Effects of weaning age on growth, nutrient digestibility and metabolism, and serum parameters in Hu lambs Academic research paper on "Animal and dairy science"

Animal Nutrition

" KeAi fe

Accepted Manuscript

Effects of weaning age on growth, nutrient digestibility and metabolism, and serum parameters in Hu lambs

Jianmin Chai, Qiyu Diao, Haichao Wang, Yan Tu, Xiaojing Tao, Naifeng Zhang

PII: S2405-6545(15)30054-8

DOI: 10.1016/j.aninu.2015.11.007

Reference: ANINU 48

To appear in: Animal Nutrition Journal

Received Date: 2 November 2015 Revised Date: 10 November 2015 Accepted Date: 12 November 2015

Please cite this article as: Chai J, Diao Q, Wang H, Tu Y, Tao X, Zhang N, Effects of weaning age on growth, nutrient digestibility and metabolism, and serum parameters in Hu lambs, Animal Nutrition Journal (2015), doi: 10.1016/j.aninu.2015.11.007.

This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

1 Effects of weaning age on growth, nutrient digestibility and metabolism, and serum

2 parameters in Hu lambs

3 Jianmin Chaia, Qiyu Diaoa, Haichao Wanga, Yan Tua, Xiaojing Taob, Naifeng Zhanga*

5 a Feed Research Institute of Chinese Academy of Agricultural Sciences, Key

6 Laboratory of Feed Biotechnology of the Ministry of Agriculture, Beijing 100081,

7 China

8 b Jiangsu Taizhou Helen Sheep Ltd, Taizhou 225300, China

9 10 11 12

14 ^Corresponding author.

15 E-mail address: zhangnaifeng@caas.cn (N. Zhang)

Abstract:

This study was conducted to investigate the effect of weaning age on growth performance, nutrition digestion and metabolism, and serological indicators, and to obtain an optimal weaning age in Hu lambs. Forty-eight newborn Hu lambs (birth weight, 2.53 ± 0.14 kg) were randomly divided into 4 groups. The lambs in control group (ER) suckled their dams. The lambs in other three experimental groups were weaned on milk replacer at 10, 20, and 30 days of age (EW10, EW20, and EW30 groups), respectively. The results were as follows: 1) lambs in EW10 and EW30 groups had a lower (/J<0.05) ADG than those in ER group within 10 days post-weaning; the weaned lambs began to show a higher (P<0.05) ADG than those in ER group after 20 days post-weaning. 2) EW10 and EW20 groups had a higher (/J<0.05) creep feed intake than EW30 and ER groups from 15 to 60 days of age. 3) The apparent digestibility of dry matter, organic matter, gross energy, nitrogen, ether extract and phosphorus, and the deposition of nitrogen and phosphorus did not differ (P>0.05) among groups; however, the apparent digestibility and deposition of calcium in early weaned lambs were lower (/J<0.05) than those in ER lambs. 4) The albumin (ALB) content of EW30 group was lower (/J<0.05) than that in ER group; the globulin (GLB) content of EW30 group was higher (/J<0.05) than that in other groups; the content of serum insulin-like growth factor- I (IGF- I ) in weaned lambs tended to increase compared with lambs in ER group. Finally, the growth rate of lambs decreased within 10 days post-weaning, but early weaning boosted creep feed intake, leading to better growth and health later in life. The Hu lambs can be weaned on milk replacer and creep feed at 10 days of age.

Key words: Lambs; Hu lambs; Early weaning; Milk replacer; Growth development; Digestibility and metabolism; Serum indexes

1. Introduction

Early-weaning of lambs has become a key process for improving the efficiency and profitability of the intensive sheep husbandry. Weaning age, as one of the key parameters in early weaning, is crucial for the success of early-weaning of lambs (Teke and Akdag, 2012). Due to underdevelopment and rapidly growth of gastrointestinal tract, it is essential to obtain the best weaning age to minimize weaning stress and guarantee post-weaning healthy growth of lambs. Weaning lambs on milk replacer instead of solid feed has been steadily gaining ground. However, results on weaning age of lambs vary widely because of the diversity of feeding and management practices and the various genotypes of lambs. Lanza et al. (2006) weaned lambs at 1 day of age and fed them a milk replacer. Yeom et al. (2002) carried out early weaning at 7 days of age. Most previous studies examined the growth rate for a single period, instead of focussing on the growth curve and nutrient metabolism of weaned lambs throughout their production cycle. In addition, weaning at different ages would result in different types of weaning stress, which would affect subsequent growth and health of lambs. It is necessary to find the optimal weaning age for the specific lamb under a specific feeding and management condition. Hu sheep are a prolific indigenous mutton breed in China. However, the weaning age of Hu lambs has not been fully examined(Chen et al., 2012). Therefore, we hypothesized that weaning the Hu lamb on milk replacer at an appropriate age could minimize weaning stress and benefit their later growth. Thus, the objective of this study was to investigate the effect of different weaning ages on growth performance, nutrient digestibility, and serum parameters in Hu lambs, and to obtain an optimal weaning age for improving the efficiency and profitability of intensive Hu lamb production.

