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Increased dietary protein in the second trimester of gestation increases live weight gain and carcass composition in weaner calves to 6 months of age

Published online by Cambridge University Press:  08 November 2016

G. G. Miguel-Pacheco
Affiliation:
School of Veterinary Medicine and Science, University of Nottingham, Sutton Bonington LE12 5RD, UK
L. D. Curtain
Affiliation:
School of Animal Studies, University of Queensland, Gatton, QLD 4345, Australia
C. Rutland
Affiliation:
School of Veterinary Medicine and Science, University of Nottingham, Sutton Bonington LE12 5RD, UK
L. Knott
Affiliation:
School of Veterinary Science, University of Queensland, Gatton, QLD 4345, Australia
S. T. Norman
Affiliation:
School of Animal and Veterinary Sciences, Charles Sturt University, Wagga Wagga, NSW 2650, Australia
N. J. Phillips
Affiliation:
School of Veterinary Science, University of Queensland, Gatton, QLD 4345, Australia
V. E. A. Perry*
Affiliation:
School of Veterinary Medicine and Science, University of Nottingham, Sutton Bonington LE12 5RD, UK Robinson Research Institute, School of Medicine, University of Adelaide, Frome Road, SA 5001, Australia
*

Abstract

Genetically similar nulliparous Polled Hereford heifers from a closed pedigree herd were used to evaluate the effects of dietary protein during the first and second trimester of gestation upon foetal, placental and postnatal growth. Heifers were randomly allocated into two groups at 35 days after artificial insemination (35 days post conception (dpc)) to a single bull and fed high (15.7% CP) or low (5.9% CP) protein in the first trimester (T1). At 90 dpc, half of each nutritional treatment group changed to a high- or low-protein diet for the second trimester until 180 dpc (T2). High protein intake in the second trimester increased birth weight in females (P=0.05), but there was no effect of treatment upon birth weight when taken over both sexes. Biparietal diameter was significantly increased by high protein in the second trimester with the effect being greater in the female (P=0.02), but also significant overall (P=0.05). Placental weight was positively correlated with birth weight, fibroblast volume and relative blood vessel volume (P<0.05). Placental fibroblast density was increased and trophoblast volume decreased in the high-protein first trimester treatment group (P<0.05). There was a trend for placental weight to be increased by high protein in the second trimester (P=0.06). Calves from heifers fed the high-protein treatment in the second trimester weighed significantly more on all occasions preweaning (at 1 month (P=0.0004), 2 months (P=0.006), 3 months (P=0.002), 4 months (P=0.01), 5 months (P=0.03), 6 months (P=0.001)), and grew at a faster rate over the 6-month period. By 6 months of age, the calves from heifers fed high nutrition in the second trimester weighed 33 kg heavier than those fed the low diet in the second trimester. These results suggest that dietary protein in early pregnancy alters the development of the bovine placenta and calf growth to weaning.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Animal Consortium 2016

Implications

Protein supplementation during pregnancy in nulliparous heifers may significantly increase growth rate and muscle development in the progeny. This may have significant financial implications to the cattle producer. This effect may in part be executed via the observed adaptations in the developing placenta.

Introduction

It is well established from epidemiological studies in human populations and experimental studies in a range of animal models that varying maternal nutrition during critical periods of foetal development can alter or ‘program’ body mass and body composition in later life (Symonds et al., Reference Talbot, Caperna, Edwards, Garrett, Wells and Ealy2004; Micke et al., Reference Micke, Sullivan, Kennaway, Hernandez-Medrano and Perry2010a; Micke et al., Reference Micke, Sullivan, McMillen, Gentili and Perry2011a; Micke et al., Reference Micke, Sullivan, McMillen, Gentili and Perry2011b). Range cattle managed under extensive conditions experience such variations in maternal nutrition sufficient to affect foetal programming and thereby the postnatal growth and carcass characteristics of their progeny (Cafe et al., Reference Cafe, Hennessy, Hearnshaw, Morris and Greenwood2006; Greenwood et al., Reference Greenwood, Cafe, Hearnshaw, Hennessy and Morris2006; Martin et al., Reference Martin, Vonnahme, Adams, Lardy and Funston2007; Micke et al., Reference Micke, Sullivan, Kennaway, Hernandez-Medrano and Perry2010a; Summers et al., Reference Symonds, Pope, Sharkey and Budge2015). Maternal nutrient supply to the foetus regulates the foetal IGF axis (Oliver et al., Reference Perry, Norman, Daniel, Owens, Grant and Doogan1996; Sullivan et al., Reference Sullivan, Micke, Magalhaes, Phillips and Perry2009a) and can programme the postnatal IGF axis (Micke et al., Reference Micke, Sullivan, Kennaway, Hernandez-Medrano and Perry2010a; Symonds et al., Reference Symonds, Pearce, Bispham, Gardner and Stephenson2012). Calf plasma IGF-1 at birth is positively associated with birth weight (Breier et al., Reference Breier, Gluckman and Bass1988; Micke et al., Reference Micke, Sullivan, Kennaway, Hernandez-Medrano and Perry2010a), as is postnatal IGF concentration with average daily gain (ADG) and linear growth (Lund-Larsen et al., Reference Lund-Larsen, Sundby, Kruse and Velle1977; Micke et al., Reference Micke, Sullivan, Kennaway, Hernandez-Medrano and Perry2010a; Micke et al., Reference Micke, Sullivan, Soares Magalhaes, Rolls, Norman and Perry2010b). The reported effects of foetal programming upon ADG and carcass development in cattle progeny is however inconsistent (Greenwood et al., Reference Greenwood, Cafe, Hearnshaw and Hennessy2005; Micke et al., Reference Micke, Sullivan, McMillen, Gentili and Perry2011b; Summers et al., Reference Symonds, Pope, Sharkey and Budge2015). The disparity recorded between these studies may be influenced by the genetic heterogeneity, and age of the dams observed as well as timing of intervention: the Greenwood et al. (Reference Greenwood, Cafe, Hearnshaw and Hennessy2005) study used both pluriparous and nulliparous dams, whereas the Micke et al. (Reference Micke, Sullivan, McMillen, Gentili and Perry2011b) and Summers et al. (Reference Symonds, Pope, Sharkey and Budge2015) only nulliparous, with each study using different relatively diverse genotypes and intervention periods.

