Journal of Animal Reproduction and Biotechnology 2024; 39(2): 121-130
Published online June 30, 2024
https://doi.org/10.12750/JARB.39.2.121
Copyright © The Korean Society of Animal Reproduction and Biotechnology.
Shil Jin* , Sung-Sik Kang , Jeong Il Won , Hyoun Ju Kim , Sun Sik Jang and Sung Woo Kim
Hanwoo Research Institute, National Institute of Animal Science, Rural Development Administration, Pyeongchang 25340, Korea
Correspondence to: Shil Jin
E-mail: jins21@korea.kr
This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/), which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
Background: This study focused on reproductive traits in Hanwoo cattle, specifically the environmental factors affecting gestation length and birth weight.
Methods: The records of 1,540 cows calved at the Hanwoo Research Institute from 2015 to 2023 were examined. This study analyzed two populations, line-breeding Hanwoo (LBH) and general Hanwoo (GH), with all cows undergoing estrus synchronization and artificial insemination. The R software was used to compare the differences between the two populations and analyze the environmental factors affecting each trait.
Results: The results showed that the average gestation length for LBH was 283.28 ± 5.93 days, which was significantly shorter than that of the GH, which had an average of 285.63 ± 6.21 days (p < 0.001). The average birth weight of LBH calves was 25.10 ± 3.69 kg, significantly lighter than GH calves, which weighed 27.26 ± 4.11 kg on average (p < 0.001). Analysis of environmental factors revealed significant differences in the gestation length of LBH based on dam parity, year, and season of calving. However, no significant differences were observed based on calf sex. For LBH, birth weight showed significant differences based on dam parity, year of calving, and sex of the calf, but not the season of calving. In GH, gestation length varied with dam parity and calving season, but not with calving year or calf sex. The GH birth weight showed differences based on dam parity, year of calving, and calf sex, but not the season of calving.
Conclusions: Reproductive traits in the Hanwoo cattle industry are economically vital but are heavily influenced by environmental factors due to their low heritability. An accurate evaluation of the genetic potential of these traits requires an analysis of the environmental factors affecting them. The results of this study serve as foundational data for predicting the potential for genetic improvement in the gestation length and birth weight of Hanwoo cattle.
Keywords: birth weight, gestation length, Hanwoo, reproductive trait
Interest in improving the genetic capabilities of cows in Hanwoo cattle (Korean native cattle) continues to grow. This is because the abilities of both the sire and dam are important for producing superior calves. In Korea, a Hanwoo cattle improvement program is conducted at the national level, leading to the selection and numbering of Hanwoo proven bulls (Korean Proven Bull’s Number, KPN). Semen produced by Hanwoo proven bulls is distributed to farms, facilitating the enhancement of Hanwoo cattle through artificial insemination (AI) and contributing to increased income for farms (Kim et al., 2017; Choi et al., 2018). Therefore, farms must select superior cows for breeding to produce calves with excellent genetic capabilities.
Among the various capabilities of cows, reproductive ability is a crucial economic trait directly linked to farm income. This study investigated and analyzed the gestation length of dams and calf birth weight among the various reproductive traits of Hanwoo cattle. Gestation length in cattle is defined as the duration from conception to birth of the calf. Typically, a shorter gestation length is linked to a lighter birth weight, easier calving, and enhanced subsequent reproductive performance in dams. Additionally, calves born after a shorter gestation length tend to have longer post-birth growth periods, which can lead to heavier weaning weights (BREEDPLAN, 2024).
The ranges for gestation length and birth weight in Hanwoo cattle, as well as the environmental factors affecting these traits, such as the region, farm, parity of the dam, timing of calving (year and season of calving), sex of the calf, and sire, have been reported to vary significantly depending on the time of investigation and experimental subjects. Lopez et al. (2019) noted that calving-related traits in Hanwoo cattle, including gestation length, exhibited low heritabilities ranging from 0.03 to 0.13. However, they emphasized that the economic importance of these traits should not be overlooked, and that through improved management techniques, it is necessary to develop these traits to reach optimal levels.
Similar to all other traits, reproductive traits are determined by complex interactions between genetic and environmental factors, with a particularly significant influence of external environmental conditions. Therefore, understanding the environmental factors affecting reproductive traits is essential before efforts to genetically improve these traits can begin.
This study investigated the gestation length and birth weight of two populations at the Hanwoo Research Institute (HRI) of the National Institute of Animal Science (NIAS) and analyzed the environmental factors influencing these traits. Hanwoo cattle are known for their distinct genetic characteristics and pure bloodline, distinguishable from exotic beef species, as outlined in the Livestock Industry Act. To preserve these qualities, the Hanwoo proven bulls are selected from a diverse range of pedigrees, taking into consideration the lineage of the sire and maternal grandsire to maintain genetic diversity within the entire Hanwoo population and to prevent inbreeding depression (Jin et al., 2023). Additionally, the HRI has been maintaining a line-breeding population using its own non-KPN sires to enhance the genetic diversity of Hanwoo cattle. From this line-breeding population of the HRI, two outstanding animals are selected annually as candidate bulls, contributing to the preservation of genetic diversity in Hanwoo cattle (MAFRA, 2024). The HRI thus maintains two distinct populations: the line-breeding Hanwoo (LBH), a line-breeding population that has been maintained since 2009 at HRI using proprietary bulls selected, and the general Hanwoo (GH), a population formed using Hanwoo proven bulls. A previous study compared the two populations based on 11 microsatellite markers, showing genetic differences between the populations (Jin et al., 2023).
In the present study, we investigated the gestation lengths and birth weights of two populations of Hanwoo cattle raised under the same feeding and gestational environments. Our objective was to analyze the environmental effects on these reproductive traits and to use the data from these populations to predict the potential for genetic improvement of gestation length and birth weight of Hanwoo cattle. These insights are crucial for understanding how external conditions influence reproductive outcomes and for informing future breeding strategies.
In this study, we analyzed the calving records of 1,540 Hanwoo cows that delivered normal singletons between 2015 and 2023 at the HRI of NIAS. The dataset included the records of 910 LBH and 630 GH cows. LBH is a line-breeding population that has been maintained at the HRI since 2009 using selected proprietary bulls, and GH is a population formed using Hanwoo proven bulls. All experimental procedures were conducted according to national and institutional guidelines and were approved by the Ethical Committee of the NIAS, Republic of Korea (approval number: 2020-449).
All individuals were inseminated through AI following estrus synchronization. Regardless of the estrous cycle stage, each cow was fitted with a Controlled Internal Drug Release (CIDR) device containing 1.9 g of progesterone (CIDR; Zoetis, New Zealand) inserted into the vagina at 09:00. Concurrently, 2 mL (100 mcg gonadorelin acetate/mL) of gonadotropin-releasing hormone (GnRH; Fertagyl GmbH, Germany) was administered via injection into the neck muscles. Seven days later, the CIDR device was removed at 09:00, followed by the administration of 5 mL (5 mg dinoprost tromethamine/mL) of prostaglandin F2α (PGF2a; Lutalyse, Zoetis, Belgium).
Two days after the removal of the CIDR, a further 2 mL of GnRH was injected to induce ovulation. AI procedures were performed at 18:00 on the day of the GnRH injection (first AI) and again at 09:00 the following morning (second AI). The semen used for AI contained an average of 18 million sperm per 0.5 mL straw. Before the AI procedure, semen straws were thawed in water at 37℃ for 40 s and loaded into an AI gun fitted with a protective sheath. Skilled technicians performed the insemination. Further details regarding estrus synchronization and AI have been described by Kang et al. (2024).
The gestation length was calculated from the second AI date to the day of calving. Birth weight was measured immediately after birth (within 8 h). The final analysis included gestation lengths of 260 to 310 days and calf birth weights ranging from 17 to 38 kg. The number of cows used per parity for calving is shown in Table 1.
Table 1 . Number of data used for analysis by parity in two Hanwoo populations
Parity | LBH (N) | GH (N) |
---|---|---|
1 | 286 | 185 |
2 | 167 | 131 |
3 | 150 | 111 |
4 ≤ | 307 | 203 |
Total | 910 | 630 |
LBH, line-breeding Hanwoo; GH, general Hanwoo; N, number of animals.
For the comparative analysis between various groups, cows were classified into three groups based on parity: Group A included heifers and cows; Group B comprised 1st, 2nd, 3rd, and higher parity cows; and Group C consisted of 1st, 2nd, 3rd, and 4th or higher parity cows.
The calving seasons were classified as follows: March to May (spring); June to August (summer); September to November (fall); and December to February (winter). Although Group A is categorized into four seasons, AI at HRI specifically targets calve births in spring and fall. Due to the unequal distribution of samples across the seasons, Group B was designated for comparing the spring and fall seasons.
R software (R Foundation for Statistical Computing, Vienna, Austria) was used for data preprocessing and variance analysis. The data preprocessing steps included handling missing values and detecting and correcting outliers.
The primary objective of this study was to evaluate the differences in gestation length and birth weight between LBH and GH cattle, as well as the differences between groups according to various environmental factors. For this purpose, linear models were constructed, and variance analysis (ANOVA) was conducted to quantitatively assess the differences between groups.
