Go to Top Go to Bottom
Anim Biosci > Volume 28(9); 2015 > Article
Luo, Lei, Shen, Yang, Pu, Zhu, Li, Tang, Li, Zhang, and Zhu: Estimation of Growth Curves and Suitable Slaughter Weight of the Liangshan Pig


The Liangshan pig is a traditional Chinese small-sized breed; it has a relatively long feeding period and low meat production ability but superior meat quality. This study utilized three non-linear growth models (Von Bertalanffy, Gompertz, and logistic) to fit the growth curve of Liangshan pigs from an unselected, random-bred pig population and estimate the pigs most suitable slaughter weight. The growth development data at 20 time points of 275 Liangshan pigs (from birth to 250 d) were collected. To analyze the relative gene expression related to development, seven slaughter weight phases (50, 58, 66, 74, 82, 90, and 98 kg) (20 pigs per phase) were examined. We found that the Liangshan pig growth curve fit the typical S-curve well and that their growth turning point was 193.4 days at a weight of 62.5 kg, according to the best fit Von Bertalanffy model based on the goodness of fit criteria. Furthermore, we estimated that the most suitable slaughter weight was 62.5 to 74.9 kg based on the growth curve and the relative expression levels of growth-related genes.


The Liangshan pig, a traditional small-sized Chinese breed, is mainly distributed in Yi Autonomous Prefecture of Liangshan at an altitude of 1,500 to 2,500 m; it exhibits cold and coarse feeding resistance, and superior meat quality (Jones et al., 1998). Owing to its poor growth performance and carcass composition, it is now in danger of extinction. In recent years, the Liangshan pig has been included in the national preservation program for autochthonous breeds. To utilize this precious genetic resource, it is necessary to study the pig’s basic parameters. So far, there are no such reports on their growth development and characteristics at different slaughter weights.
Swine growth models have the potential to influence alternative management decisions and identify alternative strategies to improve swine production efficiency (Schinckel and De Lange, 1996). The pig’s growth potential must be accurately characterized to effectively apply these models (Craig and Schinckel, 2001). The process of growth measured as body mass or body weight on a longitudinal time frame has often been summarized using mathematical equations fitted to growth curves. Correct specification of the growth model is important for the appropriateness of the subsequent analysis. Thus, a general goodness-of-fit testing method for growth curve models is likely to have immense practical value. One of the objectives of curve fitting is to describe body weight increases over time or with age using biologically interpretable mathematical parameters. Growth curves vary among different species, especially in native breeds where growth is often delayed. In western pigs, the live body weight range most desired by the market is 110 to 120 kg (Boland et al., 1996). Understanding the biology of model parameters and their relationships provides a sound basis for developing a breeding strategy to modify or change the trajectory of growth. Growth trend parameters are highly heritable and are successfully used in selection studies. Studies have pointed out that the purpose of growth curve fitting is to describe the course of mass increase with age by simple equations with a few parameters (Ricklefs, 1985). They are important not only as selection criteria but also in terms of feed management techniques used during the production period to achieve slaughter weight. Other research has determined the optimum slaughter date for pigs kept on different energy diets with the aim of maximum utilization of the meat growth potential, while simultaneously achieving greater economic benefits (Kuhn et al., 1987). Knowing the parameters in some models enables us to predict the future live weights of animals or their tissues and organs, and allows good predictions of the time needed to obtain a predefined live weight.
The asymmetric S-function, a generalized logistic equation with a variable inflection point, has proved appropriate in describing boar growth during the fattening period (Kralik et al., 1993). Growth functions can be grouped into three categories: those that only represent diminishing returns behavior (e.g., monomolecular, exponential with abrupt cut-off), those describing a fixed point of inflection (e.g., Gompertz, logistic), and those encompassing a variable (flexible) point of inflection (e.g., von Bertalanffy, Richards). The flexible functions are generalized models that encompass simpler models for particular values of an additional parameter.
Moreover, many studies have reported the effect of slaughter weight on growth development and carcass quality (Correa et al., 2006), but few reports have compared the relative expression levels of growth-related genes at different slaughter weights. The melanocortin-4 receptor (MC4R) gene has been implicated in regulating feeding behavior and body weight (Marsh et al., 1999). Analyses of growth and performance test records revealed significant associations between MC4R genotypes and backfat thickness, growth rate, and overall feed intake (Kim et al., 2000). Insulin-like growth factor I (IGF1) is the main regulator of postnatal somatic growth, stimulating anabolic processes such as cell division, skeletal growth, and protein synthesis (Curi et al., 2005). Pituitary specific transcription factor-1 (PIT1) regulates growth hormone, prolactin, and thyroid-stimulating hormone 6 in several mammals. Therefore, PIT1 was chosen as a candidate gene to investigate its association with growth and carcass traits in pigs (Yu et al., 1995). Leptin (LEP) has been implicated in the regulation of food intake, energy expenditure, and whole-body energy balance (Houseknecht et al., 1998). Myostatin (MSTN), a member of the transforming growth factor-beta (TGF-β) family of signaling molecules, regulates the growth and force generation of skeletal muscle (Patel and Amthor, 2005). Growth hormone 1 (GH1) is known for its indispensable action in promoting growth and regulating energy metabolism (Goodman, 1993).
The objective of this study was to examine the growth and development of the Liangshan pig by fitting its growth curve with three non-linear models. To estimate the most suitable slaughter weight of the Liangshan pig, we analyzed the differences in the relative expression levels of several growth and carcass-related genes in seven different growth phases.


