Study on the Prolactin Receptor 3 (PRLR3) Gene and the Retinol-binding Protein 4 (RBP4) Gene as Candidate Genes for Production Traits in Berkshire Pigs

Article information

Asian-Australas J Anim Sci. 2012;25(2):183-188

Publication date (electronic) : 2012 February 01

doi : https://doi.org/10.5713/ajas.2011.11216

¹College of Natural Resource and Life Sciences, Pusan National University, Miryang, Korea.

^*Corresponding Author : Dong-Hee Lee. Department of Life Sciences, University of Seoul, 13 Siripdae-kil, Dongdaemun-Gu 130-743, Korea. Tel: +82-2-2210-2170, Fax: +82-2-2210-2888, E-mail: leedh@uos.ac.kr

Department of Biosystem Sciences, Chungnam National University, Yuseong, Daejeon 305-764, Korea

Received 2011 July 08; Accepted 2011 October 04.

Abstract

To investigate the influence of the prolactin receptor 3 (PRLR3) gene and the retinol-binding protein 4 (RBP4) gene on the production traits of swine, genotyping was performed on 156 and 141 Berkshire pigs, respectively, that were carefully selected for economic traits. The frequencies of allele A in the PRLR3 locus and allele B in the RBP4 locus were 0.50 and 0.42, respectively. Neither locus was in the Hardy-Weinberg equilibrium. After a genotype was assigned to the individuals whose parents had the homozygous genotype, a statistical analysis was conducted for 291 pigs. The animals with the PRLR3 and RBP4 genotypes included 182 and 227 head, respectively. Even though the genotypic effects of PRLR3 (p<0.05) and RBP4 (p<0.01) had a significant influence on the pigs’ back fat thickness, the interaction of both genes was not highly significant in terms of the back fat thickness (p = 0.1235). While the estimated epistasis effects of aaBB and aaBb decreased the back fat thickness and reduced the growth rate, the effects of AAbb and aabb increased the growth rate. Despite the insignificant difference in the PRLR genotypes in terms of the days to 90 kg and the average daily gain, the back fat thickness showed a significant difference (p<0.05), and the additive effect of allele A and the dominant effect of the hetero-genotype were −0.377 and 1.206 mm, respectively. The RBP4 genotypes had a very significant effect (p<0.01) on the back fat thickness, the days to 90 kg, and the average daily gain. The additive effects of allele B of the RBP4 locus on the back fat thickness, the days to 90 kg, and the average daily gain were 0.70 mm, −1.3 days and 6.2 g, respectively. Moreover, the dominant effects of the heterozygote for those traits were 0.63 mm, 9.9 days and −45.0 g, respectively. Allele A of the PRLR3 locus favorably influenced the back fat thickness, the days to 90 kg of the body weight, and the average daily gain and its dominant effect unfavorably influenced those traits. Allele B of RBP4 showed an incremental growth rate and back fat thickness, which could lower the lean meat percentage in the carcass. The RBP4 hetero-genotype negatively affected the pork production. These results strongly imply that the selection of allele A of PRLR3 and allele B of RBP4 would produce highly productive pigs in the Berkshire breed. Careful selection of allele B of RBP4 is required because of the increase in the back fat thickness.

Keywords: Prolactin Receptor; Retinol-binding Protein; Candidate Gene; Additive Effect; Production Traits

INTRODUCTION

The pig population in Korea is mainly composed of highly productive breeds such as the Landrace, Yorkshire and Duroc breeds and their crossbreeds. Berkshire pigs are raised for quality pork, and are publicly known for the quality of their carcass. Niche markets have been reported (Honeyman et al., 2006) for Berkshire pork, including from internet sales, local abattoir sales, direct marketing, farmer networks and targeting of organized groups in the U.S. Even in Korea, the meat of Berkshire pigs is sold as high-quality pork in supermarkets, with a premium price. A study found Berkshire-sired pigs superior in terms of most of their eating quality traits, such as their cooking loss and tenderness (Mabry and Baas, 1998). The productivity of the Berkshire breed is not efficient, unlike other major breeds. Small litter sizes were also observed in Berkshire breeds (Do, 2007b). Mabry and Baas (1998) reported that Berkshire-sired pigs had the most fat and the small loin muscle areas. It was because of this that increasing productivity came to the attention of Berkshire farmers.