2. Materials and methods

68 The experimental procedure was approved by the Animal Ethics Committee of

69 CAAS, and humane animal care and handling procedures were followed throughout

70 the experiment. This study was conducted on the farm of Taizhou Helen Sheep Ltd in

71 Jiangsu Province, China (latitude 32°44'N, longitude 120°24'E), from October to

72 December in 2013.

73 2.1 Experimental design, Animal and diets

74 A single factor randomized design was applied and weaning age of lambs was

75 taken as the experimental factor. Forty-eight Hu lambs (birth weight, 2.53 ± 0.13 kg;

76 24 males and 24 females) were selected based on their birth type, sex, and birth

77 weight and randomly assigned into 4 groups. Each group had 3 replicates with 4

78 lambs per replicate. The lambs were ewe-reared (ER group), or early weaned at 10, 20

79 and 30 days of age (EW10, EW20, and EW30 groups) and fed a milk replacer (MR)

80 (Beijing Precision Animal Nutrition Research Centre, patent number ZL02 128844.5)

81 until 60 days of age. All lambs had ad libitum access to a commercial textured creep

82 feed from 15 to 60 days of age, and their creep feed intake was recorded daily. The

83 nutrient levels of ewe milk, milk replacer, and creep feed are presented in Table 1.

84 Each lamb was weighed at 10, 20, 30, 40, 50 and 60 days of age and average daily

85 gains (ADG) were calculated.

86 2.2 Raising management

87 Ewe-reared lambs stayed with their dams during the whole experimental period

88 but were not allowed to access the ewes' diet. Other weaned lambs were separated

89 from their dams with 4 lambs in a 4 x 2 square metres indoor pen. A 3-day adaptation

90 was carried out to wean lambs gradually from their dams. During the adaptation

91 period, MR was offered gradually according to the body weight of lambs ( 0.67% of

92 BW for d 1, 1.34% of BW for d 2, and 2% of BW for d 3) before the ewe's milk was

totally replaced. The amount of milk replacer given after weaning was adjusted according to the lamb BW (approximately 2%) every 10 days with 3 times daily (0700, 1300, and 1900 h) from 10 to 50 days of age and then 2 times daily (0800, 1800 h) from 51 to 60 days of age. Before feeding, the MR was dissolved in hot water to obtain a 40 °C solution (16.67% dry matter) and offered to each animal with a milk bottle. Clean water was offered ad libitum throughout the trial. 2.3 Sampling and analyses

A digestibility and metabolism trial was carried out from 50 to 60 days of age with 4 lambs randomly selected from each group. Lambs were moved from the floor pens into individual metabolism crates at 50 days of age. During the digestibility trial period, the ewe-reared lambs were put back to their dams to ingest ewe milk about 10 minutes whereas the weaned lambs feeding with MR. After 5 days of adaptation, the amounts of feed intake, faeces and urine were recorded from 56 to 60 days of age. During this time, total faeces were collected and weighed daily. After thorough and uniform mixing, 10% of total faeces was taken and mixed with a few millilitres of 12 M HCL solution. The faecal samples from each lamb were pooled over the 5-day collection period. Total urine was collected into a plastic container containing 100 mL of 12 M HCL solution to maintain pH below 3, the volume was measured, and recorded daily. Then 20% of the total urine was collected and pooled after the 5-day collection period. Samples of feed orts, faeces and urine were frozen in the refrigerator at -20°C for further analysis. After the digestibility trial, the frozen feed, orts, and faecal subsamples were thawed overnight at room temperature and analysed for air dry matter (DM) by drying in an oven at 65 °C for 48 h and ground through a 1-mm sieve. The samples were then analysed for dry matter by drying in an oven at 135°C for 2 h, organic matter (OM) by ashing at 550°C for at least 8 h, crude protein