All animal procedures were conducted in accordance with institutional guidelines for the care and use of laboratory animals was approved by the Animal Care and Ethics Committee of Sichuan Agricultural University, Sichuan, China, under Permit number DKY-S20123030.

Animals and treatment

The experiment was organized by Sichuan Agricultural University and conducted on the Liangshan pig preservation farm in Mabian Gold Liangshan Agricultural Development Co., Ltd. The growth development data at 20 time points of 275 captive Liangshan pigs with similar date and weight at birth were collected from birth to 250 d in an unselected, random mating population. Feed conversion rate (FCR), daily feed intake (DFI), and growth weight were measured to fit the growth curve by three non-liner models. The pigs with the same days were housed in individual pens (2 m2) located in the same room. The DFI is the average weight of the room. Calculation formula: average DFI = daily consumption/the number of pigs. All pigs were fed twice daily with the same diet, and had ad libitum access to feed and water (nipple drinkers). The experimental diets, based on corn and soybean meal, were formulated with crude protein concentrations, trace minerals, and vitamins to meet or exceed the National Research Council (NRC, 1998) recommendations for the different growth phases. During the experimental period, the corn–soybean meal diet was offered to pigs as shown in Table 1. A total of 140 male (barrow) pigs were randomly selected for gene expression samples. We set up seven different growth phases (50 kg, 58 kg, 66 kg, 74 kg, 82 kg, 90 kg, and 98 kg respectively, 20 pigs per phase, all the pigs were randomly selected from the group), all the actual body weight and phases situations were shown in Table 2. When the pigs had reached their target weights, they were transported to a commercial abattoir. After the pigs had rested for approximately 24 h at the abattoir, they were ready for slaughter. On the day of slaughter, the pigs were electrically stunned (90 V, 10 s, 50 Hz), exsanguinated, dehaired, and eviscerated. After slaughter, the right side of the carcass was used for segmentation to measure backfat, dressing percentage, and carcass lean. Every pig was slaughtered and decomposed into lean meat, bone and fat, and then the lean meat percentage was calculated according to the actual weight. The left one was used for sample collection. The samples were obtained from the core of the longissimus dorsi (LD) adjacent to the last rib from the left side carcass immediately after exsanguination, and rapidly frozen in liquid nitrogen for the detection of gene expression.