In this study, nulliparous Polled Hereford heifers from a closed stud herd mated at 15 months of age were used, ensuring a reduction in genetic variation within the dams and enabling focus upon the adolescent yearling heifer which has been shown to be more susceptible to foetal growth restriction following gestational nutritional perturbation (Copping et al., Reference Copping, Hoare, Callaghan, McMillen, Rodgers and Perry2014; Hernandez-Medrano et al., Reference Hernandez-Medrano, Copping, Hoare, Wapanaar, Grivell, Kuchel, Miguel-Pacheco, McMillen, Rodgers and Perry2015). Based on our former studies (Perry et al., Reference Perry, Norman, Owen, Daniel and Phillips1999; Sullivan et al., Reference Sullivan, Micke, Magalhaes, Martin, Wallace, Green and Perry2009b; Micke et al., Reference Micke, Sullivan, Kennaway, Hernandez-Medrano and Perry2010a; Micke et al., Reference Micke, Sullivan, Rolls, Hasell, Greer, Norman and Perry2015), we hypothesise that low protein in the first trimester will enhance placental development and in the second trimester will result in reduced growth and carcass muscling in the offspring.

Materials and methods

Project animals management and treatments

All procedures were performed with the approval of the University of Queensland Animal Ethics Committee, approval number SVS/748/08. Genetically similar Polled Hereford heifers (n=80), ~15 months old from the same closed pedigree herd, were selected for inclusion in this trial. Preceding artificial insemination, the heifers were weighed and their reproductive tract palpated for normality. Oestrus was synchronised by insertion of intravaginal progesterone implants (‘EAZI-BREED CIDR-B’; Genetics Australia, Bacchus Marsh, VIC, Australia) for 11 days, with an injection of 12.5 mg of dinoprost tromethamine (Lutalyse; Upjohn Pty Limited, Rydalmere, NSW, Australia) and 500 IU of equine chorionic gonadotrophin (ECG) on the day of CIDR removal. Approximately 48 h after the CIDR implants were removed, the heifers were all artificially inseminated on the same day without detection of oestrus. The sire used was a Polled Hereford bull with an estimated breeding value for birth weight of +2.1 kg at 86% reliability.

The study design was a 2×2 factorial design. The heifers were stratified by body weight and randomly allocated to two equal first trimester (T1) dietary treatment groups, high (15.7% CP) and low (5.9% CP) protein at 14 days post conception (dpc). Pregnancy diagnosis was completed by manual palpation at 35 days following insemination (taken as 35 dpc). As T1 treatment did not start at conception, the periconception period is, therefore, not addressed. After pregnancy diagnosis, all non-pregnant animals were removed from trial (n=21). Following an outbreak of Bovine Ephemeral Fever during trimester 1, 17 heifers were recorded to have aborted and were excluded from the study. The remaining numbers of calves in each treatment period were: T1 high protein, n=10 consisting of six male and four female calves; and T1 Low protein, n=11 consisting of seven male and four female. At 90 dpc half of each nutritional group was changed to a high (15.6% CP) or low (6.1% CP) protein treatment until 180 dpc (T2). Numbers of animals in T2 high protein: n=13 consisting of 10 male and three female; and in T2 low protein: n=8 consisting of three male and five female. This factorial design gave rise to four treatment groups: high/high (HH; four males and two female), high/low (HL; two males and two females), low/high (LH; six males and one female), low/low (LL; one male and three females). After 180 dpc heifers were run together on the same native pasture during the final trimester until term. The diet for this final trimester consisted of native pasture, containing grasses and medicago polymorpha with a CP value ranging between 10% and 13% over the trimester. Both dietary groups of heifers received a grain ration and either ad libitum pasture hay (low) or pasture grazing (high). Details on dry matter intake (DMI) calculations are given in (Table 1).

Table 1 Nutrient content of dietary rations fed to dams during each trimester of gestation (T1=36 to 90 dpc, T2=90 to 180 dpc or T3=181 to term) by treatment (high or low)

Data are presented on an as-fed dry matter (DM) basis per heifer per day.

1 Estimates of DMI from pasture and hay were calculated based upon the National Research Council (NRC) energy requirements for replacement Bos taurus pregnant heifers with a mature weight of 500 kg and a calf birth weight of 32 kg. As the sorghum and copra meal energy content were known (12 and 11.2 MJ/kg DM, respectively) and the heifers on the low-protein diet averaged 340 kg with a rate of gain of 0.8 kg during the first trimester, the DMI of pasture and hay was calculated based upon the energy requirement sufficient to sustain this rate of gain. Similar DMI estimations were completed in the second and third trimesters based on the rate of gain in each treatment group.

2 NRC comparison to ration to NRC (1996) recommended nutrient requirements for pregnant yearling Bos taurus replacement heifers with calf weight of 32 kg.

Before calving, heifers were individually placed in a small yard. Measurements were taken of the newborn calf before suckling (birth weight (BIRW) and biparietal diameter (BPD)), and the foetal portion of the placenta was collected immediately upon expulsion. Placental measures included wet weight, cotyledon number and wet weight of cotyledons (CWW) post separation from adjoining membranes. The dry cotyledon weight (CDW) measure was obtained by drying cotyledons overnight at 100°C and then weighing at 1 h intervals, until the same weight was recorded on three consecutive weightings.

After calving, all the heifers were grazed together with their calves on native pasture. Weights from the heifers and calves were recorded monthly. At 6 months of age, ultrasound (model Aloka-500®; Aloka Inc., Tokyo, Japan with 3 MHz linear probe) was used to assess fat depth at the P8 (rump) and 12th rib (FT12) sites (Hopkins, Reference Hopkins1989). Anal Fat Fold (AFFT), the thickness of skin and subcutaneous fat situated between the point of the ischium and the base of the tail, was assessed using techniques described by Johnson (Reference Johnson1994) by a single experienced technician using calibrated calipers. Heifers were fasted for 6 h and weighed to obtain their empty live weight (ELW). ELW and AFFT were used to calculate the percentage carcass components (muscle, fat and bone) following the published regression equations in Bos taurus Hereford cattle by Johnson (Reference Johnson1994).