To assess whether the differences between groups were statistically significant, Duncan’s new multiple range test, which uses the mean square error, was conducted. This test was used to identify groups with statistically significant differences and to analyze the specific differences between the group means.
Significant differences were observed in both gestation length and birth weight between the LBH and GH populations (Table 2). The average gestation length for LBH was 283.28 ± 5.93 days, while for GH it was 285.63 ± 6.21 days, with the LBH having a significantly shorter gestation length (
Table 2 . Statistical analysis of gestation length of dams and birth weight of calves in two Hanwoo populations
Population | N | GL (day) | BW (kg) | |||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
Mean | SD | MIN | MAX | Mean | SD | MIN | MAX | |||||
LBH | 910 | 283.28b | 5.93 | 261 | 309 | < 0.001 | 25.10b | 3.69 | 17 | 38 | < 0.001 | |
GH | 630 | 285.63a | 6.21 | 264 | 310 | 27.26a | 4.11 | 17 | 38 |
a,bValues in columns denoted by different superscript lower-case letters differ significantly among groups (
Table 3 shows the analysis results based on the parity of the dam. In LBH, the gestation length was significantly shorter for heifers at 282.65 ± 6.07 days compared with that of cows that had given birth once, which was 283.56 ± 5.85 days (Group A,
Table 3 . Effect of parity of dams on gestation length and birth weight of calves in two Hanwoo populations
Variation | LBH | GH | ||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Group | Parity | N | Mean ± SD | MIN | MAX | N | Mean ± SD | MIN | MAX | |||||
GL (day) | A | 1 | 286 | 282.65 ± 6.07b | 261 | 302 | 0.03 | 185 | 285.01 ± 6.33 | 264 | 310 | 0.105 | ||
2 ≤ | 624 | 283.56 ± 5.85a | 263 | 309 | 445 | 285.89 ± 6.15 | 264 | 308 | ||||||
B | 1, 2 | 453 | 282.66 ± 6.27b | 261 | 305 | 0.002 | 316 | 285.12 ± 6.25b | 264 | 310 | 0.041 | |||
3 ≤ | 457 | 283.89 ± 5.53a | 266 | 309 | 314 | 286.13 ± 6.14a | 264 | 308 | ||||||
C | 1 | 286 | 282.65 ± 6.07b | 261 | 302 | 0.004 | 185 | 285.01 ± 6.33b | 264 | 310 | 0.027 | |||
2 | 167 | 282.67 ± 6.60b | 263 | 305 | 131 | 285.29 ± 6.15b | 264 | 306 | ||||||
3 | 150 | 283.18 ± 5.61a,b | 266 | 302 | 111 | 285.09 ± 5.46b | 271 | 308 | ||||||
4 ≤ | 307 | 284.24 ± 5.46a | 267 | 309 | 203 | 286.70 ± 6.42a | 264 | 307 | ||||||
BW (kg) | A | 1 | 286 | 24.49 ± 3.67b | 17 | 34 | < 0.001 | 185 | 26.42 ± 4.07b | 17 | 37 | < 0.001 | ||
2 ≤ | 624 | 25.37 ± 3.68a | 17 | 38 | 445 | 27.61 ± 4.07a | 17 | 38 | ||||||
B | 1, 2 | 453 | 24.75 ± 3.74b | 17 | 38 | 0.005 | 316 | 26.34 ± 3.99b | 17 | 38 | < 0.001 | |||
3 ≤ | 457 | 25.44 ± 3.62a | 17 | 37 | 314 | 28.18 ± 4.02a | 18 | 37 | ||||||
C | 1 | 286 | 24.49 ± 3.67b | 17 | 34 | 0.006 | 185 | 26.42 ± 4.07b | 17 | 37 | < 0.001 | |||
2 | 167 | 25.20 ± 3.83a,b | 17 | 38 | 131 | 26.23 ± 3.88b | 17 | 38 | ||||||
3 | 150 | 25.23 ± 3.76a,b | 17 | 36 | 111 | 28.00 ± 4.49a | 18 | 37 | ||||||
4 ≤ | 307 | 25.54 ± 3.55a | 17 | 37 | 203 | 28.28 ± 3.75a | 18 | 37 |
a,bValues in columns denoted by different superscript lower-case letters differ significantly among groups (
Both LBH and GH groups showed differences in birth weight according to dam parity. In LBH, the birth weight was significantly heavier for calves from cows (25.37 ± 3.68 kg) than those from heifers (24.49 ± 3.67 kg) (Group A,
There were significant yearly differences in gestation length for LBH (
Table 4 . Effect of calving year on gestation length and birth weight of calves in two Hanwoo populations
Variation | LBH | GH | ||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
N | Mean ± SD | MIN | MAX | N | Mean ± SD | MIN | MAX | |||||
GL (day) | 2015 | 4 | 278.75 ± 5.19c | 275 | 286 | < 0.001 | - | - | - | - | 0.156 | |
2016 | 62 | 281.39 ± 6.04b,c | 268 | 296 | 42 | 286.14 ± 8.14 | 267 | 308 | ||||
2017 | 78 | 284.65 ± 6.08a,b | 270 | 302 | 52 | 285.23 ± 5.59 | 270 | 297 | ||||
2018 | 53 | 282.04 ± 6.43a,b,c | 264 | 297 | 51 | 284.73 ± 6.81 | 268 | 297 | ||||
2019 | 123 | 282.34 ± 7.16a,b | 261 | 301 | 62 | 284.24 ± 7.78 | 264 | 300 | ||||
2020 | 157 | 284.50 ± 6.19a,b | 266 | 309 | 105 | 286.12 ± 6.14 | 268 | 306 | ||||
2021 | 105 | 285.09 ± 4.86a | 273 | 298 | 104 | 286.24 ± 6.02 | 264 | 307 | ||||
2022 | 176 | 283.39 ± 4.64a,b | 270 | 302 | 103 | 286.60 ± 5.16 | 277 | 310 | ||||
2023 | 152 | 282.01 ± 5.64a,b,c | 265 | 297 | 111 | 284.86 ± 5.33 | 273 | 302 | ||||
BW (kg) | 2015 | 4 | 20.75 ± 2.22d | 19 | 24 | < 0.001 | - | - | - | - | < 0.001 | |
2016 | 62 | 23.56 ± 3.12b,c | 18 | 34 | 42 | 25.38 ± 3.89c,d | 18 | 36 | ||||
2017 | 78 | 26.06 ± 2.96a | 20 | 33 | 52 | 27.42 ± 3.46a,b | 20 | 37 | ||||
2018 | 53 | 22.17 ± 3.30c,d | 17 | 31 | 51 | 24.87 ± 4.07d | 17 | 33 | ||||
2019 | 123 | 24.52 ± 3.64a,b | 17 | 38 | 62 | 26.52 ± 3.87b,c | 18 | 36 | ||||
2020 | 157 | 25.89 ± 3.91a | 17 | 36 | 105 | 27.62 ± 3.64a,b | 20 | 37 | ||||
2021 | 105 | 25.51 ± 3.40a,b | 18 | 37 | 104 | 27.17 ± 4.22a,b | 17 | 36 | ||||
2022 | 176 | 25.46 ± 3.17a,b | 18 | 34 | 103 | 28.49 ± 4.08a | 18 | 38 | ||||
2023 | 152 | 25.31 ± 4.19a,b | 17 | 37 | 111 | 28.00 ± 4.27a,b | 17 | 37 |
a-dValues denoted in columns by different superscript lower-case letters differ significantly among groups (
Both LBH and GH exhibited differences in gestation length and birth weight depending on the calving season (Table 5). Among LBH cows, those calving in the fall had a gestation length of 284.76 ± 6.68 days, which was significantly longer than those calving in other seasons (Group A,
Table 5 . Effect of calving season on gestation length and birth weight of calves in two Hanwoo populations
Variation | LBH | GH | ||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Group | Season | N | Mean ± SD | MIN | MAX | N | Mean ± SD | MIN | MAX | |||||
GL (day) | A | Spring | 295 | 282.51 ± 6.17b | 264 | 302 | < 0.001 | 314 | 285.19 ± 6.08a,b | 264 | 307 | < 0.001 | ||
Summer | 212 | 283.04 ± 4.81b | 263 | 298 | 66 | 281.68 ± 4.50c | 271 | 293 | ||||||
Fall | 281 | 284.76 ± 6.68a | 261 | 309 | 238 | 287.39 ± 6.26a | 264 | 310 | ||||||
Winter | 122 | 282.11 ± 4.52b | 265 | 294 | 12 | 283.83 ± 4.15b,c | 280 | 293 | ||||||
B | Spring | 295 | 282.51 ± 6.17b | 264 | 302 | < 0.001 | 314 | 285.19 ± 6.08b | 264 | 307 | < 0.001 | |||
Fall | 281 | 284.76 ± 6.68a | 261 | 309 | 238 | 287.39 ± 6.26a | 264 | 310 | ||||||
BW (kg) | A | Spring | 295 | 25.14 ± 3.56 | 17 | 38 | 0.083 | 314 | 27.43 ± 3.86 | 17 | 38 | 0.191 | ||
Summer | 212 | 25.15 ± 3.81 | 17 | 37 | 66 | 26.48 ± 4.05 | 17 | 37 | ||||||
Fall | 281 | 24.73 ± 3.69 | 17 | 36 | 238 | 27.33 ± 4.43 | 17 | 37 | ||||||
Winter | 122 | 25.75 ± 3.76 | 17 | 37 | 12 | 25.67 ± 3.42 | 21 | 34 | ||||||
B | Spring | 295 | 25.14 ± 3.56 | 17 | 38 | 0.171 | 314 | 27.43 ± 3.86 | 17 | 38 | 0.781 | |||
Fall | 281 | 24.73 ± 3.69 | 17 | 36 | 238 | 27.33 ± 4.43 | 17 | 37 |
a-cValues denoted in columns by different superscript lower-case letters differ significantly among groups (
The average birth weight of LBH calves born in spring was 25.14 ± 3.56 kg, while those born in fall had an average birth weight of 25.73 ± 3.69 kg. For GH calves, the average birth weight of those born in spring was 27.43 ± 3.86 kg, and for those born in fall, it was 27.33 ± 4.43 kg. However, there was no significant difference in calf birth weight between the calving seasons for either LBH or GH (Group B,
The analysis results based on calf sex are described in Table 6. There was no difference in gestation length based on calf sex for either LBH or GH. For LBH, the gestation length of dams producing female calves was 282.91 ± 5.63 days, while for dams producing male calves, it was 283.67 ± 6.22 days (
Table 6 . Effect of calf sex on gestation length and birth weight of calves in two Hanwoo populations
Variation | LBH | GH | ||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
N | Mean ± SD | MIN | MAX | N | Mean ± SD | MIN | MAX | |||||
GL (day) | Female | 469 | 282.91 ± 5.63 | 264 | 305 | 0.054 | 314 | 285.52 ± 6.01 | 264 | 307 | 0.673 | |
Male | 441 | 283.67 ± 6.22 | 261 | 309 | 316 | 285.73 ± 6.41 | 264 | 310 | ||||