(CP) using the macro-Kjeldahl procedure that was calculated as 6.25 X N, ether extract (EE) using a reflux system (ANKOM XT 15, America) with petroleum ether at 90°C for 1 h, gross energy (GE) through an isothermic calorimeter (6400 Calorimeter, Parr Instrument Company, Illinois, USA), calcium (Ca) using an atomic absorption spectrometer (Czerny-Turner AAS8000, America), and phosphorus (P) determined by the molybdenum blue colorimetric method (AOAC, 1999).

At 60 days of age, blood samples obtained from 4 lambs per group were collected in heparinized tubes by jugular venipuncture and centrifuged within 2 h at 1,040 x g for 15 min to obtain serum (which was then stored at -20°C for further analysis). The serum concentrations of total protein, albumin, globulin, serum urea nitrogen (SUN), cholesterol, glucose, non-esterified fatty acid (NEFA), triglyceride and alkaline phosphatase (ALP) activity were determined using an automated analyzer (Hitachi 7600, Tokyo, lapan). Insulin-like growth factor I (IGF- I ) concentration was determined using enzyme-linked immunosorbent assay (ELISA) kits (R&D System Inc., Minneapolis, MN, USA). 2.4 Statistical analysis

The data of ADG and creep feed intake were analysed using the PROC MIXED procedure of one-way ANOVA with repeated measures of SAS software and conducted double comparative using LSD method (Version 9.2, SAS Institute Inc., Cary, NC) according to the following model: Yijk^T&Mj+TMij+Cfflik+Eij,

where 7 was the dependent variable, ¡li was the overall mean, T was the effect of group, M was the age after birth, C was the effect of lambs, and e was the residual error. Group differences were considered significant when P < 0.05 and tendencies were discussed when 0.05 < P < 0.10.

Data for nutrient utilization and serum parameters were analysed as a completely randomized design using one-way analysis of variance (Version 9.2, SAS Institute Inc., Cary, NC). Duncan's method for multiple comparisons was used if the overall F test for the measurement was significant (P < 0.05). The results of all data were stated as least-squares means. 3. Results

3.1 Effect of weaning age on growth performance

3.1.1 Lamb ADG

The effect of weaning age on the ADG of lambs is showed in Table 2. The ADG in EW10 group decreased (P < 0.05) from 11 to 20 days of age, whereas it increased (P < 0.05) from 31 to 40 days of age compared with other groups. The ADG in EW30 group was lower (P < 0.05) from 31 to 40 days of age, whereas it was greater from 51 to 60 days of age than that in EW10 and ER groups. The ADG in EW20 group was greater from 41 to 50 and 51 to 60 days of age than that in ER group.

The ADG of lambs among 4 groups was not different (P > 0.05) during the whole trial period and from 1 to 10 and 21 to 30 days of age. However, it significantly increased with increasing age (P < 0.01), and there was a significant interaction effect between group and age.

3.1.2 Lamb creep feed intake

The effect of weaning age on creep feed intake is reported in Table 3. Weaning age had a significant effect on feed intake and there was an interaction effect between group and age. The creep feed intake in EW10 group was not different from ER group from 15 to 20 days of age. However, it increased (P < 0.05) from 21 to 60 days of age compared with ER group. The creep feed intake of EW20 group was greater (P < 0.05) than that of ER group from 31 to 60 days of age. During the whole trial period, the

creep feed intake of EW10 and EW20 groups was greater (P < 0.05) than those of ER group. Furthermore, creep feed intake in EW10 group was greater (P < 0.05) than that in EW20 group. However, there was no difference (P > 0.05) between EW30 and ER groups.