Quantitative analysis of placental tissue

The placenta was immediately collected after expulsion (Stage 3 of labour varying between 0.5 and 6 h) at term and weighed whole before excision of all cotyledons from the surrounding membranes (Perry et al., Reference Perry, Norman, Owen, Daniel and Phillips1999). Those not completely expelled by 6 h post calving were considered retained foetal membranes and not used. One small (average 4.4 g), one medium (average 24.2 g) and one large cotyledon (average 55 g) were removed from the gravid horn, fixed in neutral buffered formalin (10%) for 48 h, processed and embedded in paraffin wax. Two-micron sections were cut from each cotyledon and stained with haematoxylin–eosin (H&E) with a further section stained with Masson’s Trichrome.

Quantitative analysis was used to calculate volume densities and relative total component volumes of major cellular components, surface density and barrier thickness of trophectoderm. An L-36 Merz grid was used in conjunction with a video image analysis system as detailed by Perry et al. (Reference Perry, Norman, Owen, Daniel and Phillips1999) for morphometric analysis, at a final magnification of 250× (Nikon 80i microscope with Nikon DS camera system software; Nikon, Tokyo, Japan). The points falling on each structure or component were manually assigned using morphological features appropriate to H&E or Masson’s Trichrome as appropriate, blood vessels were not differentiated between arteries, veins or capillaries. Ten systematic random fields of each cotyledon, of each size, were analysed (three cotyledons per cow), thus 30 fields were analysed per animal to calculate structural quantities (Weibel et al., Reference Wooding and Beckers1966). The cellular components that were measured and counted by point and intersection counting were: trophectoderm, connective tissue matrix, connective tissue fibroblasts and connective tissue blood vessels.

Equations detailed by Weibel et al. (Reference Wooding and Beckers1966), were used to calculate relative volume densities of each component, surface density and mean barrier thickness of the foetal trophectoderm. The relative volume densities (calculated at 1 g of placenta occupying 1 cm3) in conjunction with the CWW (collected as detailed above) of each placenta were used to calculate relative total component volumes of cellular components. The surface area of the foetal trophectoderm was also calculated from the number of times the lines on the Merz grid intersected the surface of the trophectoderm. Volume density=number of points falling on structure/total number of test points (V d =P a /P T ). Relative volume of each component=volume density×placental weight in grams (V c =V d ×weight (g)). Surface density=2×number of intercepts/total length of lines (S v =2×L a /L T ). Barrier thickness=trophoblast volume density/surface density of the trophoblast (B T =D d /S v ) (Weibel et al., Reference Wooding and Beckers1966; Roberts et al., Reference Shimada, Nakano, Takahashi, Imai and Hashizume2001). Every photomicrograph was high quality and could be counted, resulting in 1080 point counts per animal.

Statistical analyses

The study used a 2×2 factorial design, with factors being nutrition in the first trimester (T1) and the second trimester (T2). Statistical analyses were performed using StataCorp. 2015 (Stata Statistical Software: Release 14; StataCorp LP, College Station, TX, USA), and significance was set at P<0.05 for all the results. Normality and equality of variance was checked before any analysis and transformation of the data was applied if it was necessary.

Birth calf weights were analysed using ANOVA with T1×T2, with sex used as covariate. Birth weight and the monthly calf weights were all subjected to ANOVA with repeated measures, and sex and calf age were added as covariates. For each calf the ADG (kg/day) between birth and the final weighing was computed. This calculation involved just the first and last set of weights. The linear growth rate (g/day), which involved fitting a straight line to the weight data and estimating the slope, was also calculated yielding the linear growth rate. Both calculations gave very similar results with live weights and growth rates showing the same response to the treatments.

Muscle, fat and bone in the live animal were considered as three separate dependent variables, against the fixed effects of nutrition in T1×T2 and sex. The effect of group was also analysed. ANOVA was used to examine treatment effects upon placental tissues adding calf sex as covariate. Correlation coefficients between treatment effects and other parameters were also calculated using Pearson’s correlation coefficient and were also considered statistically significant if P<0.05.

Results

Placental gross morphometry

There was a trend for placental weight to be increased in the high-protein second trimester treatment group (P=0.06), but there was no significant effect upon CWW and CDW. In addition, no significant differences were observed between treatments in relation to cotyledon number (Table 2).

Table 2 Placental gross morphometry and calf measurements at birth by treatment group

BPD=biparietal diameter.

a,bDifferent alphabetic superscripts denote mean values which are significantly different from each other (P<0.05).

1 The observed increase in placental weight by second trimester high-protein treatment was below this level at P=0.06.

Placental cellular components

Fibroblast density was increased by the high-protein treatment in the first trimester (P=0.01; Table 3), whereas low protein intake in the first trimester increased trophectoderm volume (P<0.05; Table 3). There were, however, no significant effects of treatment upon other density measures of cellular components, matrix density and relative blood vessel volume density (BVVD). There were no statistically significant interactions between treatments for any of the cellular components measured (Table 3).

Table 3 Cellular composition of bovine placenta by treatment group

Values are unadjusted mean and ±SEM of the cellular composition of bovine placenta by treatment group. Volume densities are a proportion, dimensionless numbers as they are a ratio of two numbers=cm0; Surface density measures surface area per volume or weight of tissue (g of cotyledon) (cm2/cm3)=cm−1; Barrier thickness of trophectoderm – linear measurement=cm; relative volume of each component assumes 1 g of placenta occupies 1 cm3=cm3.

a,bDifferent alphabetic superscripts denote mean values that are significantly different (P<0.05) from each other.

Calf measures at birth

High protein in the second trimester significantly increased BPD (P=0.05; Table 2), with a greater effect in female progeny (P=0.02). There was a similar effect of second trimester high-protein diet increasing birth weight in female progeny (P=0.05), however no effect of treatment on overall birth weight. There was no interaction between treatment and sex. There was increased variability in the birth weight of male calves.