BW (kg) | Female | 469 | 24.21 ± 3.39b | 17 | 36 | < 0.001 | 314 | 26.21 ± 3.90b | 17 | 37 | < 0.001 | |
Male | 441 | 26.04 ± 3.77a | 17 | 38 | 316 | 28.30 ± 4.04a | 18 | 38 |
a,bValues denoted in columns by different superscript lower-case letters differ significantly among groups (
For both LBH and GH, there was a difference in calf birth weight based on sex. In LBH, the average birth weight of female calves was 24.21 ± 3.39 kg, while that of male calves was 26.04 ± 3.77 kg (
Research findings on gestation length and birth weight in cattle breeds are highly diverse. Even within Hanwoo cattle, there have been various reports on a range of significant environmental factors.
Shin and Baik (1984) reported an average gestation length of 283.9 days for 192 Hanwoo cows surveyed in Jeonbuk Province from 1981 to 1983. Kwon et al. (2019) reported an average gestation length of 287.602 ± 4.797 days for 58,800 cows in Jeonbuk Province from 2010 to 2017. Eum et al. (2016) reported an average gestation length of 289.69 ± 7.883 days for 10,471 Hanwoo cows raised in Gyeongnam province from 2007 to 2015. Recently, Lopez et al. (2020) reported a gestation length range of 271 to 299 days, with a mean of 286.15 days, for 51,303 Hanwoo cow calves from February 1998 to March 2017. The average gestation length of Hanwoo cows has been reported to range from 283 to 289 days, showing variability depending on the region and the subjects investigated.
The average birth weight of Hanwoo cattle has also been variably reported across different regions and subjects since Shin et al. (1975) documented the average birth weight of 233 Hanwoo cattle in the Daegwallyeong region from 1968 to 1974 as 22.72 ± 0.49 kg. Since then, the birth weight of Hanwoo cattle has steadily increased through improvement, and recently, Lopez et al. (2020) reported that the birth weights of 52,173 Hanwoo born between 1998 and 2017 ranged from 17.0 to 38.3 kg, with an average of 27.41 kg.
In Hanwoo cattle, gestation length appeared to increase, as did the birth weight of calves. In the present study, the gestation lengths and birth weights of LBH and GH were all within the range previously reported for Hanwoo cattle; however, LBH cattle tended to have a shorter gestation length of 283.28 ± 5.93 days and a lower birth weight of 25.10 ± 3.69 kg, compared to average Hanwoo cattle (Table 2).
Andersen and Plum (1965) described a positive relation between dam weight and calf birth weight in both cattle and buffaloes, and a positive correlation between gestation length and calf birth weight. In the present study, the gestation length of LBH cows was significantly shorter than that of GH cows (
Shin et al. (1986) reported that in Hanwoo cattle, as parity increases, there is a slight tendency for gestation length to increase, and calves from heifers are the lightest, with calf weight gradually increasing with increasing parity. Kim (2021) found that gestation length is the shortest and birth weight is the lightest for heifers, with both gestation length and birth weight increasing as parity increases up to the seventh parity. In their study of gestation length and birth weight in Hanwoo and Yanbian Yellow cattle, Shin et al. (1999) found that Hanwoo cattle had significantly longer gestation lengths beyond the fifth parity, and birth weight increased from parity one to three. However, there were no significant differences in gestation length or birth weight in Yanbian Yellow cattle.
The results showed that LBH heifers had a significantly shorter gestation length than cows (
For both LBH and GH, the birth weight of calves produced by heifers was significantly lower (
Dam parity is generally considered to influence gestation length and birth weight in cattle, with numerous studies reporting that older cows have longer gestation lengths and larger birth weights than heifers. A positive correlation has also been reported between mature dam body weight, gestation length, and calf birth weight (Andersen and Plum, 1965). Therefore, cows with more than two parities tend to have longer gestation lengths and larger calf birth weights than those with insufficient growth in their first two parities.
The effect of year on gestation length and calf birth weight in Hanwoo cattle was reported by Shin et al. (1986), who found that gestation length increased slightly and birth weight increased as the years progressed from 1974 to 1984. Numerous studies on Hanwoo birth weight during the 1970s and the 1980s reported a significant increase in birth weight over time, indicating active research and improvement efforts in Hanwoo cattle improvement program. Additionally, significant effects of calving year on birth weight have been reported in several studies (Baik et al., 1985; Choi et al., 1988; Son et al., 1997). Recent research by Kim (2021) also reported a trend of increasing gestation length and a significant increase in birth weight as the calving years progressed. Shin et al. (1999) confirmed significant differences in birth weight by calving year in both Hanwoo and Yanbian Yellow cattle but found no difference in gestation length.
In this study, LBH showed significant differences in both gestation length and birth weight according to calving year, whereas GH only exhibited a difference in birth weight (
The effect of calving season on Hanwoo cattle was also investigated. Shin and Baik (1984) reported that the gestation length of cows calving in spring and summer was approximately two days longer than that of cows calving in fall and winter. However, other studies have reported no significant seasonal differences in gestation length in Hanwoo cattle (Han et al., 1989; Han, 2002). Baik et al. (1985) and Shin et al. (1986) reported that calves born in spring or summer tend to have higher birth weights than those born in fall or winter. However, numerous studies have shown either no effect of season or heavier birth weights in calves born in winter (Shin et al., 1975; Shin and Baik, 1984; Choi et al., 1988; Son et al., 1997).
Kim (2021) reported that gestation length was significantly shorter for cows calving in summer, and the birth weights of calves born in summer and fall were significantly lower than those born in spring and winter. Cho et al. (2021) and Park et al. (2022) found that calves born in summer, including July, had significantly lower birth weights, suggesting that heat stress during the late stages of pregnancy may lead to decreased birth weight and impaired fetal growth.
Both LBH and GH, cows that calved in fall had the longest gestation length (
The Daegwallyeong area, where the HRI is located, maintains cool weather even in the summer due to its high altitude compared to other regions in South Korea. In South Korea, the average monthly temperature during the hottest month, August, ranges from 19.7 to 26.7℃. The average maximum temperature in Daegwallyeong during August is 23.6℃ (KMA, 2024). Therefore, it seems that there was no decrease in calf birth weight due to heat stress during summer. However, the environmental differences that dams experience from early to late pregnancy for calving in spring and fall may influence their gestation length. In particular, there was a significant difference in the feed supplied during pregnancy. Cows inseminated in May for calving in March of the following year at the HRI spend their spring consuming hay and rice straw during early pregnancy and receive corn silage during late pregnancy while enduring winter. Conversely, cows inseminated in November received corn silage during early pregnancy and some cows graze on fresh grass during mid-pregnancy. Later in pregnancy, they receive rice straw or hay and experience summer. Corn silage has a high nutrient retention rate and palatability. The nutritional management of dams during pregnancy is reported to regulate fetal development and influence the health and performance of offspring after birth (Šlyžienė et al., 2023). Therefore, seasonal environmental differences appear to have a significant effect on the maintenance of pregnancy and calving.