Growth curve models

There are three nonlinear models involved in our study. The first is the logistic growth curve model, the equation is Wt = A/(1+Bekt). The second is the Gompertz growth curve model, defined by the equation Wt = AeBekt. The third is the Von Bertalanffy growth curve model, which is defined by the equation Wt = A×(1−Bekt)3. When fitting a curve by these models, lnB/k, lnB/k, and lnB/k represent the inflection age; A/2, A/e, and 8A/27 represent the inflection weight; kw/2, kw, and 3 kw/2 represent the maximum daily gain. In the above equations, Wt represents the time point where the weight was recorded, A represents the maximum size, k may be interpreted as the inherent relative growth rate at the start, and B is the growth curve line constant.
Goodness-of-fit (R2) was used to judge the merits of the fitting model, the equation is R2=1-RSERST, where R2 represents the goodness-of-fit, RSE represents the residual sum of squares, and RST represents the sum of squares of deviations.

Real-time polymerase chain reaction analysis

Samples were obtained from the core of the LD adjacent to the last rib from the left side of carcass immediately after exsanguination. The samples for gene expression were promptly frozen in liquid nitrogen and stored at −80°C until subsequent analyses. The relative expression levels of selected genes were quantified using real-time RT- polymerase chain reaction (PCR) analysis. Briefly, total RNA was extracted using TRIZOL reagent (Invitrogen Corp, Carlsbad, CA, USA) according to the manufacturer’s instructions. Reverse transcription was performed using oligo (dT) random 6-mers primers provided in the PrimeScript RT Master Mix kit (TaKaRa, Dalian, China), following the manufacturer’s recommendations. Quantitative PCR was performed using the SYBR Premix Ex Taq kit (TaKaRa, China) on a CFX96 Real-Time PCR detection system (Bio-Rad, Richmond, CA, USA). All measurements contained a negative control (no cDNA template) and each RNA sample was analyzed in triplicate. Relative expression levels of the target mRNAs were calculated using the ΔΔCt method (Livak and Schmittgen, 2001).

Statistical analyses

All experimental data were preliminary processed by Excel 2007. Statistical analyses were performed using the analysis of variance (ANOVA) procedure of SAS System (SAS 9.2; SAS Inst. Inc., Cary, NC, USA). All of the data were analyzed using one-way ANOVA, the factor was slaughter weight. Tukey-Kramer test was applied to post hoc test. Values are expressed as means±standard error of the mean. Differences were considered statistically significant if p<0.05.


Lianshan pig growth curve

The three non-liner models we used to estimate the value of Liangshan pig body weights are shown in Table 3 and Figure 1. A rapid growth period occurred between 150 to 190 d, and the Liangshan pig growth curve and the typical S-curve were a good fit. The relative growth intensity of younger pigs was higher than that of older pigs, and it decreased gradually with age. As shown in the tables, the fitted lines from all models were very close to the observed real values and the models could be ranked according to their R2 values as Von Bertalanffy (0.9971), Gompertz (0.9968), and logistic (0.9947). The inflection point of the growth curve suggested that Liangshan pigs reached their maximum growth rate at day 193.4 and the average body weight at this time was 62.5 kg, after which the growth rate slowed down. The maximum growth rate was 455.43 g/d, much lower than Large White, which is 659.08 g/d (Dube et al., 2014). The above results were consistent with other reports on Chinese native pigs, the inflection point weight of the Tibetan pig is 29.73 kg with 180.0 g in maximal daily gain and in the Chenghua pig is 77.73 kg with 430.0 g in maximal daily gain (Hao et al., 2007). Previous research has shown that ADG decreased with increasing slaughter weight and found a reduction in growth rate the heavier the slaughter weight, which explains the deterioration in feed efficiency (Neely et al., 1979; Kanis et al., 1990; Ellis et al., 1996; Candek-Potokar et al., 1997). In the present study, the Liangshan pig exhibited poor growth performance, thus, their slaughter weight should be much lower than many western commercial pigs (Bazer et al., 1988a,b). According to these results, we can conclude that the suitable slaughter weight of the Liangshan pig >62.5 kg. Since the Liangshan pig belongs to an endangered variety and the population is quite small, the sample used in our study was not big enough, that is, the above results needed more data for validation. If possible, we will expand the numbers in the future.