3.2 Effect of weaning age on nutrient digestibility and metabolism

The apparent digestibility of dry matter, organic matter, gross energy, nitrogen, ether extract and phosphorus, and the deposition of nitrogen and phosphorus was not different (P > 0.05) among groups (Table 4). The weaned lambs had a lower (P < 0.05) apparent digestibility and deposition of calcium compared with ewe-reared lambs. 3.2 Effect of weaning age on serum parameters

Effect of weaning age on serum parameters of lambs is presented in Table 5.The ALB concentration was lower (P < 0.05) in EW30 group than that in ER group. The GLB concentration in the EW30 group was higher (P < 0.05) than that in other groups. The GLB in EW10 and EW20 groups was greater (P < 0.05) than that in ER group. No difference in the serum concentration of GLU, TP, SUN, cholesterol, triglyceride, NEFA, IGF- I and ALP was observed among groups. However, the concentration of IGF- I in weaned lambs was trended to increase (P < 0.10) compared with ER lambs. 4. Discussion

4.1 Effect of weaning age on growth performance in lambs

In the current study, the growth rate of weaned lambs decreased at first 10-day post-weaning compared with ewe-reared lambs. It was the weaning stress caused by separating from their dams, changing of diets and feeding regime that limited the lamb growth (Napolitano et al., 2008). Emsen et al. (2004) reported that lambs weaned at 2 or 3 days of age had a lower BW at 15 days of age than ewe-reared lambs. After ten days of post-weaning, it appeared that the early-weaned lambs were used to

the new feeding regime and rearing environment in our study. Meanwhile, the nutrient content of MR maybe fulfilled the nutrient requirement of lambs in the later period. All these led to a greater ADG in early-weaned lambs. Similarly, Bhatt et al. (2009) founded that early weaned lambs had a higher BW in later period of post-weaning. Emsen et al. (2004) also reported that the group fed with MR had a more rapid growth than the control after lambs adapting new feeding regime. Furthermore, lambs weaned at 10 days of age had a faster recoverability to grow. It was speculated that the earlier weaning of lambs resulted in a smaller psychological stress from the separation with the ewes (Simitzis et al., 2012) and an ability to consume more creep feed (Alvarez-Rodriguez et al., 2010).

Weaning on ewe milk and feeding milk replacer can boost creep feed intake. In this study, lambs in EW10 and EW20 groups had a greater creep feed intake than lambs in EW30 and ER groups, especially the EW10 lambs. The creep feed intake was correlated with rumen development. The rumen function establishment of lambs begins at 3 weeks of age when rumen epithelial cell proliferation is sensitive to the stimulus of plant protein or solid feed. Ghorbani et al. (2007) reported that feeding MR was important for the development of rumen of lambs and therefore improved creep intake ensued. Similarly, Alvarez-Rodriguez et al. (2010) also confirmed that early-weaned lambs had a higher creep feed intake than suckling lambs. Therefore, earlier weaning on MR and subsequent higher creep feed intake in EW10 and EW20 groups should stimulate and enhance the earlier rumen development, which leads to a greater growth rate. However, the higher creep feed intake was not observed in lambs weaned at 30 days of age. It is speculated that the long time lambs relying on their dams may have retarded their adaption to the MR and creep feed. 4.2 Effect of weaning age on nutrient utilization in lambs

218 Nutrient utilization can reflect the lamb gastrointestinal characteristics and

219 productivity. Nutrient digestibility and metabolism of lambs weaned at different ages

220 varies as gastrointestinal development is affected due to weaning stress (Zhong et al.,

221 2014). In the current study, no difference was observed among different treatments on

222 the digestibility and utilization of main nutrients. The ewe-reared lambs reduced their

223 milk intake as time went by and also had a lower intake of creep feed compared with

224 early-weaned lambs. However, the ewe-reared lambs had a lower average daily gain

225 compared with early-weaned lambs from 50 to 60 days of age. While the

226 early-weaned lambs with high creep feed intake and average daily gain were observed,

227 the nutrient utilization was likely similar. In a similar study, Danso et al. (2014)

228 reported that feeding MR plus creep significantly increased growth performance and

229 organ development of lambs, however, did not affect the efficiency of feed utilization.

230 The current results were similar to previous studies, suggesting it may be possible for

231 artificially-reared or ewe-reared lambs to have a similar gastrointestinal development.

232 However, the early-weaned lambs had a lower apparent digestibility and deposition of

233 Ca compared with ewe-reared lambs in this study. It was likely due to the inorganic

234 calcium salt added in MR, which affected the Ca digestibility.

235 4.3 Effect of weaning age on serum parameters in lambs

236 The serum glucose concentration reflects energy utilisation of ruminants. When

237 serum glucose concentration decreases, it indicates the lack of dietary energy or poor

238 energy utilization. In this study, the serum glucose concentration was not affected

239 which was consistent with the energy digestibility result.