Shin et al. (1986) and Kim (2021) reported that male calves have significantly longer gestation lengths and higher birth weights than those of female calves. Cho et al. (2021) and Park et al. (2022) also found that the average birth weight of male calves was higher than that of female calves; however, there is also a study showing no significant differences based on sex (Shin and Baik, 1984).
In this study, in both the LBH and GH, the gestation length of cows giving birth to male calves was longer, although the difference was not significant (
It is generally reported that male calves tend to be heavier at birth compared to female calves (Andersen and Plum, 1965). This difference may be attributed to the greater muscle mass and larger skeletal structure in males compared with those in females, which can influence birth weight. However, the exact mechanism by which sex affects birth weight is still not fully understood (Šlyžienė et al., 2023).
In the Hanwoo cattle industry, reproductive traits are economically crucial but are often susceptible to environmental influences due to low genetic heritability. Consequently, the impact of environmental factors on gestation length and birth weight has been widely reported to vary depending on the time and subject of the investigation. Additionally, research on reproductive traits has been limited because selection and improvement have primarily focused on carcass traits in Hanwoo cattle (Lopez et al., 2019).
Recently, Lopez et al. (2019) estimated the genetic parameters for four reproductive traits in Hanwoo cattle using a multi-trait model: age at first calving, calving interval, days open, and gestation length. The heritabilities were found to be low, with age at first calving at 0.01, calving interval at 0.03, days open at 0.03, and gestation length at 0.13. The genetic correlations among these traits ranged from low to high levels, with notable correlations between gestation length and other traits; however, they opined that selection may be challenging consid-ering the low heritabilities. Subsequently, Lopez et al. (2020) estimated genetic parameters for birth weight and weaning weight, determining their direct heritabilities to be 0.22 and 0.51, respectively. Birth weight had genetic correlations of 0.06 with age at first calving and 0.21 with gestation length. Birth weight is typically the first trait measured in calves and is considered an important economic indicator because of its positive association with post-weaning daily weight gain and mature weight.
In this study, significant differences were observed between the two populations with different genetic compositions despite exposure to the same feeding and gestational environments. Further investigation is needed to explore these differences. Most importantly, it is essential to understand and utilize environmental factors to select and improve reproductive traits. Moreover, systematic record-keeping on farms can aid in understanding the characteristics of their own populations, which will help in planning the season and age (parity) of cows to use for calving.
There are limitations in studying traits because most reproduction is conducted through AI at the HRI. However, HRI produces high-quality data through systematic research and record management. Thus, along with the findings of this study, it is crucial to expand the number of traits under investigation and continue to pursue a correlation between the collected data and genetic parameter estimates. The results of this study are expected to accurately predict the reproductive traits of Hanwoo cows and serve as foundational data for further improvement.
Thank you to all members of the Hanwoo Research Institute for their efforts. A special thanks to Mrs. Sooja Hwang and Mrs. Geumsun Jeon for their assistance.
Conceptualization, S.J.; methodology, S.J., J.I.W.; investigation, S.J., S-S.K.; data curation, S.J.; writing - original draft preparation, S.J.; writing - review and editing, S.J., S-S.K., J.I.W., H.J.K., S.S.J., S.W.K.; supervision, S.J.; project administration, J.I.W., H.J.K., S.J.; funding acquisition, J.I.W., H.J.K., S.J.
This research was funded by the Rural Development Administration Research Project (Project Name: Establishment of Line Population for Future Demand, Study of the Genetic Characteristics, and Development of Application Technology for Hanwoo, Project Number: PJ01502802).
All experimental procedures were conducted according to national and institutional guidelines and approved by the Ethical Committee of the National Institute of Animal Science, Republic of Korea (approval number: 2020-449).
Not applicable.
Not applicable.
Not applicable.
No potential conflict of interest relevant to this article was reported.
Journal of Animal Reproduction and Biotechnology 2024; 39(2): 121-130
Published online June 30, 2024 https://doi.org/10.12750/JARB.39.2.121
Copyright © The Korean Society of Animal Reproduction and Biotechnology.
Shil Jin* , Sung-Sik Kang , Jeong Il Won , Hyoun Ju Kim , Sun Sik Jang and Sung Woo Kim
Hanwoo Research Institute, National Institute of Animal Science, Rural Development Administration, Pyeongchang 25340, Korea
Correspondence to:Shil Jin
E-mail: jins21@korea.kr
This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/), which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
Background: This study focused on reproductive traits in Hanwoo cattle, specifically the environmental factors affecting gestation length and birth weight.
Methods: The records of 1,540 cows calved at the Hanwoo Research Institute from 2015 to 2023 were examined. This study analyzed two populations, line-breeding Hanwoo (LBH) and general Hanwoo (GH), with all cows undergoing estrus synchronization and artificial insemination. The R software was used to compare the differences between the two populations and analyze the environmental factors affecting each trait.
Results: The results showed that the average gestation length for LBH was 283.28 ± 5.93 days, which was significantly shorter than that of the GH, which had an average of 285.63 ± 6.21 days (p < 0.001). The average birth weight of LBH calves was 25.10 ± 3.69 kg, significantly lighter than GH calves, which weighed 27.26 ± 4.11 kg on average (p < 0.001). Analysis of environmental factors revealed significant differences in the gestation length of LBH based on dam parity, year, and season of calving. However, no significant differences were observed based on calf sex. For LBH, birth weight showed significant differences based on dam parity, year of calving, and sex of the calf, but not the season of calving. In GH, gestation length varied with dam parity and calving season, but not with calving year or calf sex. The GH birth weight showed differences based on dam parity, year of calving, and calf sex, but not the season of calving.
Conclusions: Reproductive traits in the Hanwoo cattle industry are economically vital but are heavily influenced by environmental factors due to their low heritability. An accurate evaluation of the genetic potential of these traits requires an analysis of the environmental factors affecting them. The results of this study serve as foundational data for predicting the potential for genetic improvement in the gestation length and birth weight of Hanwoo cattle.
Keywords: birth weight, gestation length, Hanwoo, reproductive trait
Interest in improving the genetic capabilities of cows in Hanwoo cattle (Korean native cattle) continues to grow. This is because the abilities of both the sire and dam are important for producing superior calves. In Korea, a Hanwoo cattle improvement program is conducted at the national level, leading to the selection and numbering of Hanwoo proven bulls (Korean Proven Bull’s Number, KPN). Semen produced by Hanwoo proven bulls is distributed to farms, facilitating the enhancement of Hanwoo cattle through artificial insemination (AI) and contributing to increased income for farms (Kim et al., 2017; Choi et al., 2018). Therefore, farms must select superior cows for breeding to produce calves with excellent genetic capabilities.
Among the various capabilities of cows, reproductive ability is a crucial economic trait directly linked to farm income. This study investigated and analyzed the gestation length of dams and calf birth weight among the various reproductive traits of Hanwoo cattle. Gestation length in cattle is defined as the duration from conception to birth of the calf. Typically, a shorter gestation length is linked to a lighter birth weight, easier calving, and enhanced subsequent reproductive performance in dams. Additionally, calves born after a shorter gestation length tend to have longer post-birth growth periods, which can lead to heavier weaning weights (BREEDPLAN, 2024).
The ranges for gestation length and birth weight in Hanwoo cattle, as well as the environmental factors affecting these traits, such as the region, farm, parity of the dam, timing of calving (year and season of calving), sex of the calf, and sire, have been reported to vary significantly depending on the time of investigation and experimental subjects. Lopez et al. (2019) noted that calving-related traits in Hanwoo cattle, including gestation length, exhibited low heritabilities ranging from 0.03 to 0.13. However, they emphasized that the economic importance of these traits should not be overlooked, and that through improved management techniques, it is necessary to develop these traits to reach optimal levels.
Similar to all other traits, reproductive traits are determined by complex interactions between genetic and environmental factors, with a particularly significant influence of external environmental conditions. Therefore, understanding the environmental factors affecting reproductive traits is essential before efforts to genetically improve these traits can begin.
This study investigated the gestation length and birth weight of two populations at the Hanwoo Research Institute (HRI) of the National Institute of Animal Science (NIAS) and analyzed the environmental factors influencing these traits. Hanwoo cattle are known for their distinct genetic characteristics and pure bloodline, distinguishable from exotic beef species, as outlined in the Livestock Industry Act. To preserve these qualities, the Hanwoo proven bulls are selected from a diverse range of pedigrees, taking into consideration the lineage of the sire and maternal grandsire to maintain genetic diversity within the entire Hanwoo population and to prevent inbreeding depression (Jin et al., 2023). Additionally, the HRI has been maintaining a line-breeding population using its own non-KPN sires to enhance the genetic diversity of Hanwoo cattle. From this line-breeding population of the HRI, two outstanding animals are selected annually as candidate bulls, contributing to the preservation of genetic diversity in Hanwoo cattle (MAFRA, 2024). The HRI thus maintains two distinct populations: the line-breeding Hanwoo (LBH), a line-breeding population that has been maintained since 2009 at HRI using proprietary bulls selected, and the general Hanwoo (GH), a population formed using Hanwoo proven bulls. A previous study compared the two populations based on 11 microsatellite markers, showing genetic differences between the populations (Jin et al., 2023).