Liangshan pig growth and carcass traits

Growth rate, FCR, and lean meat percentage of the Liangshan pig are shown in Figure 2. The growth rate increased greatly in the early growth phase and remained steady in the intermediate phases (from the third to fifth phases), then declined slowly. The FCR began to rise slowly from the third phase (67.4 kg weight), that means the feed efficiency began to decline. The lean meat percentage was 43.81±2.09%, higher in the earlier stage and increased rapidly from approximately 67.4 kg (the third phase) and 74.9 kg (the fourth phase), then gradually decreased. These results were consistent with other reports, which found that superior phenotypes occur in the intermediate phase (Latorre et al., 2004; Heyer and Lebret, 2007). The turning point of the Liangshan pig’s growth rate, FCR, and carcass lean percentage occurred in either the third (67.4 kg body weight) or fourth growth phase (74.9 kg body weight). This is similar to previous research in which the growth rate, FCR, and lean meat declined as slaughter weight increased in the later period (Ellis et al., 1996; Latorre et al., 2004). That is, the suitable slaughter weight of the Liangshan pig is 67.4 to 74.9 kg.

Expression patterns of growth and carcass trait related genes

The relative expression level of several genes related to growth and carcass quality are shown in Figure 3. The expression patterns of IGF1, PIT1, and GH1 in the growth and development of the Liangshan pig were quite similar, with higher expression in the intermediate slaughter weight growth phases (67.4±2.11 kg, 74.9±1.25 kg, and 80.4±1.00 kg) than other phases (p<0.05). These results were in agreement with previous studies on growth and carcass traits (Yu et al., 1995; Curi et al., 2005; Dandan et al., 2014). LEP and MSTN gene expression in the intermediate weight phase was significantly lower than in other phases (p<0.05), consistent with the growth development curve. Leptin, encoded by the LEP gene, is a hormone that acts as a signal of satiety affecting feed intake, energetic balance, and body composition (Pérez-Montarelo et al., 2011). Its relative expression level was low in the intermediate phases because of the higher energy needs for high-speed growth. A previous study found that MSTN might be a candidate gene for muscular hypertrophy and may regulate muscle development (Stinckens et al., 2008). We speculate that muscle develops faster in the intermediate weight phase than in other phases, which is consistent with the carcass lean variation in the different growth phases in our study. MC4R expression was higher in all slaughter weight phases, the relative expression in the fourth and fifth phase were significantly lower than in the first, second, and third phases (p<0.05), but there was no significant difference between it and the other phases. Other reports have studied MC4R as a candidate gene for growth control and performance traits in the pig (Kim et al., 2000; Ovilo et al., 2006). For example, MC4R was associated with increased DFI, daily gain, and backfat thickness, and decreased lean meat content (Piórkowska et al., 2010). Therefore, its expression was higher at all slaughter weights but lower in the intermediate weight phases because muscle development was fast at this time. According to the above analysis, we speculate that the suitable slaughter weight of the Liangshan pig occurs in the third (67.4±2.11 kg) to the fourth phases (74.9±1.25 kg).


Our study utilized three non-linear growth models to fit the growth curve of the Liangshan pig from an unselected, random pig population. Von Bertalanffy was the best for achieving a real observation model to fit the Liangshan pig growth curve. According to the Von Bertalanffy model, the Liangshan pig growth turning point was day 193.4, with a weight of 62.5 kg. Backfat, dressing, and lean percentage implied that the third phase was the optimal slaughtering stage. The gene expression results revealed significant associations between the relative MC4R, IGF1, and LEP expression levels and growth and carcass traits. Overall, considering the growth curve and gene expression results, we conclude that the most suitable slaughter weight of the Liangshan pig is 62.5 to 74.9 kg.