Marker-assisted selection (MAS) by genetic markers is a tool to improve swine productivity. Genes such as melanocortin 4 receptor (MC4R) (Kim et al., 2000) for growth, ryanodine receptor (RYR1) (Fujii, 1991), and heart fatty acid binding protein (HFABP) (Gerbens et al., 1999) for meat quality have been identified in pigs as associated with economic traits.

Prolactin receptor (PRLR), which mediates the signal transduction pathway in target endocrine tissues (Bole-Feysot et al., 1998; Goffin et al., 2002), has been shown to play certain roles in inducing milk-protein gene expression in the mammary gland (Rui et al., 1992). Retinol-binding proteins (RBPs), which are the specific carriers of retinol (vitamin A alcohol) in the blood, deliver retinol from the liver to the peripheral tissues. In pigs, alleles for the PRLR and RBP4 genes have been associated with significant differences in litter size (Vincent et al., 1998; Rothschild et al., 2000; Drogemuller et al., 2001) and in fetus and early growth (Do et al., 2010).

Production traits, such as back fat thickness, days to 90 kg, and average daily gain, are also vital elements of the revenue of pig farmers. To properly practice MAS using the candidate genes without economic loss, the association of the genes with meat production traits should be considered. In this study, the influence and characteristics of PRLR3 and RBP4 genes on the back fat thickness, days to 90 kg, and average daily gain of Berkshire pigs were examined.

MATERIALS AND METHODS

Animals and DNA isolation

The Berkshire pigs were subjected to intense selection of their production and reproduction traits over six generations. During this period, approximately 20 boars and 100 sows were continuously raised in the herd. Computer breeding software was used to minimize inbreeding and to augment genetic enhancement of economic traits. Accordingly, the final inbreeding coefficient was estimated to have been approximately 1.6%. Genotyping was performed on 339 and 474 animals to characterize PRLR3 and RBP4, respectively, as shown in Table 1. The classification and least square means of the pigs with growth records were also determined and are summarized in Table 2 and 3. Some of the male piglets were castrated on day 2 or 3. There were 291 genotyped animals with records of back fat thickness, days to 90 kg, and average daily gain, which were measured at 156.8 days (standard deviation: 11.7 days) of age and adjusted using the growth curves for the Berkshire breed (Do, 2007a). The genomic DNA was isolated from the blood samples of the pigs using the Toyobo MagExtraction Kit.

Table 1

Classification of animals by PRLR3 and RBP4 genotype

Table 2

Distribution of production traits by genotype, birth year and gender

Table 3

Least square means of back fat thickness, days to 90 kg and average daily gain

Primer design and polymerase chain reaction

The PRLR3 and RBP4 genes of the Berkshire pigs were amplified and obtained using the following primer pairs:

PRLR3: Forward 5′-CGT GGC TCC GTT TGA AGA ACC-3′
Reverse 5′-CTG AAA GGA GTG CAT AAA GCC-3′
RBP4: Forward 5′-GAG CAA GAT GGA ATG GGT T-3′
Reverse 5′-CTC GGT GTC TGT AAA GGT G-3′

PCR was performed in a 10 μl reaction mixture that contained 12 ng of genomic DNA, 10 pmol of the primer, 200 μM of dNTP, 2.5 units of Taq DNA polymerase (Enzynomics™, Korea), and the reaction buffer with 1.5 mM of MgCl₂. The reaction was carried out using a PTC-200 thermocycler (MJ Research, Watertown, MA, USA) with 5-min primary denaturation at 94°C, 45 s at the annealing temperature, 60 s at 72°C and a final 10-min extension at 72°C.

Polymorphism identification and genotyping

The polymorphic sites were tested for restriction fragment length polymorphisms (RFLPs) according to the NEBcutter program after each DNA sample from the Berkshire breed was genotyped. All the restriction enzymes were purchased from New England BioLabs (NEB) (Ipswich, MA, USA), and the restriction digestions were performed according to Rothschild et al. (2000).

