 genes. Journal of Dairy Science, 2009, 92(6): 2696-2705.
[12] Wang X J, Liu T, Li F D, et al . Effect of starter supply age on the morphology of the rumen and small intestine in lamb. Acta Prataculturae Sinica, 2016, 25(4): 172-178.
汪晓娟, 刘婷, 李发弟, 等. 开食料补饲日龄对羔羊瘤胃和小肠组织形态的影响. 草业学报, 2016, 25(4): 172-178.
[13] Khan M A, Lee H J, Lee W S, et al . Starch source evaluation in calf starter: II. Ruminal parameters, rumen development, nutrient digestibilities, and nitrogen utilization in Holstein calves. Journal of Dairy Science, 2008, 91(3): 1140-1149.
[14] Filmus J, Robles A I, Shi W, et al . Induction of cyclin D 1 overexpression by activated ras. Oncogene, 1994, 9(12): 3627-3633.
[15] Norbury C, Nurse P. Animal cell cycles and their control. Annual Review of Biochemistry, 1992, 61(1): 441-468.
[16] Jeffrey P D, Russo A A, Polyak K, et al . Mechanism of CDK activation revealed by the structure of a cyclin A-CDK2 complex. Nature, 1995, 376: 313-320.
[17] Kanakkanthara A, Jeganathan K B, Limzerwala J F, et al . Cyclin A2 is an RNA binding protein that controls Mre11 mRNA translation. Science, 2016, 353: 1549-1552.
[18] Girard F, Strausfeld U, Fernandez A, et al . Cyclin A is required for the onset of DNA replication in mammalian fibroblasts. Cell, 1991, 67(6): 1169-1179.
[19] Lu J, Zhao H, Xu J, et al . Elevated cyclin D 1 expression is governed by plasma IGF-1 through Ras/Raf/MEK/ERK pathway in rumen epithelium of goats supplying a high metabolizable energy diet. Journal of Animal Physiology and Animal Nutrition, 2013, 97(6): 1170-1178.
[20] Shen Z, Seyfert H M, Lohrke B, et al . An energy-rich diet causes rumen papillae proliferation associated with more IGF type 1 receptors and increased plasma IGF- 1 concentrations in young goats. The Journal of Nutrition, 2004, 134(1): 11-17.