Relationships between birth weight and placental parameters

BIRW was positively correlated with placental weight, CWW, and cotyledon number, with a tendency for a positively correlation with CDW. The strongest correlation being with CWW (r=0.65, P=0.003; Table 4). Relative matrix volume (P=0.008) and relative blood vessel volume (BVV) (P=0.03) were the only cellular parameters correlated with BIRW (Table 4). Cotyledon number was highly positively correlated with BVVD (r=0.569, P=0.014), matrix volume (r=0.497, P=0.036), fibroblast volume (r=0.594, P=0.009), BVV (r=0.575, P=0.012) and CWW (r=0.531, P=0.023); and negatively correlated with surface density (r=−0.605, P=0.008) and trophectoderm volume density (r=−0.493, P=0.037). BPD had strong positive correlations with BVVD (r=0.674, P=0.002), matrix volume (r=0.685, P=0.002), BVV (r=0.769, P=0.0002), BIRW (r=0.678, P=0.001), CWW (r=0.783, P=0.0001), CDW (r=0.511, P=0.03) and placental weight (r=0.679, P=0.001). Placental weight was significantly positively correlated with matrix volume (r=0.653, P=0.003), fibroblast volume (r=0.498, P=0.035), BVV (r=0.522, P=0.03) and BVVD (r=0.478, P=0.04).

Table 4 Correlation coefficients (r) between birth weight and placental parameters

CWW=cotyledon wet weight; CDW=cotyledon dry weight; Ns=not significant.

Preweaning growth of calves

Calf live weights and growth rates showed a similar response to the treatments, whereby there was no effect of nutrition in trimester one on ADG, and there was no sex effect observed on ADG and no interaction between protein levels fed in trimesters one and two (P>0.05). There was a significant effect of nutrition in trimester 2 on ADG (P=0.01) (Figure 1). Calves from heifers fed the high-protein diet in the second trimester weighed significantly more on all occasions (at 1 month (P=0.004), 2 months (P=0.006), 3 months (P=0.002), 4 months (P=0.01), 5 months (P=0.03), 6 months (P=0.01), and grew at a faster rate over the 6-month period (Figure 1). By 6 months of age, the calves from the heifers fed the high-protein diet in the second trimester weighed 33 kg heavier than those fed the low diet in the second trimester (16% heavier).

Figure 1 Mean and ±SEM of calf body weight from birth (0 months) until 6 months of age by treatment during the second trimester. Levels of significance indicated by *P<0.05, **P<0.01 and ***P<0.001, respectively.

In the live carcass measures, there was a sex effect on the amount of muscle (P=0.0001) and fat (P=0.0007), but not bone (P=0.91); males had increased muscle (59.67±0.26) and less fat (23.15±0.38) compared with females (muscle: 57.04±0.51, and fat: 26.71±0.76). For all three variables, there was a significant effect of nutrition in trimester 1 and a significant interaction between nutrition fed in the two trimesters. Decreased protein during trimester 1 led to increased muscle (P=0.002) and decreased fat (P=0.002). Animals in the HL group had significantly lower muscle and bone percentages and significantly higher fat percentages than animals in the LL group. No other group was different from another in either muscle bone or fat (Table 5).

Table 5 Anal fat fold (AFFT) measurement and body composition of calves at 6 months of age according to treatment groupEquations used to calculate the body composition were taken from Johnson (Reference Johnson1994). Different alphabetic superscripts denote group mean values that are statistically significantly different from each other, a, b and c for P<0.05

Equations used to calculate the body composition were taken from Johnson (Reference Johnson1994).

(1)=72.92 (if males)/69.97(if females)−0.090×AFFT−0.027×ELW; (2)=4.37(if male)/8.32 (if female)+0.132×AFFT+0.038×ELW; (3)=18.81−0.029×AFFT−0.010×ELW.

a,b,cDifferent alphabetic superscripts denote mean values that are statistically significantly different from each other for P<0.05.

Discussion

This study provides clear evidence that nutrition during the first two trimesters of pregnancy alters the growth and body phenotype of the calf. Importantly, decreasing genetic variability in the heifer dams enabled this clear effect of gestational protein manipulation upon progeny growth to be revealed. The analysis of weight gain of progeny supports the hypothesis that providing heifers with a high-protein diet in the second trimester resulted in a faster growth rate and a significant increase in body weight (~33 kg) in their calves at 6 months of age when compared with calves born to heifers fed low protein in the second trimester. Further, this study also shows early gestational dietary protein affects the developing placenta and supports the hypothesis that reduced protein in the first trimester increases physiologically important components of placental development. These findings are of significant interest to the cattle industry in Australia as protein is the most deficient nutrient in the Australian rangelands (Norman, Reference Oksbjerg, Gondret and Vestergaard1963; Sullivan et al., Reference Sullivan, Micke, Magalhaes, Phillips and Perry2009a).

This downside to utilising these high-value pedigree animals and the farm site of this study was a reduction in the level of intervention permitted. This included prevention of dietary intervention before 35 dpc, which is known to affect foetal development (Copping et al., Reference Copping, Hoare, Callaghan, McMillen, Rodgers and Perry2014; Hernandez-Medrano et al., Reference Hernandez-Medrano, Copping, Hoare, Wapanaar, Grivell, Kuchel, Miguel-Pacheco, McMillen, Rodgers and Perry2015).