The PCR product was incubated with 8U Alu I (NEB) and electrophoresed on a 3% Metaphor (FMC) agarose gel to generate several fragments. The combination of 85-bp, 59-bp and 19-bp represented the AA genotype, and the 104-bp and 59-bp fragments represented the BB genotype. The digestion of the remaining PCR product was performed with 4 U of MspI, and the fragments were resolved on 3% FMC gel such that the 190-bp, 154-bp and 136-bp fragments were used to observe AA, and the 154-bp, 136-bp and 125-bp fragments were used to observe BB.

Statistical analysis

The GLM procedure of SAS (2001) was used to assess the effects of the genotype. The data were analyzed by birth year, sex and dam’s parity, along with the genotype of the candidate genes. The epistasis effects were calculated from the deviation of the least square means of PRLR3*RBP4, PRLR3 and RBP4 from the population mean of the model. The epistasis effect of AA/BB was the difference of AA/BB from the sum of AA and BB (Karain et al., 1979). To assess the additive effects, the least square means of the two homozygous genotypes were compared. The dominance effects were calculated on the basis of the deviation of the heterozygote effect from the mean of the two homozygous genotypes.

RESULTS AND DISCUSSION

Polymorphisms were observed in the PRLR3 and RBP4 loci of the Berkshire pigs. The Hardy-Weinberg equilibrium was checked with the number of animals that were genotyped, and the expected numbers are shown in Table 1. The frequencies of allele A in the PRLR3 locus and allele B in the RBP4 locus were 0.50 and 0.42, respectively. Neither locus showed the typical Hardy-Weinberg equilibrium. The frequencies of the hetero-genotypes were higher in the PRLR3 gene and lower in the RBP4 gene than the expected frequency that was obtained based on the Hardy-Weinberg principle. The genotype was assigned to offspring whose parents were homozygote, without further genotyping in a laboratory. The counts of the animals that were genotyped by pedigree information were 195 and 318 for PRLR3 and RBP4, respectively. The number of genotyped animals with production records for each gene differed due to the difference in the number of animals genotyped, as shown in Table 2.

Pigs with generally less back fat, fewer days to gain 90 kg of body weight, and higher daily growth gains are required to increase a farmers revenue. The traits of days to 90 kg and average daily gain are closely related, as they indicate how fast a pig grows. The data on these two traits were negatively correlated, though. The basic statistics for those production traits are shown in Table 3. The pigs that were castrated at birth showed higher back fat thickness and average daily gain than the other pigs, but lower days to 90 kg. The number of animals in Table 2 decreased rapidly in closer parity with the dam, because the sows’ reproductive traits were selected. The birth year, gender and dam parity were included in the models to eliminate their effects when the genotypic effects were estimated. These were considered environmental influences on the phenotype of the traits and hence, not relevant to transmittable genetic ability.

Statistical epistasis is a population property, and is a function of both the allele frequencies and the biological interactions among genes (Carter et al., 2005). The analysis of gene interaction characterizes whether or not multiple genes influence a particular genetic trait. It is not certain if two or more genes can interact to express a particular phenotype. Multiple gene products can also contribute to the expression of a single phenotype along the biochemical pathways in cells (Klug et al., 2007). Even though the genotypic effects of PRLR3 (p<0.05) and RBP4 (p<0.01) were significant in terms of the back fat thickness, the interaction of both genes was not significant in terms of the back fat thickness (p = 0.1235). The estimated epistatic effects of aaBB and aaBb were negative, at −1.516 and −1.514 mm, respectively. This extent of thickness reduction due to epistasis could lure animal breeders to further investigate large animal populations for MAS applications. The interactions of the genes were very significant (p<0.01) in the traits of days to 90 kg and average daily gain. This may strongly imply the presence of epistasis between the RBP4 and PRLR3 genes. The genotypes of aaBB and aaBb with a reduction in the back fat thickness also showed a decrease in the growth rate traits of days to 90 kg and average daily gain. The epistatic effects of the AAbb and aabb genotypes increased the rate of growth by −8.2 and −5.8 days for 90 kg of body weight and by 42.0 and 27.8 g for daily gain, respectively.