In the present study, we investigated the gestation lengths and birth weights of two populations of Hanwoo cattle raised under the same feeding and gestational environments. Our objective was to analyze the environmental effects on these reproductive traits and to use the data from these populations to predict the potential for genetic improvement of gestation length and birth weight of Hanwoo cattle. These insights are crucial for understanding how external conditions influence reproductive outcomes and for informing future breeding strategies.
In this study, we analyzed the calving records of 1,540 Hanwoo cows that delivered normal singletons between 2015 and 2023 at the HRI of NIAS. The dataset included the records of 910 LBH and 630 GH cows. LBH is a line-breeding population that has been maintained at the HRI since 2009 using selected proprietary bulls, and GH is a population formed using Hanwoo proven bulls. All experimental procedures were conducted according to national and institutional guidelines and were approved by the Ethical Committee of the NIAS, Republic of Korea (approval number: 2020-449).
All individuals were inseminated through AI following estrus synchronization. Regardless of the estrous cycle stage, each cow was fitted with a Controlled Internal Drug Release (CIDR) device containing 1.9 g of progesterone (CIDR; Zoetis, New Zealand) inserted into the vagina at 09:00. Concurrently, 2 mL (100 mcg gonadorelin acetate/mL) of gonadotropin-releasing hormone (GnRH; Fertagyl GmbH, Germany) was administered via injection into the neck muscles. Seven days later, the CIDR device was removed at 09:00, followed by the administration of 5 mL (5 mg dinoprost tromethamine/mL) of prostaglandin F2α (PGF2a; Lutalyse, Zoetis, Belgium).
Two days after the removal of the CIDR, a further 2 mL of GnRH was injected to induce ovulation. AI procedures were performed at 18:00 on the day of the GnRH injection (first AI) and again at 09:00 the following morning (second AI). The semen used for AI contained an average of 18 million sperm per 0.5 mL straw. Before the AI procedure, semen straws were thawed in water at 37℃ for 40 s and loaded into an AI gun fitted with a protective sheath. Skilled technicians performed the insemination. Further details regarding estrus synchronization and AI have been described by Kang et al. (2024).
The gestation length was calculated from the second AI date to the day of calving. Birth weight was measured immediately after birth (within 8 h). The final analysis included gestation lengths of 260 to 310 days and calf birth weights ranging from 17 to 38 kg. The number of cows used per parity for calving is shown in Table 1.
Table 1. Number of data used for analysis by parity in two Hanwoo populations.
Parity | LBH (N) | GH (N) |
---|---|---|
1 | 286 | 185 |
2 | 167 | 131 |
3 | 150 | 111 |
4 ≤ | 307 | 203 |
Total | 910 | 630 |
LBH, line-breeding Hanwoo; GH, general Hanwoo; N, number of animals..
For the comparative analysis between various groups, cows were classified into three groups based on parity: Group A included heifers and cows; Group B comprised 1st, 2nd, 3rd, and higher parity cows; and Group C consisted of 1st, 2nd, 3rd, and 4th or higher parity cows.
The calving seasons were classified as follows: March to May (spring); June to August (summer); September to November (fall); and December to February (winter). Although Group A is categorized into four seasons, AI at HRI specifically targets calve births in spring and fall. Due to the unequal distribution of samples across the seasons, Group B was designated for comparing the spring and fall seasons.
R software (R Foundation for Statistical Computing, Vienna, Austria) was used for data preprocessing and variance analysis. The data preprocessing steps included handling missing values and detecting and correcting outliers.
The primary objective of this study was to evaluate the differences in gestation length and birth weight between LBH and GH cattle, as well as the differences between groups according to various environmental factors. For this purpose, linear models were constructed, and variance analysis (ANOVA) was conducted to quantitatively assess the differences between groups.
To assess whether the differences between groups were statistically significant, Duncan’s new multiple range test, which uses the mean square error, was conducted. This test was used to identify groups with statistically significant differences and to analyze the specific differences between the group means.
Significant differences were observed in both gestation length and birth weight between the LBH and GH populations (Table 2). The average gestation length for LBH was 283.28 ± 5.93 days, while for GH it was 285.63 ± 6.21 days, with the LBH having a significantly shorter gestation length (
Table 2. Statistical analysis of gestation length of dams and birth weight of calves in two Hanwoo populations.
Population | N | GL (day) | BW (kg) | |||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
Mean | SD | MIN | MAX | Mean | SD | MIN | MAX | |||||
LBH | 910 | 283.28b | 5.93 | 261 | 309 | < 0.001 | 25.10b | 3.69 | 17 | 38 | < 0.001 | |
GH | 630 | 285.63a | 6.21 | 264 | 310 | 27.26a | 4.11 | 17 | 38 |
a,bValues in columns denoted by different superscript lower-case letters differ significantly among groups (
Table 3 shows the analysis results based on the parity of the dam. In LBH, the gestation length was significantly shorter for heifers at 282.65 ± 6.07 days compared with that of cows that had given birth once, which was 283.56 ± 5.85 days (Group A,
Table 3. Effect of parity of dams on gestation length and birth weight of calves in two Hanwoo populations.
Variation | LBH | GH | ||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Group | Parity | N | Mean ± SD | MIN | MAX | N | Mean ± SD | MIN | MAX | |||||
GL (day) | A | 1 | 286 | 282.65 ± 6.07b | 261 | 302 | 0.03 | 185 | 285.01 ± 6.33 | 264 | 310 | 0.105 | ||
2 ≤ | 624 | 283.56 ± 5.85a | 263 | 309 | 445 | 285.89 ± 6.15 | 264 | 308 | ||||||
B | 1, 2 | 453 | 282.66 ± 6.27b | 261 | 305 | 0.002 | 316 | 285.12 ± 6.25b | 264 | 310 | 0.041 | |||
3 ≤ | 457 | 283.89 ± 5.53a | 266 | 309 | 314 | 286.13 ± 6.14a | 264 | 308 | ||||||
C | 1 | 286 | 282.65 ± 6.07b | 261 | 302 | 0.004 | 185 | 285.01 ± 6.33b | 264 | 310 | 0.027 | |||
2 | 167 | 282.67 ± 6.60b | 263 | 305 | 131 | 285.29 ± 6.15b | 264 | 306 | ||||||
3 | 150 | 283.18 ± 5.61a,b | 266 | 302 | 111 | 285.09 ± 5.46b | 271 | 308 | ||||||
4 ≤ | 307 | 284.24 ± 5.46a | 267 | 309 | 203 | 286.70 ± 6.42a | 264 | 307 | ||||||
BW (kg) | A | 1 | 286 | 24.49 ± 3.67b | 17 | 34 | < 0.001 | 185 | 26.42 ± 4.07b | 17 | 37 | < 0.001 | ||
2 ≤ | 624 | 25.37 ± 3.68a | 17 | 38 | 445 | 27.61 ± 4.07a | 17 | 38 | ||||||
B | 1, 2 | 453 | 24.75 ± 3.74b | 17 | 38 | 0.005 | 316 | 26.34 ± 3.99b | 17 | 38 | < 0.001 | |||
3 ≤ | 457 | 25.44 ± 3.62a | 17 | 37 | 314 | 28.18 ± 4.02a | 18 | 37 | ||||||
C | 1 | 286 | 24.49 ± 3.67b | 17 | 34 | 0.006 | 185 | 26.42 ± 4.07b | 17 | 37 | < 0.001 | |||
2 | 167 | 25.20 ± 3.83a,b | 17 | 38 | 131 | 26.23 ± 3.88b | 17 | 38 | ||||||
3 | 150 | 25.23 ± 3.76a,b | 17 | 36 | 111 | 28.00 ± 4.49a | 18 | 37 | ||||||
4 ≤ | 307 | 25.54 ± 3.55a | 17 | 37 | 203 | 28.28 ± 3.75a | 18 | 37 |
a,bValues in columns denoted by different superscript lower-case letters differ significantly among groups (
Both LBH and GH groups showed differences in birth weight according to dam parity. In LBH, the birth weight was significantly heavier for calves from cows (25.37 ± 3.68 kg) than those from heifers (24.49 ± 3.67 kg) (Group A,
There were significant yearly differences in gestation length for LBH (
Table 4. Effect of calving year on gestation length and birth weight of calves in two Hanwoo populations.
