Effect of weight and body condition score from pregnant cows on the carcass characteristics of their progeny: Meta-analysis

Adams, Sander Martinho; Lenon Klein, John; Soares Machado, Diego; Alves Filho, Dari Celestino; Brondani, Ivan Luiz; Pizzuti, Luiz Angelo Damian; Adams, Sander Martinho; Lenon Klein, John; Soares Machado, Diego; Alves Filho, Dari Celestino; Brondani, Ivan Luiz; Pizzuti, Luiz Angelo Damian

doi:10.22319/rmcp.v13i4.6065

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Revista mexicana de ciencias pecuarias

versão On-line ISSN 2448-6698versão impressa ISSN 2007-1124

Rev. mex. de cienc. pecuarias vol.13 no.4 Mérida Out./Dez. 2022 Epub 11-Nov-2022

https://doi.org/10.22319/rmcp.v13i4.6065

Articles

Effect of weight and body condition score from pregnant cows on the carcass characteristics of their progeny: Meta-analysis

Sander Martinho Adams^a

John Lenon Klein^a

Diego Soares Machado^b

Dari Celestino Alves Filho^a

Ivan Luiz Brondani^a

Luiz Angelo Damian Pizzuti^a

^{^a} Universidade Federal de Santa Maria. Laboratório de Bovinocultura de Corte. Av. Roraima nº 1000 Cidade Universitária, Camobi, Santa Maria - RS, Brazil.

^{^b} Instituto Federal de Educação Ciência e Tecnologia Farroupilha - Alegrete. Brazil.

Abstract

The objective of the meta-analysis was to evaluate the effects of beef cows weight variation during the 2nd and / or 3rd trimester pregnancy on some parameters of the progeny carcass. The cow weight gain during this gestational period was calculated to standardize the treatments: moderate loss (ML= cows that lost 0 to 5 % of weight) and moderate gain (MG= cows that gained 0 to 5 % of weight). The effect size for all parameters was calculated as medium difference (MD) with a 95% confidence interval and heterogeneity determined using the Q test and the I² statistic. A random effects meta-analysis was performed for each indicator separately as the medium control and experimental groups. The cow’s weight variation during the studied time variation did not influence the progeny carcass characteristics (P>0.05). Although, a trend towards greater hot carcass weight (P=0.15) and thickness of subcutaneous fat (P=0.10) was observed in calves from MG cows in relation to calves from ML cows. However, the meta-analysis demonstrated that small variations in cow weight during the final half of pregnancy do not affect progeny carcass characteristics.

Key words Beef cows; Marbling. Steers. Subcutaneous fat

Resumen

El objetivo del meta análisis fue evaluar los efectos de la variación del peso de vacas de carne durante el 2º y/o 3º trimestre de gestación en algunos parámetros de la canal de la progenie. La ganancia de peso de la vaca durante este período gestacional se calculó para estandarizar los tratamientos: pérdida moderada (PM= vacas que perdieron de 0 a 5 % de peso) y ganancia moderada (GM= vacas que ganaron de 0 a 5 % de peso). El tamaño del efecto para todos los parámetros se calculó como la diferencia de medias (DM) con un intervalo de confianza del 95 % y la heterogeneidad se determinó utilizando la prueba Q y el estadístico I². Se realizó un meta análisis de efectos aleatorios para cada indicador por separado como grupo de control medio y experimental. La variación del peso de la vaca durante la variación de tiempo estudiada no influyó en las características de la canal de la progenie (P>0.05). Aunque se observó una tendencia hacia un mayor peso de la canal caliente (P=0.15) y del grosor de la grasa subcutánea (P=0.10) en terneros de vacas GM en relación con terneros de vacas PM. Sin embargo, el meta análisis demostró que las pequeñas variaciones en el peso de la vaca durante la mitad final de la gestación no afectan las características de la canal de la progenie.