This study was supported by the earmarked fund for China Agriculture Research System (No. CARS-36-05B), the Chinese national Sci & Tech Support Program (No. 2013BAD20B07), and the Sichuan Sci & Tech Support Program (No. 2012NZ001, and 2013NZ0041).

Figure 1
The actual growth curve and the fitting growth curve of different models of Liangshan pig.
Figure 2
Growth rate, feed conversion rate (FCR) and carcass lean percentage of Liangshan pig. (A) growth rate (B) FCR and (C) carcass lean percentage. x-coordinate 1 to 7 mean the slaughter weight phases.
Figure 3
The relative expression level of several genes related to growth and development. (A) The melanocortin-4 receptor (MC4R), (B) Insulin-like growth factor I (IGF1), (C) Pituitary specific transcription factor-1 (PIT1), (D) Leptin (LEP), (E) Myostatin (MSTN), (F) Growth hormone 1 (GH1). Gene expression levels represent the relative mRNA expression compared to the controls. Values represent the mean±standard error, all are normalized by the maximum value.
Table 1
Ingredients and nutritional composition of the basal experiment diets
Item 20 to 50 kg 50 to 90 kg
Ingredients (g/kg)
 Corn 700 772
 Soybean 270 200
 CaHPO4 9 8
 Limestone 8 7
 Salt 3 3
 Lysine 0.3 -
 Premix1 10 10
Nutritional composition
 DE (MJ/kg) 13.9 13.83
 CP (g/kg) 180 154
 Ca (g/kg) 6 5.2
 P (g/kg) 5 4.6
 Lysine (g/kg) 9.5 7.5

DE, digestible energy; CP, crude protein.

1 Provided the following (unit/kg): 1,600 mg of Cu; 10,000 mg of Fe; 3,000 mg of Mn; 10,000 mg of Zn; 40 mg of I and 30 mg of Se; 605,000 IU of vitamin A; 155,000 IU of vitamin D3; 1,800 IU of vitamin E; 200 mg of vitamin K3; 300 mg of vitamin B1; 400 mg of riboflavin; 200 mg of vitamin B6; 1.5 mg of vitamin B12; 1,500 mg of pantothenic acid; 2,800 mg of niacin; 12,500 mg of choline.

All data were analyzed values except DE, which was calculated using swine National Research Council (1998) values.

Table 2
Information of Liangshan pigs being slaughtered
Phases Number Growth days Slaughter weight expected (kg) Slaughter weight reality (kg)
1 20 160 50 53.2±1.37
2 20 171 58 59.5±0.86
3 20 195 66 67.4±2.11
4 20 216 74 74.9±1.25
5 20 228 82 80.4±1.00
6 20 240 90 86.7±0.79
7 20 254 98 91.5±1.85
Table 3
The measured and estimated value of the body weight of Liangshan pig produced by different curve models
Day Measured value Von Bertalanffy Logistic Gompertz

Weight (kg) ADG (g) Weight (kg) ADG (g) Weight (kg) ADG (g) Weight (kg) ADG (g)
0 0.77 1.16 4.13 2.17
21 3.33 121.90 3.44 108.65 6.03 90.69 4.26 99.76
28 4.00 95.71 4.51 153.75 6.83 114.39 5.21 135.12
48 7.20 160.00 8.46 197.22 9.69 142.98 8.69 174.21
58 10.91 371.00 10.89 243.53 11.49 180.07 10.89 220.22
88 22.68 392.33 19.84 298.06 18.71 240.64 19.35 282.04
94 24.10 236.67 21.88 340.97 20.52 301.31 21.36 334.57
100 25.40 216.67 24.00 353.25 22.46 322.66 23.46 350.38
120 29.72 216.00 31.53 376.47 29.82 368.36 31.08 380.70
130 31.43 171.00 35.52 398.91 34.00 417.59 35.18 409.87
150 42.13 535.00 43.83 415.58 43.12 456.19 43.78 430.22
160 49.19 706.00 48.11 427.94 47.94 481.63 48.21 443.34
180 56.55 368.00 56.82 435.38 57.67 486.66 57.17 447.78
190 62.28 573.00 61.21 439.28 62.42 474.44 61.63 445.89
200 66.88 460.00 65.61 439.76 66.98 455.67 66.04 440.86
210 70.13 325.00 70.00 438.82 71.28 430.36 70.37 433.38
220 75.09 496.00 74.36 436.59 75.28 400.06 74.61 423.77
230 79.26 417.00 78.70 433.19 78.94 366.45 78.73 412.35
240 81.72 246.00 82.98 428.76 82.26 331.16 82.73 399.45
250 86.80 508.00 87.22 423.40 85.21 295.64 86.58 385.35