240 The serum total protein, mainly including albumin and globulin, is the main solid

241 component in serum and is an indicator of the nutritional status of the animal. In this

242 study, TP concentration was not affected by weaning age, which was in accordance

with the results of Paez Lama et al. (2014) who reared Criollo kids under two different rearing systems. The serum globulin concentration in early-weaned lambs was higher than that in ewe-reared lambs. Globulin can inactivate and degrade antigen proteins in the body and its content can reflect the animal's immune status (Li et al., 2008). Passive immunity of lambs is inherited from their dams by ingesting colostrum, whereas acquired immunity is developed with the growth and development of lambs (Loste et al., 2008). Therefore, the early weaning of lambs probably strengthened the acquired immunity compared with the ewe-reared lambs and had a high globulin value. However, the immunity of weaned lambs is the topic of future research.

The SUN can reflect the state of protein metabolism in lambs and its concentration is related to dietary nitrogen substance and protein utilization (Stanley et al., 2002). The SUN concentration was not different among the 4 experimental groups. It demonstrated that the N utilization was not affected by the weaning age.

The serum lipid concentration is often correlated with the body lipid metabolism. In the study, serum cholesterol, triglyceride and NEFA concentrations were no difference among groups, which explained the undifferentiated EE digestibility.

As well known, the growth factor, IGF- I , is important for lamb development. In this study, the serum concentration of IGF- I in weaned lambs trended to increase. Hoffman et al. (2014) stated that animals with poor nutrition will be reduced growth rate because of reduced circulating IGF-I. Therefore, this result was a proof of the great growth rate of weaned lambs.

The serum ALP could be used as a marker of bone growth and is positive correlated with ADG (Hill et al., 2010). Although there was no significant difference among groups, the higher ALP value was apparently correlated with the higher ADG in weaned lambs compared with ewe-reared lambs.

5. Conclusion

In this study, there was a growth check in early-weaned lambs within 10 days post-weaning. After adapting the feeding regime, the weaned lambs fed MR had a higher creep feed intake and growth rate. Overall, the lamb can be weaned on MR at 10 days of age. Acknowledgement

This work was supported by the Special Fund for Agro-scientific Research in the Public Interest (201303143) and China Scholarship Council Fund (201403250010). The authors are grateful to professor Ziyu Wang (worked in Nanjing Agricultural University) and Chunhua Meng (worked in Institute of Livestock Science of Jiangsu Academy of Agricultural Sciences) for assistance in carrying out the experiment. References

Alvarez-Rodriguez J, Sanz A, Ripoll-Bosch R, Joy M. Do alfalfa grazing and lactation length affect the digestive tract fill of light lambs? Small Ruminant Research 2010; 94:109-116.

AOAC. Official Official methods of analysis of the Association of Official Analytical Chemist (16th ed.). AOAC, International, Gaithersburg (United States) 1999.

Bhatt RS, Tripathi MK, Verma DL, Karim SA. Effect of different feeding regimes on pre-weaning growth rumen fermentation and its influence on post-weaning performance of lambs. Journal of Animal Physiology & Animal Nutrition 2009; 93:568-576.

Chen L, Liu K, Zhao Z, Blair HT, Zhang P, Li D, Ma RZ. Identification of Sheep Ovary Genes Potentially Associated with Off-season Reproduction. Journal of Genetics and Genomics 2012; 39: 181-190.

293 Danso AS, Morel P, Kenyon PR, Blair HT. Effect of early life diet on lamb

294 growth and organ development. Proceedings of the New Zealand Society of Animal

295 Production 2014; 74: 205-208.

296 Emsen E, Yaprak M, Bilgin OC, Emsen B, Ockerman HW. Growth performance

297 of Awassi lambs fed calf milk replacer. Small Ruminant Research 2004; 53: 99-102.

298 Ghorbani GR, Kowsar R, Alikhani M, Nikkhah A. Soymilk as a Novel Milk

299 Replacer to Stimulate Early Calf Starter Intake and Reduce Weaning Age and Costs.

300 Journal of dairy science 2007; 90: 5692-5697.

301 Hill TM, Bateman Ii HG, Aldrich JM, Schlotterbeck RL. Effect of milk replacer

302 program on digestion of nutrients in dairy calves. Journal of dairy science 2010; 93:

303 1105-1115.