Poor maternal dietary protein in early gestation has been shown to impair bovine foetal growth (Long et al., Reference Long, Vonnahme, Hess, Nathanielsz and Ford2009; Micke et al., Reference Micke, Sullivan, Soares Magalhaes, Rolls, Norman and Perry2010b; Copping et al., Reference Copping, Hoare, Callaghan, McMillen, Rodgers and Perry2014), which was confirmed in this experiment. Low dietary protein intake in the second trimester decreased BPD similar to previous experiments although birth weight was not affected as comprehensively as previously reported (Cafe et al., Reference Cafe, Hennessy, Hearnshaw, Morris and Greenwood2006; Micke et al., Reference Norman2010c), being only significant in the female. The relatively small numbers in this experiment compared with the Micke paper (Micke et al., Reference Norman2010c) may have influenced this result as variability was greater in the male calves. Furthermore, birth weight at term may not be indicative of intrauterine growth restriction (IUGR) in earlier gestation (Long et al., Reference Long, Vonnahme, Hess, Nathanielsz and Ford2009; Hernandez-Medrano et al., Reference Hernandez-Medrano, Copping, Hoare, Wapanaar, Grivell, Kuchel, Miguel-Pacheco, McMillen, Rodgers and Perry2015) in the bovine. BPD and BIRW had a strong positive relationship with placental weight and the placental parameters of BVV, CWW and CDW, concomitant with previous studies (Perry et al., Reference Perry, Norman, Owen, Daniel and Phillips1999; Sullivan et al., Reference Sullivan, Micke, Magalhaes, Martin, Wallace, Green and Perry2009b). There was a trend (P=0.06) for placental weight to be increased by increased dietary protein in the second trimester, whereas trophectoderm volume was increased by high-protein first trimester as previously described (Perry et al., Reference Perry, Norman, Owen, Daniel and Phillips1999). The initial rapid growth of the placenta has been linked to the rapid and vigorous development of the foetal trophoblast through proliferation and branching of the foetal villi into the maternal stromal tissue (Bell et al., Reference Bell, Hay and Ehrhardt1999). Interdigitation between the foetal trophectoderm and maternal microvilli is complete by 28 dpc in the bovine (Wooding and Beckers, Reference Zhu, Du, Hess, Means, Nathanielsz and Ford1987), which is before the initiation of our dietary treatments. Placentome weight and surface area in the bovine however, continually increase until term unlike the ovine in which placentome weight is constant or decreasing from 65 dpc (Baur, Reference Baur1977; Reynolds and Redmer, Reference Robelin, Picard, Listrat, Jurie, Barboiron, Pons and Geay1995). The observed increase in trophectoderm volume in the low-protein heifers during the first trimester may enhance the functional potential of the placenta during this period of maximal villi development and thereby enable an increased nutrient supply to the foetus during later gestation if protein availability increases. Supporting evidence suggesting that the protein restricted bovine foetus signals to the placenta an increased requirement for nutrients is found in its ability to increase blood supply via the uterine artery (Hernandez-Medrano et al., Reference Hernandez-Medrano, Copping, Hoare, Wapanaar, Grivell, Kuchel, Miguel-Pacheco, McMillen, Rodgers and Perry2015) and increased cotyledonary vasculature (Zhu et al., Reference Zhu, Du, Hess, Means, Nathanielsz and Ford2007) at 125 dpc.

The relative vasculature proportions in the foetal cotyledons were not altered in this study, although there was a positive correlation between calf birth weight and vasculature. The literature shows that vascular components of the placenta vary greatly depending upon environmental perturbations, dam age, the timing of perturbation and timing of cotyledon excision. Gestational undernutrition (Vonnahme et al., Reference Weibel, Kistler and Scherle2007) found decreased bovine cotyledonary vasculature in the later, but not early stages of placental development, whereas Zhu et al. (Reference Zhu, Du, Hess, Means, Nathanielsz and Ford2007) showed nutrient restriction increased cotyledonary vascularity at day 125 with no affect at day 250. Furthermore, cows in their third or greater pregnancy did not show effects upon placental composition observed in younger heifers (Long et al., Reference Long, Vonnahme, Hess, Nathanielsz and Ford2009). This may illustrate a window and age-specific effect of nutrition upon placental vascularisation.

Connective tissue fibroblast density was increased (P<0.05) in the placenta of heifers receiving the high-protein dietary treatment in the first trimester (HH, HL) a similar finding to that of a previous study by Roberts et al. (Reference Shimada, Nakano, Takahashi, Imai and Hashizume2001) in sheep, where maternal dietary restriction (70% of recommended intake) reduced the total placental surface area for exchange, and the surface density of trophoblast. However, the arithmetic mean barrier thickness for diffusion in this study was increased by this maternal food restriction (Roberts et al., Reference Shimada, Nakano, Takahashi, Imai and Hashizume2001). Similarly, in the current study barrier thickness of the trophectoderm was increased by protein restriction. It has been suggested by Perry et al. (Reference Perry, Norman, Owen, Daniel and Phillips1999) that a restriction in protein in the first trimester in heifers may lead to a larger placenta at term due to the greater development of the microvilli, particularly if this early period of restriction is followed up by a phase of improved nutrition. Indeed the LH group did have the largest CWW (Table 2), but this was only significantly greater than CWW in the HH group (P=0.03). It has been suggested (Talbot et al., Reference Tong, Yan, Zhu, Ford, Nathanielsz and Du2000; Shimada et al., Reference Sullivan, Micke, Perkins, Martin, Wallace, Gatford, Owens and Perry2001; Dunlap et al., Reference Dunlap, Palmarini, Varela, Burghardt, Hayashi, Farmer and Spencer2006) that trophoblasts from ungulates (including cattle), proliferate in the absence of fibroblast growth factors (FGFs), suggesting that the role of FGFs is more limited in maintaining the trophoblast lineage in cattle in comparison with rodents. It has also been shown that fibroblasts and FGFs play a role in angiogenesis, including within the placenta (Klagsbrun and D’Amore, Reference Klagsbrun and D’Amore1991), therefore a concomitant increase in vasculature within these placentae may be expected.

These results suggest that maternal diet restriction affects the structure and function of the placenta as previously reported (Perry et al., Reference Perry, Norman, Owen, Daniel and Phillips1999; Long et al., Reference Long, Vonnahme, Hess, Nathanielsz and Ford2009; Sullivan et al., Reference Sullivan, Micke, Magalhaes, Martin, Wallace, Green and Perry2009b; Sullivan et al., Reference Summers, Blair and Funston2009c). Such perturbations to placental development may reduce foetal growth due to decreased nutrient transport via the placenta (Sullivan et al., Reference Summers, Blair and Funston2009c) generating a decrease in birth weight (Perry et al., Reference Perry, Norman, Owen, Daniel and Phillips1999; Micke et al., Reference Norman2010c), or alternatively dichotomous placental development (as in the LH group) may be attendant to increased birth weight and associated dystocia.

Interpretation of the carcass composition results requires consideration of the stages of foetal bovine muscle development, which are predominantly controlled by IGF-2 expression that peaks between 150 and 160 dpc (Gerrard and Grant, Reference Gerrard and Grant1994; Florini et al., Reference Florini, Ewton and Coolican1996). The first wave of differentiation however occurs much earlier when primary skeletal muscle fibres (type I) differentiate from primary myotubes at 39 dpc (Robelin et al., Reference Roberts, Sohlstrom, Kind, Earl, Khong, Robinson, Owens and Owens1993), the second at 90 dpc results in secondary fibres; and a third at 110 dpc gives rise to tertiary fibres (Gagniere et al., Reference Gagniere, Picard and Geay1999). These critical events occur during the dietary treatments imposed in this study.