Variation | LBH | GH | ||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
N | Mean ± SD | MIN | MAX | N | Mean ± SD | MIN | MAX | |||||
GL (day) | 2015 | 4 | 278.75 ± 5.19c | 275 | 286 | < 0.001 | - | - | - | - | 0.156 | |
2016 | 62 | 281.39 ± 6.04b,c | 268 | 296 | 42 | 286.14 ± 8.14 | 267 | 308 | ||||
2017 | 78 | 284.65 ± 6.08a,b | 270 | 302 | 52 | 285.23 ± 5.59 | 270 | 297 | ||||
2018 | 53 | 282.04 ± 6.43a,b,c | 264 | 297 | 51 | 284.73 ± 6.81 | 268 | 297 | ||||
2019 | 123 | 282.34 ± 7.16a,b | 261 | 301 | 62 | 284.24 ± 7.78 | 264 | 300 | ||||
2020 | 157 | 284.50 ± 6.19a,b | 266 | 309 | 105 | 286.12 ± 6.14 | 268 | 306 | ||||
2021 | 105 | 285.09 ± 4.86a | 273 | 298 | 104 | 286.24 ± 6.02 | 264 | 307 | ||||
2022 | 176 | 283.39 ± 4.64a,b | 270 | 302 | 103 | 286.60 ± 5.16 | 277 | 310 | ||||
2023 | 152 | 282.01 ± 5.64a,b,c | 265 | 297 | 111 | 284.86 ± 5.33 | 273 | 302 | ||||
BW (kg) | 2015 | 4 | 20.75 ± 2.22d | 19 | 24 | < 0.001 | - | - | - | - | < 0.001 | |
2016 | 62 | 23.56 ± 3.12b,c | 18 | 34 | 42 | 25.38 ± 3.89c,d | 18 | 36 | ||||
2017 | 78 | 26.06 ± 2.96a | 20 | 33 | 52 | 27.42 ± 3.46a,b | 20 | 37 | ||||
2018 | 53 | 22.17 ± 3.30c,d | 17 | 31 | 51 | 24.87 ± 4.07d | 17 | 33 | ||||
2019 | 123 | 24.52 ± 3.64a,b | 17 | 38 | 62 | 26.52 ± 3.87b,c | 18 | 36 | ||||
2020 | 157 | 25.89 ± 3.91a | 17 | 36 | 105 | 27.62 ± 3.64a,b | 20 | 37 | ||||
2021 | 105 | 25.51 ± 3.40a,b | 18 | 37 | 104 | 27.17 ± 4.22a,b | 17 | 36 | ||||
2022 | 176 | 25.46 ± 3.17a,b | 18 | 34 | 103 | 28.49 ± 4.08a | 18 | 38 | ||||
2023 | 152 | 25.31 ± 4.19a,b | 17 | 37 | 111 | 28.00 ± 4.27a,b | 17 | 37 |
a-dValues denoted in columns by different superscript lower-case letters differ significantly among groups (
Both LBH and GH exhibited differences in gestation length and birth weight depending on the calving season (Table 5). Among LBH cows, those calving in the fall had a gestation length of 284.76 ± 6.68 days, which was significantly longer than those calving in other seasons (Group A,
Table 5. Effect of calving season on gestation length and birth weight of calves in two Hanwoo populations.
Variation | LBH | GH | ||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Group | Season | N | Mean ± SD | MIN | MAX | N | Mean ± SD | MIN | MAX | |||||
GL (day) | A | Spring | 295 | 282.51 ± 6.17b | 264 | 302 | < 0.001 | 314 | 285.19 ± 6.08a,b | 264 | 307 | < 0.001 | ||
Summer | 212 | 283.04 ± 4.81b | 263 | 298 | 66 | 281.68 ± 4.50c | 271 | 293 | ||||||
Fall | 281 | 284.76 ± 6.68a | 261 | 309 | 238 | 287.39 ± 6.26a | 264 | 310 | ||||||
Winter | 122 | 282.11 ± 4.52b | 265 | 294 | 12 | 283.83 ± 4.15b,c | 280 | 293 | ||||||
B | Spring | 295 | 282.51 ± 6.17b | 264 | 302 | < 0.001 | 314 | 285.19 ± 6.08b | 264 | 307 | < 0.001 | |||
Fall | 281 | 284.76 ± 6.68a | 261 | 309 | 238 | 287.39 ± 6.26a | 264 | 310 | ||||||
BW (kg) | A | Spring | 295 | 25.14 ± 3.56 | 17 | 38 | 0.083 | 314 | 27.43 ± 3.86 | 17 | 38 | 0.191 | ||
Summer | 212 | 25.15 ± 3.81 | 17 | 37 | 66 | 26.48 ± 4.05 | 17 | 37 | ||||||
Fall | 281 | 24.73 ± 3.69 | 17 | 36 | 238 | 27.33 ± 4.43 | 17 | 37 | ||||||
Winter | 122 | 25.75 ± 3.76 | 17 | 37 | 12 | 25.67 ± 3.42 | 21 | 34 | ||||||
B | Spring | 295 | 25.14 ± 3.56 | 17 | 38 | 0.171 | 314 | 27.43 ± 3.86 | 17 | 38 | 0.781 | |||
Fall | 281 | 24.73 ± 3.69 | 17 | 36 | 238 | 27.33 ± 4.43 | 17 | 37 |
a-cValues denoted in columns by different superscript lower-case letters differ significantly among groups (
The average birth weight of LBH calves born in spring was 25.14 ± 3.56 kg, while those born in fall had an average birth weight of 25.73 ± 3.69 kg. For GH calves, the average birth weight of those born in spring was 27.43 ± 3.86 kg, and for those born in fall, it was 27.33 ± 4.43 kg. However, there was no significant difference in calf birth weight between the calving seasons for either LBH or GH (Group B,
The analysis results based on calf sex are described in Table 6. There was no difference in gestation length based on calf sex for either LBH or GH. For LBH, the gestation length of dams producing female calves was 282.91 ± 5.63 days, while for dams producing male calves, it was 283.67 ± 6.22 days (
Table 6. Effect of calf sex on gestation length and birth weight of calves in two Hanwoo populations.
Variation | LBH | GH | ||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
N | Mean ± SD | MIN | MAX | N | Mean ± SD | MIN | MAX | |||||
GL (day) | Female | 469 | 282.91 ± 5.63 | 264 | 305 | 0.054 | 314 | 285.52 ± 6.01 | 264 | 307 | 0.673 | |
Male | 441 | 283.67 ± 6.22 | 261 | 309 | 316 | 285.73 ± 6.41 | 264 | 310 | ||||
BW (kg) | Female | 469 | 24.21 ± 3.39b | 17 | 36 | < 0.001 | 314 | 26.21 ± 3.90b | 17 | 37 | < 0.001 | |
Male | 441 | 26.04 ± 3.77a | 17 | 38 | 316 | 28.30 ± 4.04a | 18 | 38 |
a,bValues denoted in columns by different superscript lower-case letters differ significantly among groups (
For both LBH and GH, there was a difference in calf birth weight based on sex. In LBH, the average birth weight of female calves was 24.21 ± 3.39 kg, while that of male calves was 26.04 ± 3.77 kg (
Research findings on gestation length and birth weight in cattle breeds are highly diverse. Even within Hanwoo cattle, there have been various reports on a range of significant environmental factors.
Shin and Baik (1984) reported an average gestation length of 283.9 days for 192 Hanwoo cows surveyed in Jeonbuk Province from 1981 to 1983. Kwon et al. (2019) reported an average gestation length of 287.602 ± 4.797 days for 58,800 cows in Jeonbuk Province from 2010 to 2017. Eum et al. (2016) reported an average gestation length of 289.69 ± 7.883 days for 10,471 Hanwoo cows raised in Gyeongnam province from 2007 to 2015. Recently, Lopez et al. (2020) reported a gestation length range of 271 to 299 days, with a mean of 286.15 days, for 51,303 Hanwoo cow calves from February 1998 to March 2017. The average gestation length of Hanwoo cows has been reported to range from 283 to 289 days, showing variability depending on the region and the subjects investigated.
The average birth weight of Hanwoo cattle has also been variably reported across different regions and subjects since Shin et al. (1975) documented the average birth weight of 233 Hanwoo cattle in the Daegwallyeong region from 1968 to 1974 as 22.72 ± 0.49 kg. Since then, the birth weight of Hanwoo cattle has steadily increased through improvement, and recently, Lopez et al. (2020) reported that the birth weights of 52,173 Hanwoo born between 1998 and 2017 ranged from 17.0 to 38.3 kg, with an average of 27.41 kg.
In Hanwoo cattle, gestation length appeared to increase, as did the birth weight of calves. In the present study, the gestation lengths and birth weights of LBH and GH were all within the range previously reported for Hanwoo cattle; however, LBH cattle tended to have a shorter gestation length of 283.28 ± 5.93 days and a lower birth weight of 25.10 ± 3.69 kg, compared to average Hanwoo cattle (Table 2).
Andersen and Plum (1965) described a positive relation between dam weight and calf birth weight in both cattle and buffaloes, and a positive correlation between gestation length and calf birth weight. In the present study, the gestation length of LBH cows was significantly shorter than that of GH cows (
Shin et al. (1986) reported that in Hanwoo cattle, as parity increases, there is a slight tendency for gestation length to increase, and calves from heifers are the lightest, with calf weight gradually increasing with increasing parity. Kim (2021) found that gestation length is the shortest and birth weight is the lightest for heifers, with both gestation length and birth weight increasing as parity increases up to the seventh parity. In their study of gestation length and birth weight in Hanwoo and Yanbian Yellow cattle, Shin et al. (1999) found that Hanwoo cattle had significantly longer gestation lengths beyond the fifth parity, and birth weight increased from parity one to three. However, there were no significant differences in gestation length or birth weight in Yanbian Yellow cattle.