ADG, average daily gain (g).


Bazer FW, Thatcher WW, Martinat-Botte F, Terqui M. 1988a. Conceptus development in Large White and prolific Chinese Meishan pigs. J Reprod Fertil 84:37–42.
crossref pmid
Bazer FW, Thatcher WW, Martinat-Botte F, Terqui M. 1988b. Sexual maturation and morphological development of the reproductive tract in Large White and prolific Chinese Meishan pigs. J Reprod Fertil 83:723–728.
crossref pmid
Boland MA, Foster KA, Preckel PV, Schinckel AP. 1996. Analyzing pork carcass evaluation technologies in a swine bioeconomic model. J Prod Agric 9:45–49.
Candek-Potokar M, Zlender B, Bonneau M. 1997. The effects of age and weight at slaughter on the chemical composition of loin muscle in Duroc×(Landrace×Large White) pigs. J Recherche Porcine en France 29:391–396.

Correa JA, Faucitano L, Laforest JP, Rivest J, Marcoux M, Gariépy C. 2006. Effects of slaughter weight on carcass composition and meat quality in pigs of two different growth rates. Meat Sci 72:91–99.
crossref pmid
Craig BA, Schinckel A. 2001. Nonlinear mixed effects model for swine growth. Prof Anim Sci 17:256–260.
Curi RA, De Oliveira HN, Silveira AC, Lopes CR. 2005. Association between IGF-I, IGF-IR and GHRH gene polymorphisms and growth and carcass traits in beef cattle. Livest Prod Sci 94:159–167.
Dandan Z, Lui X, Max R, Zhang Z, Zhao S, Fan B. 2014. Genome-wide association study of the backfat thickness trait in two pig populations. Front Agric Sci Eng 1:91–95.
Dube B, Mulugeta SD, Dzama K. 2014. Genetic relationship between growth and carcass traits in Large White pigs. South Afr J Anim Sci 43:482–492.
Ellis M, Webb AJ, Avery PJ, Brown I. 1996. The influence of terminal sire genotype, sex, slaughter weight, feeding regime and slaughter-house on growth performance and carcass and meat quality in pigs and on the organoleptic properties of fresh pork. Anim Sci 62:521–530.
Goodman HM. 1993. Growth hormone and metabolism The Endocrinology of Growth, Development, and Metabolism in Vertebrates. Schreibman MP, Scanes CG, Pang TP, editorsAcademic Press; Diego, CA, USA: p. 93–115.

Hao Z, Yang-zom Q, Qiang W, Zhang L, Dui Z. 2007. Analysis of weight growth curves in Tibetan pig. Ecol Domest Anim 6:41–43.

Heyer A, Lebret B. 2007. Compensatory growth response in pigs: Effects on growth performance, composition of weight gain at carcass and muscle levels, and meat quality. J Anim Sci 85:769–778.
crossref pmid
Houseknecht KL, Baile CA, Matteri RL, Spurlock ME. 1998. The biology of leptin: A review. J Anim Sci 76:1405–1420.
crossref pmid
Jones G, Rothschild M, Ruvinsky A. 1998. Genetic aspects of domestication, common breeds and their origin. The Genetics of the Pig. Rothschild MF, Ruvinsky A, editorsCAB International; Wallingford, UK: p. 17–50.