As myocytes are formed from a pool of pluripotent stem cells (Oksbjerg et al., Reference Oliver, Harding, Breier and Gluckman2004) extrauterine signals such as those regulated by maternal nutrient intake, may affect the number of cells committed to myoblast formation whilst also affecting the rate of myoblast proliferation and thus final myofibre number. It has previously been reported that gestational dietary regimens effectively alter placental signalling hormones (Sullivan et al., Reference Summers, Blair and Funston2009c; Summers et al., Reference Symonds, Pope, Sharkey and Budge2015). These may act to signal foetal skeletal muscle IGF messenger RNA (mRNA) expression and fibre development during the first two trimesters of gestation as previously shown in foetal skeletal sheep muscle where nutritional restriction increased IGF-2 mRNA expression (Brameld et al., Reference Brameld, Mostyn, Dandrea, Stephenson, Dawson, Buttery and Symonds2000) and increased IGF receptor activity (Symonds et al., Reference Symonds, Pearce, Bispham, Gardner and Stephenson2012). Myofibre density is also reduced by maternal nutrient restriction (Costello et al., Reference Costello, Rowelerson, Astaman, Anthony, Sayer, Cooper, Hanson and Green2008). As primary fibres provide the scaffolding for secondary fibre formation, a reduction of primary fibre density resulting from decreased maternal nutrient intake during the first trimester may not be fully compensated for by the provision of increased maternal nutrient intake during the latter stages of gestation. In support of this (Micke et al., Reference Micke, Sullivan, McMillen, Gentili and Perry2011b), found that the majority of effects of maternal protein intake upon IGF mRNA expression in adult progeny skeletal muscle occurred during the first trimester of gestation suggesting these early stages of foetal development to be the most sensitive to altered nutritional environment. This is attributed to the high rate of cellular differentiation and proliferation during the early stages of gestation compared with the high rate of cellular hypertrophy during the latter stages (Brameld et al., Reference Brameld, Mostyn, Dandrea, Stephenson, Dawson, Buttery and Symonds2000; Tong et al., Reference Vonnahme, Zhu, Borowicz, Geary, Hess, Reynolds, Caton, Means and Ford2009). This study is a corollary of previous findings (Micke et al., Reference Micke, Sullivan, McMillen, Gentili and Perry2011b) as decreased protein during trimester 1 (LL and LH combined) increased muscle (P=0.002) and decreased fat (P=0.002) in progeny compared with those animals whose dams received high protein during this period. Though, the predicted values for carcass components presented in this paper are representative of the data presented in Johnson (Reference Johnson1994), it is necessary to acknowledge that these predicted measurements may be limited in their inference and accuracy when compared with ‘real’ carcass measures taken at slaughter.

The treatment effects upon carcass muscle and fat in this study reflect the reciprocal relationship between the development of muscle and adipose tissue, previously reported (Micke et al., Reference Micke, Sullivan, Kennaway, Hernandez-Medrano and Perry2010a) whereby the in utero diet alters differentiation of the mutual precursor cells of adipocytes and myocytes (Symonds et al., Reference Symonds, Pearce, Bispham, Gardner and Stephenson2012). Furthermore, Micke et al. (Reference Micke, Sullivan, McMillen, Gentili and Perry2011a) also indicated a possible causal mechanism via the effect of maternal diet upon adipogenic gene expression. The exposure of the developing calf foetus to a high maternal protein intake during the first trimester may result in a relative increase in myostatin gene expression in skeletal muscle as in other species (Liu et al., Reference Liu, Wang, Li, Yang, Sun, Albrecht and Zhao2011) and this may result in a decrease in muscle fibre number and an increase in the commitment of stem cells within the muscle to form preadipocytes. This effect may, however, be offset in part by an upregulation of the expression of IGF-1 receptor (IGF-1R) as discussed above which occurs in the progeny of such heifers (Micke et al., Reference Micke, Sullivan, McMillen, Gentili and Perry2011b).

In this study the lowest muscling occurred in the HL group (P=0.05). As the secondary muscle fibres are the largest contributor to postnatal muscle mass of cattle and begin to form at 90 dpc (Robelin et al., Reference Roberts, Sohlstrom, Kind, Earl, Khong, Robinson, Owens and Owens1993) nutrient restriction during the second trimester may have decreased formation of secondary muscle fibres during myoblast proliferation as reported in sheep (Quigley et al., Reference Reynolds and Redmer2005). Importantly, however, both circulating maternal and progeny IGF-1 has been shown to increase following gestational high dietary protein (Perry et al., Reference Quigley, Kleemann, Kakar, Owens, Nattrass, Maddocks and Walker2002; Sullivan et al., Reference Sullivan, Micke, Magalhaes, Phillips and Perry2009a; Micke et al., Reference Micke, Sullivan, Kennaway, Hernandez-Medrano and Perry2010a). This combined effect in the progeny that experienced increased protein in utero during the second trimester may have produced the increased growth rates observed.

Acknowledgements

The authors are indebted to the Doyle Family for the use of stud animals and feedstuffs in this experiment to Professor Ray Johnson (Deceased) for the completion of the work on live carcass analysis. G.G.M.-P. was funded by an AHDB grant.