304 Hoffman ML, Rokosa MA, Zinn SA, Hoagland TA, Govoni KE. Poor maternal

305 nutrition during gestation in sheep reduces circulating concentrations of insulin-like

306 growth factor-I and insulin-like growth factor binding protein-3 in offspring.

307 Domestic Animal Endocrinology 2014; 49: 39-48.

308 Lanza M, Bella M, Priolo A, Barbagallo D, Galofaro V, Landi C, Pennisi P.

309 Lamb meat quality as affected by a natural or artificial milk feeding regime. Meat

310 science 2006; 73: 313-318.

311 Li H, Diao QY, Zhang NF, Tu Y, Wang JF. Effect of Different Protein Levels On

312 Nutrient Digestion Metabolism and Serum Biochemical Parameters in Calves.

313 Agricultural Sciences in China 2008; 7: 375-380.

314 Loste A, Ramos JJ, Fern A, aacutendez, Ferrer LM, Lacasta D, Verde MT, Marca

315 MC, Ort A. Effect of colostrum treated by heat on immunological parameters in

316 newborn lambs. Livestock Science 2008; 117: 176-183.

317 Napolitano F, Rosa GD, Sevi A. Welfare implications of artificial rearing and

early weaning in sheep. Appl. Anim. Behav. Sci. 2008; 110: 58-72.

NRC. Nutrient Requirements of Small Ruminants: Sheep, Goats, Cervids, and New World Camelids. Natl. Acad. Press, Washington, DC (2007).

Paez Lama S, Grilli D, Egea V, Fucili M, Allegretti L, Guevara JC. Rumen development and blood metabolites of Criollo kids under two different rearing systems. Livestock Science 2014; 167: 171-177.

Simitzis P, Petrou M, Demiris N, Deligeorgis S. Effect of pre-weaning temporary isolation within different age periods on the early post-weaning behaviour of juvenile lambs. Appl. Anim. Behav. Sci. 2012; 141: 43-48.

Stanley C, Williams C, Jenny B, Fernandez J, Bateman II H, Nipper W, Lovejoy J, Gantt D, Goodier G. Effects of feeding milk replacer once versus twice daily on glucose metabolism in Holstein and Jersey calves. Journal of dairy science 2002; 85: 2335-2343.

Teke B, Akdag F. The effects of age of lamb and parity of dam and sex and birth type of lamb on suckling behaviours of Karayaka lambs. Small Ruminant Research 2012; 103:176-181.

Wang B, Chai JM, Wang HC, Qi ML, Zhang NF, Diao QY. Effects of Protein Levels on Growth Development and Meat Quality of Male Hu Twin Lamb. Chinese Journal of Animal Nutrition 2015; 27: 2724-2735.

Yeom KH, Van Trierum G, Hovenier R, Schellingerhout AB, Lee KW, Beynen AC. Fatty acid composition of adipose tissue in goat kids fed milk replacers with different contents of a-linolenic and linoleic acid. Small Ruminant Research 2002; 43: 15-22.

Zhong RZ, Sun HX, Li GD, Liu HW, Zhou DW. Effects of inoculation with rumen fluid on nutrient digestibility, growth performance and rumen fermentation of

343 early weaned lambs. Livestock Science 2014; 162: 154-158.

345 Table 1

346 Nutrient levels of ewe milk, milk replacer and creep feed (dry-matter basis).1

Item Ewe milk Milk replacer Creep feed

DM, % 31.12 94.47 86.37

ME, MJ/kg 19.11 17.69 13.30

CP, % 24.71 24.80 19.58

EE, % 45.27 15.43 3.77

Ash, % 4.14 7.70 8.52

Ca, % 3.70 1.02 0.95

TP, % 0.72 0.66 0.70

347 DM = dry matter; ME = metabolic energy; CP = crude protein; EE = ether extract; TP

348 = total phosphorus.

349 1Nutrient levels were measured except ME. Metabolic energy of milk replacer was

350 calculated according to the results of Wang et al. (2015) and NRC (2007), and that of

351 creep feed was calculated according to Table of Feed Composition and Nutritive

352 Values in China 2012 and NRC (2007), and that of ewe milk was calculated according

353 to the results of digestive and metabolic experiments in the current study.