Palabras clave Vacas de carne; Marmoleado; Novillos; Grasa subcutánea

Introduction

Among factors that can influence the postnatal performance of beef cattle, it can be highlight the cow nutritional insults during pregnancy, uterine changes, also known as fetal programming. The prenatal development of cattle influences productive performance throughout the postnatal period¹. The authors add that the number of muscle and fat cells an animal will have throughout its life is determined in the fetal phase and is influenced by pregnant cow nutrition, because the myogenesis and adipogenesis processes are exclusive from the fetal period². Thus, Du et al³, conclude that calves of cows kept under restricted supply of nutrients during pregnancy have a compromised meat production potential.

According to Reynolds et al⁴, the structural and functional changes in organs and tissues caused by the supply of nutrients during pregnancy serve to allow a rapid adaptation of the developing fetus to the pressure of uterine environmental selection. These changes can be related to the health and productive potential of the progeny in adulthood. However, the nutritional challenge during fetal formation can form a phenotype with greater adaptability when nutritional conditions were more challenging in the postnatal period⁵.

Thus, the effects of fetal programming are more noticeable in the first months from progeny's life⁶. The authors state that the real effects of fetal programming in beef cattle are still contradictory and need further clarification, since there are many divergences between researches, such variability of the studied nutrients, gestational period and intensity of nutritional restriction, as well the progeny characteristics evaluated. Therefore, the objective of this meta-analysis was to evaluate the effects of cow weight variation during pregnancy at progeny carcass characteristics.

Material and methods

Literature search

Literature searches were performed using specific search databases on the platforms: Scientific Electronic Library Online (https://scielo.org), Portal de Periódicos Capes (https://www.periodicos.capes.gov.br), ScienceDirect (https://www.sciencedirect.com) and Google Scholar (http://scholar.google.com). The searches were based on the keywords: “fetal programming in beef cows and the performance of steers progeny” or “fetal programming in beef cattle and progeny performance.” The literature searches included publications from the last ten years (2009 - 2019).”

This meta-analysis was performed using combined data from 10 studies (9 peer-reviewed articles, 1 doctoral thesis), with a total record of 1053 calves during termination and after slaughter phases. When possible, the same study was inserted two or more times in the meta-analysis database. The reviewed studies evaluated the effects of maternal nutrition during gestation on the postnatal performance of progeny, as described in Table 1.

Table 1 Description of the studies included in the database for conducting the meta-analysis

Study	Year	Local	Cow Breed	Sex	Initial BW¹	Comparations	Number of observations
Study	Year	Local	Cow Breed	Sex	Initial BW¹	Comparations	HCW	SFT	M	LDA
⁷	2013	USA	AxC	All	534 ± 14	Supl. x No Supl.	228	228	228	228
⁷	2013	USA	AxC	All	534 ± 14	High ECC x Low ECC	228	228	228	228
⁸	2009	USA	AxS	Male	498 ± 15	Supl. x No Supl.	24	24	24	24
⁹	2019	ARG	A	Male	408 ± 54	High CP x Low CP	24	24	24	24
¹⁰	2015^a	USA	AxS	Male	440 ± 28	Positive energy status x Negative	11	11	11	11
¹¹	2015^b	USA	AxS	All	463 ± 3	Positive energy status x Negative	101	101	101	101
¹²	2013	USA	A	Male	575 ± 9	Supl. x No Supl.	40	40	40	40
¹³	2015	USA	AxS	Male	600 ± 7	Supl. x No Supl.	71	71	71	71
¹⁴	2016	USA	AxS	Male	684 ± 7	100% TDN x 125% TDN	86	86	86	86
¹⁵	2019	BRA	CxN	Male	413 ± 8	Weight Gain x Moderate Loss	240	240	-	240
Total	-	-		-		-	1053	1053	813	1053

Cow breed, A= Aberdeen Angus; S= Simental; C= Charolês; N= Nelore.

¹Initial body weight (kg) of cows and ± SEM.

Variables, HCW= Hot carcass weight; SFT= Subcutaneous fat thickness; M= Marbling; LDA= Longissimus dorsi area.

CP= crude protein; TDN= total digestible nutrients.