Despite the insignificant difference between the PRLR genotypes in terms of days to 90 kg and average daily gain (Tables 5 and 6), the back fat thickness showed a significant difference (p<0.05), as seen in Table 4. The additive effect of allele A was −0.377 mm in terms of back fat thickness, as shown in Table 8. This may strongly imply that the PRLR gene negatively affects the synthesis or deposition of subcutaneous fat. The positive medium genetic correlation (0.24) (Do, 2007b) of the back fat thickness with the litter size in Berkshire pigs and the significant allelic substitution effect (0.71 piglets in litter size with allele a) (Drogemuller et al., 2001) of PRLR3 indicates an apparent relationship between the PRLR3 gene and the back fat thickness. Though no significant days to 90 kg and average daily gain according to the genotypes of PRLR3 were shown, the estimated additive effects were −4.54 days and 18.5 g, respectively. This appears to support the results of Freemark et al. (2001) that the absence of PRLRs in mice was accompanied by reduced body weight. The dominant effect of the PRLR3 genotype was demonstrated by 1.206 mm of back fat thickness, as shown in Table 8.

Table 5

Analysis of variance for days to 90 kg

Table 6

Analysis of variance for average daily gain

Table 4

Analysis of variance for back fat thickness

Table 8

Additive and dominant (d) genetic effects of PRLR3 and RBP4 genes in production traits1

RBPs have been known to play important roles in maintaining visual function and have additional importance related to Vitamin A concerning growth in mammals. West et al. (1997) reported the relationship of Vitamin A to child growth. The genotypes of RBP4 showed a very significant effect (p<0.01) on the back fat thickness, days to 90 kg, and average daily gain, as shown in Table 4, 5 and 6. The least square means of genotypes BB, Bb and bb in the RBP4 gene were 17.83, 17.76 and 16.42 mm for the back fat thickness, 145.1, 156.3 and 147.6 days for the days to 90 kg and 628.1, 576.9 and 615.7 g for the average daily gain, respectively. Accordingly, the additive effects of B allele for these traits were 0.70 mm, −1.3 days and 6.2 g, respectively. Unlike the reduction of the back fat thickness by allele A of the PRLR3 locus, allele B of the RBP4 locus showed a consistent increase in the growth rate and the back fat thickness. Despite the unfavorable impact of allele B of the RBP4 gene on the back fat thickness, it could reduce the number of days to reach 90 kg by 1.26 days or increase the growth rate by 6.2 g per day. This was inconsistent with the lower feeder weight (age: 74 days) of the Berkshire pigs (data not shown), and the RBP4 gene possibly produced different growth curves according to the genotype. The dominant effects of the heterozygote for those traits were 0.63 mm, 9.9 days and −45.0 g, respectively.

In summary, this genetic study investigated the significance of the prolactin receptor 3 (PRLR3) and the retinol-binding protein 4 (RBP4) genes in the meat production traits of Berkshire pigs. Allele A of the PRLR3 locus favorably influenced the back fat thickness, days to a 90 kg body weight and average daily gain, and its dominant effect unfavorably influenced these traits. Allele B of RBP4 showed an increased growth rate and a higher back fat thickness, which could lower the lean meat percentage of the carcass. The hetero-genotype of RBP4 negatively affected the pork production. These results strongly imply that the selection of allele A of PRLR3 and allele B of RBP4 would result in more productive Berkshire pigs.

Table 7

Epistatic effects of PRLR3/RBP4 genes1

ACKNOWLEDGEMENT

This study was supported by the 2008 Korea Research Council Project.

References

Bole-Feysot C, Goffin V, Edery M, Binart N, Kelly PA. 1998;Prolactin (PRL) and its receptor: actions, signal transduction pathways and phenotypes observed in PRL receptor knockout mice. Endocr Rev 19:225–268.

Carter AJR, Hermisson J, Hansen TF. 2005;The role of epistatic gene interactions in the response to selection and the evolution of evolvability. Theor Popul Biol 68:179–196.

Do CH. 2007a;Estimation of growth traits using growth curve in Gyungnam-heugdon (Berkshire). J. Anim. Sci. Technol. (Kor.) 49(2):195–202.

Do CH. 2007b;Relation of production traits and reproduction traits in swine. J. Anim. Sci. Technol. (Kor.) 49:303–308.

Drogemuller C, Hamann H, Distl O. 2001;Candidate gene markers for litter size in different German pig lines. J Anim Sci 79:2565–2570.