354 Table 2 Effect of weaning age on the average daily gain (g/d) of lambs.

Age, d Group1 SEM P-value

EW10 EW20 EW30 ER Age Group Age x group

1 to 60 190.49 180.27 178.75 171.26 5.36 <0.0001 0.3794 <0.0001

1 to 10 190.17 195.73 207.00 199.09 10.38

11 to 20 56.25a 129.73b 116.42b 107.00b 9.48

21 to 30 104.42 82.64 94.33 90.45 8.92

31 to 40 271.75a 115.73bc 76.83c 193.55b 11.50

41 to 50 252.50a 264.91a 238.33ab 204.27b 11.41

51 to 60 270.83bc 305.82ab 335.58a 240.55c 10.75

355 Within a row, means without a common superscript differ significantly (P < 0.05).

356 1The lambs were ewe-reared (ER group), or early weaned at 10, 20 and 30 days of age

357 (EW10, EW20, and EW30 groups) and fed with milk replacer.

359 Table 3 Effect of weaning age on the creep feed intake (g/d-lamb) of lambs.

Age, d Group1 SEM P-value

EW10 EW20 EW30 ER Age Group Age x group

15 to 60 260.33a 182.91b 154.75c 153.75c 8.13 <0.0001 <0.0001 <0.0001

15 to 20 32.38 10.97 10.18 11.28 1.46

21 to 30 126.69a 41.18b 30.17b 29.07b 6.43

31 to 40 251.37a 184.61b 116.26c 91.47c 9.56

41 to 50 367.34a 289.08b 268.55c 250.75c 8.96

51 to 60 523.87a 388.71b 398.58b 386.19b 10.81

360 Within a row, means without a common superscript differ significantly (P < 0.05).

361 1The lambs were ewe-reared (ER group), or early weaned at 10, 20 and 30 days of age

362 (EW10, EW20, and EW30 groups) and fed with milk replacer.

364 Table 4 Effect of weaning age on the digestion and deposition of nutrients of lambs

365 (%).

Group1

EW10 EW20 EW30 ER

SEM P-value

DM 81.78 83.89 81.82 81.60 0.62 0.5528

OM 83.46 85.44 83.47 84.04 0.74 0.7907

GE 80.96 83.79 82.24 82.74 0.67 0.5630

N 81.46 83.77 81.76 82.92 0.52 0.3924

EE 88.03 91.35 91.15 94.33 1.07 0.2357

Ca 60.29a 52.07a 56.80a 93.52b 4.89 0.0003

P 77.27 82.61 79.74 83.83 1.85 0.6377

N deposition 52.82 52.98 52.00 53.26 3.85 0.9996

Ca deposition 60.14a 51.76a 56.41a 93.34b 4.91 0.0003

P deposition 65.24 68.21 61.91 74.84 2.36 0.2651

366 DM = dry matter; OM = organic matter; GE = gross energy; CP = crude protein; EE =

367 ether extract.

368 Within a row, means without a common superscript differ significantly (P < 0.05).

369 1The lambs were ewe-reared (ER group), or early weaned at 10, 20 or 30 days of age

370 (EW10, EW20, and EW30 groups) and fed with milk replacer.

372 Table 5 Effect of weaning age on the serum parameters of lambs

Group1

Item - SEM P-value

EW10 EW20 EW30 ER

Glucose, mmol/L 8.66 7.75 8.70 8.20 0.21 0.2334

Total protein, g/L 49.63 48.23 49.78 43.33 0.88 0.2300

Albumin, g/L 33.94ab 31.91ab 29.95b 37.55a 0.84 0.0004

Globulin, g/L 15.70b 16.33b 19.83a 7.84c 1.22 0.0028

SUN, mmol/L 11.00 13.24 12.39 12.38 0.84 0.2383

Cholesterol, mmol/L 2.49 2.58 2.12 2.59 0.09 0.3993

Triglyceride, mmol/L 0.36 0.43 0.37 0.35 0.02 0.4710

NEFA, nmol/L 506.76 519.03 556.87 586.71 16.97 0.1668

IGF- I , ng/mL 150.20 121.21 128.65 110.75 7.28 0.0773

ALP, U/L 183.06 172.72 151.87 149.99 13.91 0.2291

373 SUN = serum urea nitrogen; NEFA = non-esterified fatty acid; IGF- I = Insulin-like

374 growth factor I ; ALP = alkaline phosphatase.

375 Within a row, means without a common superscript differ significantly (P < 0.05).

376 'The lambs were ewe-reared (ER group), or early weaned at 10, 20 or 30 days of age

377 (EW10, EW20, and EW30 groups) and fed with milk replacer.