The results showed that LBH heifers had a significantly shorter gestation length than cows (
For both LBH and GH, the birth weight of calves produced by heifers was significantly lower (
Dam parity is generally considered to influence gestation length and birth weight in cattle, with numerous studies reporting that older cows have longer gestation lengths and larger birth weights than heifers. A positive correlation has also been reported between mature dam body weight, gestation length, and calf birth weight (Andersen and Plum, 1965). Therefore, cows with more than two parities tend to have longer gestation lengths and larger calf birth weights than those with insufficient growth in their first two parities.
The effect of year on gestation length and calf birth weight in Hanwoo cattle was reported by Shin et al. (1986), who found that gestation length increased slightly and birth weight increased as the years progressed from 1974 to 1984. Numerous studies on Hanwoo birth weight during the 1970s and the 1980s reported a significant increase in birth weight over time, indicating active research and improvement efforts in Hanwoo cattle improvement program. Additionally, significant effects of calving year on birth weight have been reported in several studies (Baik et al., 1985; Choi et al., 1988; Son et al., 1997). Recent research by Kim (2021) also reported a trend of increasing gestation length and a significant increase in birth weight as the calving years progressed. Shin et al. (1999) confirmed significant differences in birth weight by calving year in both Hanwoo and Yanbian Yellow cattle but found no difference in gestation length.
In this study, LBH showed significant differences in both gestation length and birth weight according to calving year, whereas GH only exhibited a difference in birth weight (
The effect of calving season on Hanwoo cattle was also investigated. Shin and Baik (1984) reported that the gestation length of cows calving in spring and summer was approximately two days longer than that of cows calving in fall and winter. However, other studies have reported no significant seasonal differences in gestation length in Hanwoo cattle (Han et al., 1989; Han, 2002). Baik et al. (1985) and Shin et al. (1986) reported that calves born in spring or summer tend to have higher birth weights than those born in fall or winter. However, numerous studies have shown either no effect of season or heavier birth weights in calves born in winter (Shin et al., 1975; Shin and Baik, 1984; Choi et al., 1988; Son et al., 1997).
Kim (2021) reported that gestation length was significantly shorter for cows calving in summer, and the birth weights of calves born in summer and fall were significantly lower than those born in spring and winter. Cho et al. (2021) and Park et al. (2022) found that calves born in summer, including July, had significantly lower birth weights, suggesting that heat stress during the late stages of pregnancy may lead to decreased birth weight and impaired fetal growth.
Both LBH and GH, cows that calved in fall had the longest gestation length (
The Daegwallyeong area, where the HRI is located, maintains cool weather even in the summer due to its high altitude compared to other regions in South Korea. In South Korea, the average monthly temperature during the hottest month, August, ranges from 19.7 to 26.7℃. The average maximum temperature in Daegwallyeong during August is 23.6℃ (KMA, 2024). Therefore, it seems that there was no decrease in calf birth weight due to heat stress during summer. However, the environmental differences that dams experience from early to late pregnancy for calving in spring and fall may influence their gestation length. In particular, there was a significant difference in the feed supplied during pregnancy. Cows inseminated in May for calving in March of the following year at the HRI spend their spring consuming hay and rice straw during early pregnancy and receive corn silage during late pregnancy while enduring winter. Conversely, cows inseminated in November received corn silage during early pregnancy and some cows graze on fresh grass during mid-pregnancy. Later in pregnancy, they receive rice straw or hay and experience summer. Corn silage has a high nutrient retention rate and palatability. The nutritional management of dams during pregnancy is reported to regulate fetal development and influence the health and performance of offspring after birth (Šlyžienė et al., 2023). Therefore, seasonal environmental differences appear to have a significant effect on the maintenance of pregnancy and calving.
Shin et al. (1986) and Kim (2021) reported that male calves have significantly longer gestation lengths and higher birth weights than those of female calves. Cho et al. (2021) and Park et al. (2022) also found that the average birth weight of male calves was higher than that of female calves; however, there is also a study showing no significant differences based on sex (Shin and Baik, 1984).
In this study, in both the LBH and GH, the gestation length of cows giving birth to male calves was longer, although the difference was not significant (
It is generally reported that male calves tend to be heavier at birth compared to female calves (Andersen and Plum, 1965). This difference may be attributed to the greater muscle mass and larger skeletal structure in males compared with those in females, which can influence birth weight. However, the exact mechanism by which sex affects birth weight is still not fully understood (Šlyžienė et al., 2023).
In the Hanwoo cattle industry, reproductive traits are economically crucial but are often susceptible to environmental influences due to low genetic heritability. Consequently, the impact of environmental factors on gestation length and birth weight has been widely reported to vary depending on the time and subject of the investigation. Additionally, research on reproductive traits has been limited because selection and improvement have primarily focused on carcass traits in Hanwoo cattle (Lopez et al., 2019).
Recently, Lopez et al. (2019) estimated the genetic parameters for four reproductive traits in Hanwoo cattle using a multi-trait model: age at first calving, calving interval, days open, and gestation length. The heritabilities were found to be low, with age at first calving at 0.01, calving interval at 0.03, days open at 0.03, and gestation length at 0.13. The genetic correlations among these traits ranged from low to high levels, with notable correlations between gestation length and other traits; however, they opined that selection may be challenging consid-ering the low heritabilities. Subsequently, Lopez et al. (2020) estimated genetic parameters for birth weight and weaning weight, determining their direct heritabilities to be 0.22 and 0.51, respectively. Birth weight had genetic correlations of 0.06 with age at first calving and 0.21 with gestation length. Birth weight is typically the first trait measured in calves and is considered an important economic indicator because of its positive association with post-weaning daily weight gain and mature weight.
In this study, significant differences were observed between the two populations with different genetic compositions despite exposure to the same feeding and gestational environments. Further investigation is needed to explore these differences. Most importantly, it is essential to understand and utilize environmental factors to select and improve reproductive traits. Moreover, systematic record-keeping on farms can aid in understanding the characteristics of their own populations, which will help in planning the season and age (parity) of cows to use for calving.
There are limitations in studying traits because most reproduction is conducted through AI at the HRI. However, HRI produces high-quality data through systematic research and record management. Thus, along with the findings of this study, it is crucial to expand the number of traits under investigation and continue to pursue a correlation between the collected data and genetic parameter estimates. The results of this study are expected to accurately predict the reproductive traits of Hanwoo cows and serve as foundational data for further improvement.
Thank you to all members of the Hanwoo Research Institute for their efforts. A special thanks to Mrs. Sooja Hwang and Mrs. Geumsun Jeon for their assistance.
Conceptualization, S.J.; methodology, S.J., J.I.W.; investigation, S.J., S-S.K.; data curation, S.J.; writing - original draft preparation, S.J.; writing - review and editing, S.J., S-S.K., J.I.W., H.J.K., S.S.J., S.W.K.; supervision, S.J.; project administration, J.I.W., H.J.K., S.J.; funding acquisition, J.I.W., H.J.K., S.J.
This research was funded by the Rural Development Administration Research Project (Project Name: Establishment of Line Population for Future Demand, Study of the Genetic Characteristics, and Development of Application Technology for Hanwoo, Project Number: PJ01502802).
All experimental procedures were conducted according to national and institutional guidelines and approved by the Ethical Committee of the National Institute of Animal Science, Republic of Korea (approval number: 2020-449).
Not applicable.
Not applicable.
Not applicable.
No potential conflict of interest relevant to this article was reported.
Table 1 . Number of data used for analysis by parity in two Hanwoo populations.
Parity | LBH (N) | GH (N) |
---|---|---|
1 | 286 | 185 |
2 | 167 | 131 |
3 | 150 | 111 |
4 ≤ | 307 | 203 |
Total | 910 | 630 |
LBH, line-breeding Hanwoo; GH, general Hanwoo; N, number of animals..
Table 2 . Statistical analysis of gestation length of dams and birth weight of calves in two Hanwoo populations.
Population | N | GL (day) | BW (kg) | |||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
Mean | SD | MIN | MAX | Mean | SD | MIN | MAX | |||||
LBH | 910 | 283.28b | 5.93 | 261 | 309 | < 0.001 | 25.10b | 3.69 | 17 | 38 | < 0.001 | |
GH | 630 | 285.63a | 6.21 | 264 | 310 | 27.26a | 4.11 | 17 | 38 |
a,bValues in columns denoted by different superscript lower-case letters differ significantly among groups (
Table 3 . Effect of parity of dams on gestation length and birth weight of calves in two Hanwoo populations.