Freemark M, Fleenor D, Driscoll P, Binart N, Kelly PA. 2001;Body weight and fat deposition in prolactin receptor-deficient mice. Endocrinology 142:532–537.

Fujii J, Otsu K, Zorzato F, de Leon S, Khanna VK, Weiler JE, O’Brien PJ, MacLennan DH. 1991;Identification of a mutation in porcine ryanodine receptor associated with malignant hyperthermia. Science 253(5018):448–451.

Gerbens F, van Erp AJ, Harders FL, Verburg FJ, Meuwissen TH, Veerkamp JH, te Pas MF. 1999;Effect of genetic variants of the heart fatty acid-binding protein gene on intramuscular fat and performance traits in pigs. J Anim Sci 77:846–852.

Goffin V, Binart N, Touraine P, Kelly PA. 2002;Prolactin: the new biology of an old hormone. Annu Rev Physiol 64:47–67.

Honeyman MS, Pirog RS, Huber GH, Lammers PJ, Hermann JR. 2006;The United States pork niche market phenomenon. J Anim Sci 84:2269–2275.

Karain F, Bhatia VK, Malhotra PK. 1979. Hand book of statistical genetics Indian Agricultural Statistical Research Institute.

Kim KS, Larsen N, Short T, Plastow G, Rothschild MF. 2000;A missense variant of the porcine malanocortin-4 receptor (MC4R) gene is associated with fatness, growth and feed intake traits. Mamm Gennome 11:131–135.

Klug WS, Cummings MR, Spencer CA. 2007. Essential of genetics Pearson: Prentice Hall.

Mabry JW, Baas TJ. 1998. Facts: The impact of genetics on pork quality (Revised) National Pork Producers Council publication. Des Moines, IA:

Rui H, Djeu JY, Evans GA, Kelly PA, Farrar WL. 1992;Prolactin receptor triggering. J Biol Chem 267:24076–24081.

Rothschild MF, Messer L, Day A, Wales R, Short T, Southwood O, Plastow G. 2000;Investigation of the retinol-binding protein 4 (RBP4) gene as a candidate gene for increased litter size in pigs. Mamm Genome 11:75–77.

SAS. 2001. SAS/STAT SAS Institute. Cary, NC, USA:

Vincent AL, Evans G, Short TH, Southwood OI, Plastow GS, Tuggle CK, Rothschild MF. 1998. The prolactin receptor gene is associated with increased litter size in pigs. In : Proc. 6th World Congr. Genet. Appl. Livest. Prod. Armidale, NSW, Australia. 27p. 15–18.

West KP Jr, LeClerq SC, Shrestha SR, Wu LS-F, Pradhan EK, Khatry SK, Katz J, Adhikari R, Sommer A. 1997;Effects of vitamin A on growth of vitamin A-deficient children: Field studies in Nepal. J Nutr 127:1957–196511.

Article information Continued

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License http://creativecommons.org/licenses/by-nc/3.0/ which permits unrestricted noncommercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Table 1

Classification of animals by PRLR3 and RBP4 genotype

	PRLR3				RBP4

	AA	Aa	aa	Total	BB	Bb	bb	Total
Genotyped	22 (36)	101 (72)	21 (36)	144	34 (24)	54 (74)	68 (58)	156
Assigned1	0	160	35	195	62	118	138	318
Total	22	261	56	339	96	172	206	474
Unknown2	3	77	39	119	57	76	121	254

The figures in the parenthesis represent the expected numbers of animals under the Hardy-Weinberg Equilibrium.

Represents the animals genotyped by parent information.

Represents the numbers of animals which do not have information of genotype in other gene.

Birth year	Gender	Parity	PRLR3	RBP4
2003	35	Female	203	1	93	AA	14	BB	41
2004	62	Male	72	2	62	Aa	131	Bb	75
2005	124	Castrated	16	3	32	Aa	37	Bb	111
2006	70			4	25
				5	25
				6	25
				7	16
				≥8	13
Total	291		291		291		182		227