Inclusion and exclusion criteria

In total, 21 studies published between 2009 and 2020 were identified from the pre-established search. The criteria established for inclusion of studies in database were: 1) possibility of calculating cow average daily weight gain during gestation and adequacy to treatments; 2) provide carcass progeny variables; 3) the period of nutritional insult occurs in second or third pregnancy trimester (cow greatest demand); and 4) report information on sample size and variability measurements of interest (i.e. deviation or standard error). In case of studies that reported the standard error of mean (S.E.M.), the standard deviation (σ) was it obtained through the equation:

σ=S.E.M* n

A total of 11 studies obtained by the search terms were excluded from this meta-analysis because they did not answer the criteria mentioned above: criterion 1) 6 studies excluded; criterion 2) 2 studies excluded; criterion 3) 3 studies excluded. A large number of studies were excluded from this research for not meeting the inclusion criteria. In addition, this is justified by the wide variation between studies, especially concerning the intensity of food restriction and distance between treatments, period of food restriction, as well as the great diversity of variables evaluated, as reported by Klein et al⁶ in a literature review on the subject.

Data selection and group formation

Four carcass traits of the progeny selected as response variables, including males and females. For this meta-analysis, the measurements of hot carcass weight (HCW), obtained prior to entering the cold chamber, subcutaneous fat thickness (SFT), marbling and Longissimus dorsi area (LDA) used. These last three measurements obtained in the Longissimus dorsi muscle between the 12^th and 13^th ribs. The average daily weight gain (ADG) evaluated during the breastfeeding period, and the post-weaning ADG considered as the daily weight gain of calves during the rearing phase.

The weight variation of cows during gestation was used to standardization the tested effects (treatments), according to the equation below:

WV= (IW-FW)IW X 100

where WV represents the variation in weight of the cow between the beginning of the experimental period and calving; IW represents the weight of the cow at the beginning of experiment; FW represents the weight of cow at calving.

This standardization was necessary due to great variability of treatments of the researches included in the database. Thus, the meta-analysis consists of two groups according to weight variation classes: moderate loss (ML= cows that lost 0 to 5 % of weight during gestation) and moderate gain (MG= cows that gained 0 to 5 % of weight during gestation). In this meta-analysis, the moderate loss (ML) is used as a control group. The data for each study, such as number of replicates, means and standard deviations, organized in Microsoft® Office Excel® spreadsheets for further analysis.

Meta-analytical procedure

Statistical analyses were performed using the software R version 4.0.2¹⁶, through the ‘meta’ package, ‘metacont’ function¹⁷. Egger’s linear regression asymmetry was used to examine the presence of publication bias¹⁸, with a significant bias value when P<0.05, through the 'metabias' function. In addition, funnel plots were used to evaluate publication bias in meta-analysis through the 'funnel' function. The funnel plot graphically shows the precision of the estimated intervention effect, where smaller studies had a wider variance and larger ones had less spread of variability. In the absence of bias, the funnel plot should be approximately symmetrical. The effect size was calculated as the mean difference (MD), which is the difference between the control and experimental groups (subgroups weight gain and severe loss WG and SL from cow’ body weight). The MD requires that all studies have the same unit of measurement but allows for the interpretation of effect size in the original units¹⁹. The effects of variation in the weight of the cow during gestation were expressed in forest plot graphs, constructed from the 'forest' function, using the estimated MD. The meta package provides a forest plot with the effect size and weighted contribution to each study from fixed and random effect models¹⁷.

The consistency of results between the experiments was quantified using the measures of heterogeneity of the Chi-square test (Q) and I² statistics²⁰, which quantifies the impact of heterogeneity on the meta-analysis, whit a mathematical criterion independent of the number of studies and the metric effect of each treatment. Although the Q test is helpful in identifying heterogeneity, the measure I² was used to measure heterogeneity²⁰. The I² statistic is given by:

I2%= Q-(k-1)QX 100

where Q is the χ ² heterogeneity statistic and k is the number of trials. The I² statistic describes the percentage of variation across studies due to heterogeneity. Negative values of I² are set equal to zero; consequently, I² lies between 0 and 100%²¹. Its value might not be important if it falls within the range 0-40 %. However, a value of 30-60 % often indicates moderate heterogeneity, 50-90 % might represent substantial heterogeneity, and value in the range of 75-100 % represents considerable heterogeneity²².