Variation | LBH | GH | ||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Group | Parity | N | Mean ± SD | MIN | MAX | N | Mean ± SD | MIN | MAX | |||||
GL (day) | A | 1 | 286 | 282.65 ± 6.07b | 261 | 302 | 0.03 | 185 | 285.01 ± 6.33 | 264 | 310 | 0.105 | ||
2 ≤ | 624 | 283.56 ± 5.85a | 263 | 309 | 445 | 285.89 ± 6.15 | 264 | 308 | ||||||
B | 1, 2 | 453 | 282.66 ± 6.27b | 261 | 305 | 0.002 | 316 | 285.12 ± 6.25b | 264 | 310 | 0.041 | |||
3 ≤ | 457 | 283.89 ± 5.53a | 266 | 309 | 314 | 286.13 ± 6.14a | 264 | 308 | ||||||
C | 1 | 286 | 282.65 ± 6.07b | 261 | 302 | 0.004 | 185 | 285.01 ± 6.33b | 264 | 310 | 0.027 | |||
2 | 167 | 282.67 ± 6.60b | 263 | 305 | 131 | 285.29 ± 6.15b | 264 | 306 | ||||||
3 | 150 | 283.18 ± 5.61a,b | 266 | 302 | 111 | 285.09 ± 5.46b | 271 | 308 | ||||||
4 ≤ | 307 | 284.24 ± 5.46a | 267 | 309 | 203 | 286.70 ± 6.42a | 264 | 307 | ||||||
BW (kg) | A | 1 | 286 | 24.49 ± 3.67b | 17 | 34 | < 0.001 | 185 | 26.42 ± 4.07b | 17 | 37 | < 0.001 | ||
2 ≤ | 624 | 25.37 ± 3.68a | 17 | 38 | 445 | 27.61 ± 4.07a | 17 | 38 | ||||||
B | 1, 2 | 453 | 24.75 ± 3.74b | 17 | 38 | 0.005 | 316 | 26.34 ± 3.99b | 17 | 38 | < 0.001 | |||
3 ≤ | 457 | 25.44 ± 3.62a | 17 | 37 | 314 | 28.18 ± 4.02a | 18 | 37 | ||||||
C | 1 | 286 | 24.49 ± 3.67b | 17 | 34 | 0.006 | 185 | 26.42 ± 4.07b | 17 | 37 | < 0.001 | |||
2 | 167 | 25.20 ± 3.83a,b | 17 | 38 | 131 | 26.23 ± 3.88b | 17 | 38 | ||||||
3 | 150 | 25.23 ± 3.76a,b | 17 | 36 | 111 | 28.00 ± 4.49a | 18 | 37 | ||||||
4 ≤ | 307 | 25.54 ± 3.55a | 17 | 37 | 203 | 28.28 ± 3.75a | 18 | 37 |
a,bValues in columns denoted by different superscript lower-case letters differ significantly among groups (
Table 4 . Effect of calving year on gestation length and birth weight of calves in two Hanwoo populations.
Variation | LBH | GH | ||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
N | Mean ± SD | MIN | MAX | N | Mean ± SD | MIN | MAX | |||||
GL (day) | 2015 | 4 | 278.75 ± 5.19c | 275 | 286 | < 0.001 | - | - | - | - | 0.156 | |
2016 | 62 | 281.39 ± 6.04b,c | 268 | 296 | 42 | 286.14 ± 8.14 | 267 | 308 | ||||
2017 | 78 | 284.65 ± 6.08a,b | 270 | 302 | 52 | 285.23 ± 5.59 | 270 | 297 | ||||
2018 | 53 | 282.04 ± 6.43a,b,c | 264 | 297 | 51 | 284.73 ± 6.81 | 268 | 297 | ||||
2019 | 123 | 282.34 ± 7.16a,b | 261 | 301 | 62 | 284.24 ± 7.78 | 264 | 300 | ||||
2020 | 157 | 284.50 ± 6.19a,b | 266 | 309 | 105 | 286.12 ± 6.14 | 268 | 306 | ||||
2021 | 105 | 285.09 ± 4.86a | 273 | 298 | 104 | 286.24 ± 6.02 | 264 | 307 | ||||
2022 | 176 | 283.39 ± 4.64a,b | 270 | 302 | 103 | 286.60 ± 5.16 | 277 | 310 | ||||
2023 | 152 | 282.01 ± 5.64a,b,c | 265 | 297 | 111 | 284.86 ± 5.33 | 273 | 302 | ||||
BW (kg) | 2015 | 4 | 20.75 ± 2.22d | 19 | 24 | < 0.001 | - | - | - | - | < 0.001 | |
2016 | 62 | 23.56 ± 3.12b,c | 18 | 34 | 42 | 25.38 ± 3.89c,d | 18 | 36 | ||||
2017 | 78 | 26.06 ± 2.96a | 20 | 33 | 52 | 27.42 ± 3.46a,b | 20 | 37 | ||||
2018 | 53 | 22.17 ± 3.30c,d | 17 | 31 | 51 | 24.87 ± 4.07d | 17 | 33 | ||||
2019 | 123 | 24.52 ± 3.64a,b | 17 | 38 | 62 | 26.52 ± 3.87b,c | 18 | 36 | ||||
2020 | 157 | 25.89 ± 3.91a | 17 | 36 | 105 | 27.62 ± 3.64a,b | 20 | 37 | ||||
2021 | 105 | 25.51 ± 3.40a,b | 18 | 37 | 104 | 27.17 ± 4.22a,b | 17 | 36 | ||||
2022 | 176 | 25.46 ± 3.17a,b | 18 | 34 | 103 | 28.49 ± 4.08a | 18 | 38 | ||||
2023 | 152 | 25.31 ± 4.19a,b | 17 | 37 | 111 | 28.00 ± 4.27a,b | 17 | 37 |
a-dValues denoted in columns by different superscript lower-case letters differ significantly among groups (
Table 5 . Effect of calving season on gestation length and birth weight of calves in two Hanwoo populations.
Variation | LBH | GH | ||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Group | Season | N | Mean ± SD | MIN | MAX | N | Mean ± SD | MIN | MAX | |||||
GL (day) | A | Spring | 295 | 282.51 ± 6.17b | 264 | 302 | < 0.001 | 314 | 285.19 ± 6.08a,b | 264 | 307 | < 0.001 | ||
Summer | 212 | 283.04 ± 4.81b | 263 | 298 | 66 | 281.68 ± 4.50c | 271 | 293 | ||||||
Fall | 281 | 284.76 ± 6.68a | 261 | 309 | 238 | 287.39 ± 6.26a | 264 | 310 | ||||||
Winter | 122 | 282.11 ± 4.52b | 265 | 294 | 12 | 283.83 ± 4.15b,c | 280 | 293 | ||||||
B | Spring | 295 | 282.51 ± 6.17b | 264 | 302 | < 0.001 | 314 | 285.19 ± 6.08b | 264 | 307 | < 0.001 | |||
Fall | 281 | 284.76 ± 6.68a | 261 | 309 | 238 | 287.39 ± 6.26a | 264 | 310 | ||||||
BW (kg) | A | Spring | 295 | 25.14 ± 3.56 | 17 | 38 | 0.083 | 314 | 27.43 ± 3.86 | 17 | 38 | 0.191 | ||
Summer | 212 | 25.15 ± 3.81 | 17 | 37 | 66 | 26.48 ± 4.05 | 17 | 37 | ||||||
Fall | 281 | 24.73 ± 3.69 | 17 | 36 | 238 | 27.33 ± 4.43 | 17 | 37 | ||||||
Winter | 122 | 25.75 ± 3.76 | 17 | 37 | 12 | 25.67 ± 3.42 | 21 | 34 | ||||||
B | Spring | 295 | 25.14 ± 3.56 | 17 | 38 | 0.171 | 314 | 27.43 ± 3.86 | 17 | 38 | 0.781 | |||
Fall | 281 | 24.73 ± 3.69 | 17 | 36 | 238 | 27.33 ± 4.43 | 17 | 37 |
a-cValues denoted in columns by different superscript lower-case letters differ significantly among groups (
Table 6 . Effect of calf sex on gestation length and birth weight of calves in two Hanwoo populations.
Variation | LBH | GH | ||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
N | Mean ± SD | MIN | MAX | N | Mean ± SD | MIN | MAX | |||||
GL (day) | Female | 469 | 282.91 ± 5.63 | 264 | 305 | 0.054 | 314 | 285.52 ± 6.01 | 264 | 307 | 0.673 | |
Male | 441 | 283.67 ± 6.22 | 261 | 309 | 316 | 285.73 ± 6.41 | 264 | 310 | ||||
BW (kg) | Female | 469 | 24.21 ± 3.39b | 17 | 36 | < 0.001 | 314 | 26.21 ± 3.90b | 17 | 37 | < 0.001 | |
Male | 441 | 26.04 ± 3.77a | 17 | 38 | 316 | 28.30 ± 4.04a | 18 | 38 |
a,bValues denoted in columns by different superscript lower-case letters differ significantly among groups (
print Article | |
Export to Citation | Open Access |
Google Scholar | Send to Email |
pISSN: 2671-4639
eISSN: 2671-4663