References

Baur, R 1977. Morphometry of the placental exchange areas. Advances in Anatomy Embryology and Cell Biology 53, 120.Google Scholar
Bell, AW, Hay, W and Ehrhardt, RA 1999. Placental transport of nutrients and its implications for fetal growth. Journal of Reproduction and Fertility 54, 401410.Google Scholar
Brameld, JM, Mostyn, A, Dandrea, J, Stephenson, TJ, Dawson, JM, Buttery, PJ and Symonds, ME 2000. Maternal nutrition alters the expression of insulin-like growth factors in fetal sheep liver and skeletal muscle. Journal of Endocrinology 167, 429437.CrossRefGoogle ScholarPubMed
Breier, BH, Gluckman, PD and Bass, JJ 1988. Plasma concentrations of insulin-like growth factor-I and insulin in the infant calf: ontogeny and influence of altered nutrition. Journal of Endocrinology 119, 4350.CrossRefGoogle ScholarPubMed
Cafe, LM, Hennessy, DW, Hearnshaw, H, Morris, ST and Greenwood, PL 2006. Influences of nutrition during pregnancy and lactation on birthweights and growth to weaning of calves sired by Piedmontese and Wagyu bulls. Australian Journal of Experimental Agriculture 46, 245255.Google Scholar
Copping, KJ, Hoare, A, Callaghan, M, McMillen, IC, Rodgers, RJ and Perry, VEA 2014. Fetal programming in 2-year-old calving heifers: peri-conception and first trimester protein restriction alters fetal growth in a gender-specific manner. Animal Production Science 54, 13331337.Google Scholar
Costello, PM, Rowelerson, A, Astaman, NA, Anthony, FEW, Sayer, AA, Cooper, C, Hanson, MA and Green, LR 2008. Peri-implantation and late gestation maternal undernutrition differentially affect fetal sheep skeletal muscle development. Journal of Physiology 586, 23712379.CrossRefGoogle ScholarPubMed
Dunlap, KA, Palmarini, M, Varela, M, Burghardt, RC, Hayashi, K, Farmer, JL and Spencer, TE 2006. Endogenous retroviruses regulate periimplantation placental growth and differentiation. Proc Natl Acad Sci USA 103, 1439014395.Google Scholar
Florini, JR, Ewton, DZ and Coolican, SA 1996. Growth hormone and the insulin-like growth factor system in myogenesis. Endocrine Reviews 17, 481517.Google Scholar
Gagniere, H, Picard, B and Geay, Y 1999. Contractile differentiation of foetal cattle muscles: intermuscular variability. Reproduction, Nutrition and Development 39, 637655.CrossRefGoogle ScholarPubMed
Gerrard, DE and Grant, AL 1994. Insulin-like growth factor-II expression in developing skeletal muscle of double muscled and normal cattle. Domestic Animal Endocrinology 11, 339347.CrossRefGoogle ScholarPubMed
Greenwood, PL, Cafe, LM, Hearnshaw, H and Hennessy, DW 2005. Consequences of nutrition and growth retardation early in life for growth and composition of cattle and eating quality of beef. Recent Advances in Animal Nutrition in Australia 15, 183195.Google Scholar
Greenwood, PL, Cafe, LM, Hearnshaw, H, Hennessy, DW and Morris, ST 2006. Long-term consequences of birth weight and growth to weaning on carcass, yield and beef quality characteristics of Peidmontese- and Wagyu-sired cattle. Australian Journal of Experimental Agriculture 46, 257269.CrossRefGoogle Scholar
Hernandez-Medrano, JH, Copping, KJ, Hoare, A, Wapanaar, W, Grivell, R, Kuchel, T, Miguel-Pacheco, G, McMillen, IC, Rodgers, RJ and Perry, VEA 2015. Gestational dietary protein is associated with sex specific decrease in blood flow, fetal heart growth and post-natal blood pressure of progeny. PLoS One 10, e0125694.CrossRefGoogle ScholarPubMed
Hopkins, D 1989. Reliability of three sites for measuring fat depth on the beef carcass. Australian Journal of Experimental Agriculture 29, 165168.CrossRefGoogle Scholar
Johnson, E 1994. Comparison of the prediction of carcass components using fat thickness measurements in heifers and steers. Australian Journal of Experimental Agriculture 34, 435438.Google Scholar
Klagsbrun, M and D’Amore, PA 1991. Regulators of angiogenesis. Annual Review of Physiology 53, 217239.Google Scholar
Liu, X, Wang, J, Li, R, Yang, X, Sun, Q, Albrecht, E and Zhao, R 2011. Maternal dietary protein affects transcriptional regulation of myostatin gene distinctively at weaning and finishing stages in skeletal muscle of Meishan pigs. Epigenetics 6, 899907.CrossRefGoogle ScholarPubMed
Long, NM, Vonnahme, KA, Hess, BW, Nathanielsz, PW and Ford, SP 2009. Effects of early gestational undernutrition on fetal growth, organ development, and placentomal composition in the bovine. Journal of Animal Science 87, 19501959.CrossRefGoogle ScholarPubMed
Lund-Larsen, TR, Sundby, A, Kruse, V and Velle, W 1977. Relation between growth rate, serum somatomedin and plasma testosterone in young bulls. Journal of Animal Science 44, 189194.Google Scholar
Martin, JL, Vonnahme, KA, Adams, DC, Lardy, GP and Funston, RN 2007. Effects of dam nutrition on growth and reproductive performance of heifer calves. Journal of Animal Science 85, 841847.CrossRefGoogle ScholarPubMed
Micke, GC, Sullivan, TM, Gatford, KL, Owens, JA and Perry, VE 2010a. Nutrient intake in the bovine during early and mid-gestation causes sex-specific changes in progeny plasma IGF-I, liveweight, height and carcass traits. Animal Reproduction Science 121, 208217.CrossRefGoogle ScholarPubMed
Micke, GC, Sullivan, TM, Kennaway, DJ, Hernandez-Medrano, J and Perry, VEA 2015. Maternal endocrine adaptation throughout pregnancy to nutrient manipulation: consequences for sexually dimorphic programming of thyroid hormones and development of their progeny. Theriogenology 83, 604615.Google Scholar
Micke, GC, Sullivan, TM, McMillen, IC, Gentili, S and Perry, VEA 2011a. Heifer nutrient intake during early- and mid-gestation programs adult offspring adiposity and mRNA expression of growth-related genes in adipose depots. Reproduction 141, 697706.Google Scholar
Micke, GC, Sullivan, TM, McMillen, IC, Gentili, S and Perry, VEA 2011b. Protein intake during gestation affects postnatal bovine skeletal muscle growth and relative expression of IGF1, IGF1R, IGF2 and IGF2R. Molecular and Cellular Endocrinology 332, 234241.Google Scholar
Micke, GC, Sullivan, TM, Rolls, PJ, Hasell, B, Greer, RM, Norman, ST and Perry, VEA 2010c. Dystocia in 3-year-old beef heifers; relationship to maternal nutrient intake during early- and mid-gestation, pelvic area and hormonal indicators of placental function. Animal Reproduction Science 118, 163170.Google Scholar