Results

The funnel plots for cow weight variation effect, during pregnancy at progeny carcass characteristics are expressed in Figure 1, and no substantial asymmetry was observed in most characteristics analyzed²².

a) Hot carcass weight; b) Subcutaneous fat thickness; c) Marbling; d) Longissimus dorsi area. Each point represents an individual randomized trial. The y-axis is the standard error of the trials and the x-axis is the effect size. The Larger studies appear toward the top of the plot and cluster around of effect size (mean) and smaller studies appear toward the bottom of the plot. When publication bias has occurred one expects an asymmetry in the scatter of small studies with more studies showing a positive result than those showing a negative result.

Figure 1 Funnel plot for cow weight variation during gestation at progeny performance

The variation from cow weight (ML and MG), the number of studies, the mean gross difference and the size of the effect of each variable, P values and heterogeneity, are demonstrated in Table 2. Egger’s test showed that the variables evaluated don’t have publication bias (P>0.05).

Table 2 Effect size and heterogeneity for weight variation in beef cows during pregnancy on progeny performance

Item^A	Number of studies	MD	95% confidence intervals	P- value ^B	Q	P- value ^C	I² (%)	P- value ^D
HCW, kg	10	3.23	-1.25, 7.72	0.1580^**	2.54	0.9797	0	0.7841
SFT, cm	10	0.05	-0.01, 0.10	0.1030^**	8.07	0.5275	0	0.0825
M, points	9	-0.16	-12.96, 12.63	0.9802^NS	9.61	0.2932	17	-
LDA, cm²	10	1.13	-0.55, 2.82	0.1881^NS	15.20	0.0857	41	0.9031

^AItem, HCW= Hot carcass weight; SFT= Subcutaneous fat thickness; M= Marbling; LDA = Longissimus dorsi area.

^BP-value for MD, *Significant at 5% probability; ** Tendency; ^NS Not significant.

^CP-value for Q statistics;

I², Statistics of the estimated heterogeneity.

^DP-value for Egger’s test; - Number of studies (k<10) too small to test for small study effects¹⁸.

In general, the meta-analysis did not identify major effects of cow weight variation during pregnancy at progeny carcass characteristics (P>0.05). Despite the low studies number published in this research line, the hot carcass weight showed a favorable trend for the progeny of MG cows (P=0.15), which produced 3.25 kg more carcass at progeny from ML cows (Figure 2). Likewise, animals from MG cows at gestation end showed tendency (P=0.10) for greater thickness of subcutaneous fat compared to animals from ML cows (Figure 3). The average difference was 0.05 cm between the groups studied.

The solid line of the x-axis is the no-effect line and dotted lines represent the estimated difference of the random model; therefore, the points to the left of the line represent a reduction in the trait, while the points to the right of the line indicate an increase. Each square relative weight of the study of the overall estimate of effect size with the larger squares representing a larger weight. The upper and lower bound of the squared line represents the upper and lower confidence intervals of 95% for the size of the effect. The diamond at the bottom represents the 95% confidence interval for the global estimate.

Figure 2 Forest plot for hot carcass weight (HCW, kg) of the progeny from cows with different weight variations during gestation

Figure 3 Forest plot for subcutaneous fat thickness (SFT, cm) of the progeny from cows with different weight variations during gestation

The progeny of ML and MG cows didn’t show differences (P= 0.9802) in meat marbling content (Figure 4), with average value of 438 points, equivalent to small marbling content according the classification used. Likewise, the Longissimus dorsi area was not influenced (P= 0.1881) by weight variation from pregnant cows (Figure 5).

Figure 4 Forest plot for Marbling (points*) of the progeny from cows with different weight variations during gestation

Figure 5 Forest plot for Longissimus dorsi area (LDA, cm²) of the progeny from cows with different weight variations during gestation

Discussion

Among factors that can modify the uterine environment²³, maternal nutrition during pregnancy stands out, which according to the authors can modify developing fetus metabolism and physiology. Several studies have demonstrated interferences from nutrition of the pregnant cow and the consequent variation in cow's weight and body score, but with many divergences, on the progeny performance in adulthood. In the meta-analysis, it was found some influences of cow’s weight variation at final gestation period on the steer’s carcass characteristics.