Table 3

Least square means of back fat thickness, days to 90 kg and average daily gain

	Gender			Parity

	Back fat thickness (mm)	Days to 90 kg	Average daily gain (g)		Back fat thickness (mm)	Days to 90 kg	Average daily gain (g)
Female	17.034±0.282	156.75±1.63	575.4±6.6	1	14.809±0.432	147.84±2.46	619.1±10.3
Male	16.577±0.388	150.00±2.25	611.4±9.1	2	17.445±0.479	149.60±2.73	608.0±11.4
Castrated	18.070±0.755	148.65±4.38	614.3±17.7	3	17.012±0.693	149.51±3.95	608.9±16.5
				4	16.949±0.964	175.87±5.49	510.6±22.9
				5	16.613±1.009	148.61±5.75	608.9±24.0
				6	14.887±1.453	155.75±8.28	577.5±34.6
				7	16.242±1.301	178.48±7.41	503.5±30.9
				≥8	22.477±1.997	149.50±11.38	601.0±47.5

Table 4

Analysis of variance for back fat thickness

Source	df	MS	F	df	MS	F	df	MS	F

Year	3	228.93	48.23a	3	192.75	28.20a	3	141.74	25.84a
Gender	2	40.50	8.53a	2	41.44	6.06a	2	34.19	6.23a
Parity	7	34.14	7.19a	8	16.67	2.44b	6	12.52	2.28b
PRLR3	2	20.03	4.22b
RBP4				2	35.71	5.23a
PRLR3RBP4*							8	8.99	1.64d
Error	167	4.75		211	6.83		98	5.48

p<0.01;

p<0.05;

p<0.25.

Table 5

Analysis of variance for days to 90 kg

Source	df	MS	F value	df	MS	F	df	MS	F

Year	3	5241.1	25.94a	3	2,641.6	13.09a	3	1689.0	8.85a
Gender	2	753.3	3.73b	2	606.0	3.00c	2	380.5	1.99d
Parity	7	1,060.0	5.25a	8	293.4	1.45d	6	459.1	2.41b
PRLR3	2	118.5	0.59
RBP4				2	1,622.2	8.04a
PRLR3RBP4*							8	539.8	2.83a
Error	167	202.1		211	201.8		98	190.8

p<0.01;

p<0.05;

p<0.10;

p<0.25.

Table 6

Analysis of variance for average daily gain

Source	df	MS	F	df	MS	F	df	MS	F

Year	3	104,461.0	30.71a	3	49,335.9	14.86a	3	33,061.7	10.57a
Gender	2	22,264.4	6.55a	2	15,881.9	4.79a	2	10,159.6	3.25b
Parity	7	13,782.0	4.05a	8	5,880.7	1.77c	6	6,707.7	2.14c
PRLR3	2	2,066.7	0.61
RBP4				2	33,314.9	10.04a
PRLR3RBP4*							8	11,157.2	3.57a
Error	167	3,401.3		211	3,319.0		98	3,128.3

p<0.01;

p<0.05;

p<0.10.

Table 7

Epistatic effects of PRLR3/RBP4 genes1

Traits	PRLR3	RBP4

		BB	Bb	bb
Back fat thickness (mm)	AA	−0.490	1.523	−0.530
	Aa	0.605	0.235	0.189
	aa	−1.516	−1.540	1.525
Days to 90 kg	AA	5.267	1.259	−8.167
	Aa	−4.146	−2.170	1.454
	aa	9.328	2.928	−5.754
Average daily gain (g)	AA	−24.399	−8.271	41.981
	Aa	19.258	10.360	−7.537
	aa	−44.412	−14.800	27.820

All estimates of least square means for obtaining epistatic effects were highly significant (p<0.0001).

Table 8

Additive and dominant (d) genetic effects of PRLR3 and RBP4 genes in production traits1

		Back fat thickness (mm)	Days to 90 kg	Average daily gain (g)
PRLR3	AA	15.221±0.729	150.36±4.75	609.4±19.5
	Aa	16.803±0.398	154.66±2.59	591.3±10.7
	aa	15.974±0.546	154.90±3.56	590.9±14.6
	AA-aa	−0.753	−4.54	18.5
	d	1.206	2.03	−8.9
RBP4	BB	17.832±0.580	145.12±3.15	628.1±12.8
	Bb	17.763±0.523	156.30±2.84	576.9±11.5
	bb	16.423±0.534	147.63±2.90	615.7±11.8
	BB-bb	1.409	−2.51	12.4
	d	0.634	9.93	−45.0

All estimates of least square means were highly significant (p<0.0001).