Micke, GC, Sullivan, TM, Soares Magalhaes, RJ, Rolls, PJ, Norman, ST and Perry, VEA 2010b. Heifer nutrition during early- and mid-pregnancy alters fetal growth trajectory and birth weight. Animal Reproduction Science 117, 110.CrossRefGoogle ScholarPubMed
Norman, MJT 1963. The pattern of dry matter and nutrient content changes in native pastures at Katherine, N.T. Australian Journal of Experimental Agriculture 3, 119124.Google Scholar
Oksbjerg, N, Gondret, F and Vestergaard, M 2004. Basic principles of muscle development and growth in meat-producing mammals as affected by the insulin-like growth factor (IGF) system. Domestic Animal Endocrinology 27, 219240.Google Scholar
Oliver, MH, Harding, JE, Breier, BH and Gluckman, PD 1996. Fetal insulin-like growth factor (IGF)-I and IGF-II are regulated differently by glucose or insulin in the sheep fetus. Reproduction, Fertility and Development 8, 167172.Google Scholar
Perry, VEA, Norman, ST, Daniel, RCW, Owens, PC, Grant, P and Doogan, VJ 2002. Insulin-like growth factor levels during pregnancy in the cow are affected by protein supplementation in the maternal diet. Animal Reproduction Science 72, 110.Google Scholar
Perry, VEA, Norman, ST, Owen, JA, Daniel, RCW and Phillips, N 1999. Low dietary protein during early pregnancy alters bovine placental development. Animal Reproduction Science 55, 1321.CrossRefGoogle ScholarPubMed
Quigley, SP, Kleemann, DO, Kakar, MA, Owens, JA, Nattrass, GS, Maddocks, S and Walker, SK 2005. Myogenesis in sheep is altered by maternal feed intake during the peri-conceptal period. Animal Reproduction Science 87, 241251.Google Scholar
Reynolds, LP and Redmer, DA 1995. Utero-placental vascular development and placental function. Journal of Animal Science 73, 18391851.Google Scholar
Robelin, J, Picard, B, Listrat, A, Jurie, C, Barboiron, C, Pons, F and Geay, Y 1993. Myosin expression in semitendinosus muscle during fetal development of cattle: immunocytochemical and electrophoretic analyses. Reproduction, Nutrition, Development 33, 2541.Google Scholar
Roberts, CT, Sohlstrom, A, Kind, KL, Earl, RA, Khong, TY, Robinson, JS, Owens, PC and Owens, JA 2001. Maternal food restriction reduces the exchange surface area and increases the barrier thickness of the placenta in the guinea-pig. Placenta 22, 177185.Google Scholar
Shimada, A, Nakano, H, Takahashi, T, Imai, K and Hashizume, K 2001. Isolation and characterization of a bovine blastocyst-derived trophoblastic cell line, BT-1: development of a culture system in the absence of feeder cell. Placenta 22, 652662.Google Scholar
Sullivan, T, Micke, G, Perkins, N, Martin, G, Wallace, C, Gatford, K, Owens, J and Perry, V 2009a. Dietary protein during gestation affects maternal IGF, IGFBP, leptin concentrations, and fetal growth in heifers. Journal of Animal Science 87, 33043316.Google Scholar
Sullivan, TM, Micke, GC, Magalhaes, RS, Phillips, NJ and Perry, VEA 2009b. Dietary protein during gestation affects placental development in heifers. Theriogenology 72, 427438.Google Scholar
Sullivan, TM, Micke, GC, Magalhaes, RS, Martin, GB, Wallace, CR, Green, JA and Perry, VEA 2009c. Dietary protein during gestation affects circulating indicators of placental function and fetal development in heifers. Placenta 30, 348354.CrossRefGoogle ScholarPubMed
Summers, AF, Blair, AD and Funston, RN 2015. Impact of supplemental protein source offered to primiparous heifers during gestation on II. Progeny performance and carcass characteristics. Journal of Animal Science 93, 18711880.Google Scholar
Symonds, ME, Pope, M, Sharkey, D and Budge, H 2012. Adipose tissue and fetal programming. Diabetologia 55, 15971606.CrossRefGoogle ScholarPubMed
Symonds, ME, Pearce, S, Bispham, J, Gardner, D and Stephenson, T 2004. Timing of nutrient restriction and programming of fetal adipose tissue development. Proceedings of the Nutrition Society 63, 397403.Google Scholar
Talbot, NC, Caperna, TJ, Edwards, JL, Garrett, W, Wells, KD and Ealy, AD 2000. Bovine blastocyst-derived trophectoderm and endoderm cell cultures: interferon tau and transferrin expression as respective in vitro markers. Biology of Reproduction 62, 235247.Google Scholar
Tong, JF, Yan, X, Zhu, MJ, Ford, SP, Nathanielsz, PW and Du, M 2009. Maternal obesity downregulates myogenesis and {beta}-catenin signaling in fetal skeletal muscle. American Journal of Physiology 296, E917E924.Google ScholarPubMed
Vonnahme, KA, Zhu, MJ, Borowicz, PP, Geary, TW, Hess, BW, Reynolds, LP, Caton, JS, Means, WJ and Ford, SP 2007. Effect of early gestational undernutrition on angiogenic factor expression and vascularity in the bovine placentome. Journal of Animal Science 85, 24642472.Google Scholar
Weibel, ER, Kistler, GS and Scherle, WF 1966. Practical stereological methods for morphometric cytology. The Journal of Cell Biology 30, 2338.CrossRefGoogle ScholarPubMed
Wooding, FBP and Beckers, JF 1987. Trinucleate cells and the ultrastructural localisation of bovine placental lactogen. Cell and Tissue Research 247, 667673.Google Scholar
Zhu, MJ, Du, M, Hess, BW, Means, WJ, Nathanielsz, PW and Ford, SP 2007. Maternal nutrient restriction upregulates growth signalling pathways in the cotyledonary artery of cow placentomes. Placenta 28, 361368.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Nutrient content of dietary rations fed to dams during each trimester of gestation (T1=36 to 90 dpc, T2=90 to 180 dpc or T3=181 to term) by treatment (high or low)

Figure 1

Table 2 Placental gross morphometry and calf measurements at birth by treatment group

Figure 2

Table 3 Cellular composition of bovine placenta by treatment group

Figure 3

Table 4 Correlation coefficients (r) between birth weight and placental parameters

Figure 4

Figure 1 Mean and ±SEM of calf body weight from birth (0 months) until 6 months of age by treatment during the second trimester. Levels of significance indicated by *P<0.05, **P<0.01 and ***P<0.001, respectively.

Figure 5

Table 5 Anal fat fold (AFFT) measurement and body composition of calves at 6 months of age according to treatment groupEquations used to calculate the body composition were taken from Johnson (1994). Different alphabetic superscripts denote group mean values that are statistically significantly different from each other, a, b and c for P<0.05