The trends for higher hot carcass weight and subcutaneous fat thickness for the progeny of MG cows presented in Figures 2 and 3, respectively. The results corroborate the theories described by Du et al², who state that improving nutrition during the final stage of pregnancy favors the processes of myogenesis and adipogenesis of progeny, and consequently improves muscle mass and fat in the carcass. In a similar study, Rodrigues et al²⁴ obtained higher HCW in cows that gained up to 10 % of their body weight during pregnancy compared to cows that lost 0 to 10 % and 10 to 20% of weight during that period. The authors did not observe changes in SFT in that study. Body growth depends on the processes of hyperplasia and hypertrophy of preformed muscle fibers during pregnancy², and the nutritional restriction in this period impairs these processes due to the lower nutritional priority compared to other fetal tissues and organs²⁵.

Unlike subcutaneous fat, the weight variation of the pregnant cow did not alter the intramuscular fat deposition, known as marbling fat (Figure 4). Like the body fat deposition, the formation of adipocytes during pregnancy follows a chronological sequence. In a scheme presented by Du et al²⁶, there is sequential and overlapping deposition of visceral, subcutaneous, intermuscular and intramuscular fat. Du et al³ conclude that the formation of intramuscular adipocytes, the last to be formed, can extend over the first months of an individual’s life (approximately 250 d). Thus, postnatal life nutrition could have more effect than fetal programming intramuscular adipogenesis²⁷, according to the results obtained in the present meta-analysis, since adipocytes, despite being scarce, can increase their size as nutritional leftovers occur. In general, the similarity in adipose tissue deposition may be a consequence of the small variation in weight among cows that lost or gained weight during pregnancy, with an average of less than 5%.

The cow weight gain during late pregnancy did not improve the Longissimus dorsi area (Figure 5), corroborating the findings of Rodrigues et al²⁴. This result may be a consequence of environmental adaptation of cow calves after birth. Webb et al⁵ describe that malnutrition or food restriction during pregnancy ends up producing a phenotype that has greater adaptive skills when exposed to unfavorable environments in adulthood. Ramírez et al²⁷ conclude that the severe nutrient restriction during pregnancy can also compensate for the individual’s growth after birth, when it is exposed to restricted environments also after birth. Bell et al²⁸ also add that there may be a plasticity of postnatal rearing systems in regulation of muscle hypertrophy capable of overcoming the negative effects at pregnancy nutritional restriction.

In addition to the greater adaptation capacity from progeny in postnatal life, the fetal programming effects and the nutrients supply of the fetus can be dependent on metabolic adaptation capacity of pregnant cows. Bauman et al²⁹ describe that nutrient partition of cows through hemorrhagic and homeostatic mechanisms, where the fetus has nutritional body priorities. These mechanisms may explain the mobilization of body reserves and cow weight loss during pregnancy to maintain an adequate supply of nutrients to the fetus under moderate conditions of nutritional restrictions⁵. Thus, a small reduction in body weight of the pregnant cow, within 0 to ± 5%, can be accepted in production systems as it does not interfere with the progeny carcass characteristics.

Thus, these results corroborate those of Klein et al⁶, who found through the literature review that effects of fetal programming, or pregnant cow nutrition, are more noticeable in the early months of the progeny 's life, with lesser effects with the advancing age of these animals. Brameld et al³⁰ complement that, with enough time during postnatal life, the animal is able to overcome or compensate for most of these initial differences, resulting in only small (if any) residual effects on body composition in later growth stages. In general, the absence of effects on pregnant cow nutrition at carcass characteristics verified in this study can be attributed to the low weight variation or challenge to pregnant cows. The intensity of nutritional insult is an important factor to be considered in evaluation of the effects from fetal programming on offspring quality. Therefore, the adoption of a nutritional system that provides weight gain to pregnant cows not only depend on progeny performance evaluation, but also on a economic analysis of the entire calf production cycle according the desired goals.

Conclusions and implications

The results obtained in this meta-analysis indicate that small cow's weight variations effects during the second and / or third trimester of pregnancy are difficult to be found in adulthood and post-slaughter carcass characteristics of the progeny.

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Received: September 16, 2021; Accepted: May 30, 2022

^*Corresponding author: sander.adams@hotmail.com

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