Kanis E, Nieuwhof GJ, De Greef KH, Van der Hel W, Verstegen MW, Huisman J, Van der Wal P. 1990. Effect of recombinant porcine somatotropin on growth and carcass quality in growing pigs: interactions with genotype, gender and slaughter weight. J Anim Sci 68:1193–1200.
crossref pmid
Kim KS, Larsen N, Short T, Plastow G, Rothschild MF. 2000. A missense variant of the porcine melanocortin-4 receptor (MC4R) gene is associated with fatness, growth, and feed intake traits. Mamm Genome 11:131–135.
crossref pmid
Kralik G, Scitovski R, Sencic D. 1993. Application of asymmetric S-function for analysis of the growth of boars. Stocarstvo 47:425–433.

Kuhn G, Ender K, Otto E, Feige K, Hackl W. 1987. Predict the most suitable slaughter time based on the growth and fattening performance of Börgen pigs. Arch Tierz, Berlin 30:261–269.

Latorre M, Lázaro R, Valencia D, Medel P, Mateos G. 2004. The effects of gender and slaughter weight on the growth performance, carcass traits, and meat quality characteristics of heavy pigs. J Anim Sci 82:526–533.
crossref pmid
Marsh DJ, Hollopeter G, Huszar D, Laufer R, Yagaloff KA, Fisher SL, Burn P, Palmiter RD. 1999. Response of melanocortin–4 receptor–deficient mice to anorectic and orexigenic peptides. Nat Genet 21:119–122.
crossref pmid
Neely J, Johnson R, Walters L. 1979. Efficiency of gains and carcass characteristics of swine of two degrees of fatness slaughtered at three weights. J Anim Sci 48:1049–1056.
Ovilo C, Fernández A, Rodríguez MC, Nieto M, Silió L. 2006. Association of MC4R gene variants with growth, fatness, carcass composition and meat and fat quality traits in heavy pigs. Meat Sci 73:42–47.
crossref pmid
Patel K, Amthor H. 2005. The function of Myostatin and strategies of Myostatin blockade—new hope for therapies aimed at promoting growth of skeletal muscle. Neuromuscul Dis 15:117–126.
Piórkowska K, Tyra M, Rogoz M, Ropka-Molik K, Oczkowicz M, Różycki M. 2010. Association of the melanocortin-4 receptor (MC4R) with feed intake, growth, fatness and carcass composition in pigs raised in Poland. Meat Sci 85:297–301.
crossref pmid
Ricklefs RE. 1985. Modification of growth and development of muscles of poultry. Poult Sci 64:1563–1576.
crossref pmid
Schinckel AP, De Lange CF. 1996. Characterization of growth parameters needed as inputs for pig growth models. J Anim Sci 74:2021–2036.
crossref pmid
Stinckens A, Luyten T, Bijttebier J, Van den Maagdenberg K, Dieltiens D, Janssens S, De Smet S, Georges M, Buys N. 2008. Characterization of the complete porcine MSTN gene and expression levels in pig breeds differing in muscularity. Anim Genet 39:586–596.
crossref pmid
Yu TP, Tuggle CK, Schmitz CB, Rothschild MF. 1995. Association of PIT1 polymorphisms with growth and carcass traits in pigs. J Anim Sci 73:1282–1288.
crossref pmid

Editorial Office
Asian-Australasian Association of Animal Production Societies(AAAP)
Room 708 Sammo Sporex, 23, Sillim-ro 59-gil, Gwanak-gu, Seoul 08776, Korea   
TEL : +82-2-888-6558    FAX : +82-2-888-6559   
E-mail : editor@animbiosci.org               

Copyright © 2024 by Asian-Australasian Association of Animal Production Societies.

Developed in M2PI

Close layer
prev next