Replicated association of the single nucleotide polymorphism in PNLIP with marbling in Niigata population of Japanese Black beef cattle ()
1. INTRODUCTION
Intramuscular fat deposition (marbling) measured as a beef marbling score (BMS) is one of the economically important traits of beef cattle [1]. A high level of the BMS enriches the taste and tenderness of beef, improving the palatability [2-4], therefore, the BMS affects the evaluation of beef quality [1]. The BMS is regarded as the most important trait especially in Japan. Thus, it would be desirable to construct a more effective markerassisted breeding scheme for increasing the BMS level in Japanese Black beef cattle.
We recently showed that a single nucleotide polymerphism (SNP), namely, rs41648172, in the pancreatic lipase (PNLIP) gene was associated with the BMS level in a Japanese Black beef cattle population in Oita prefecture, with the T allele of the SNP being associated with a highest level of the BMS [5].
Thus, it was necessary to investigate whether this association could be replicated in other independent populations of Japanese Black beef cattle and to analyze the effects of the SNP genotypes on the carcass traits other than the BMS, in order to confirm the application of the rs41648172 SNP to effective marker-assisted selection.
2. MATERIALS AND METHODS
2.1. Samples and Data
We used independent Japanese Black cattle population of Niigata prefecture, and studied the association of the rs41648172 SNP with the BMS, subcutaneous fat thickness (SFT), carcass weight (CWT), rib eye area (REA), rib thickness (RT), and yield estimate (YE). In this study, 134 paternal half-sib progeny steers (1 to 16 steers per sire) produced from 39 sires were used. Hair root specimens of the progeny steers were collected for genotyping the SNP. DNA samples were prepared from the materials using DNeasy Blood & Tissue Kit (QIAGEN, Hilden, Germany).
The BMS, SFT, CWT, REA, RT and YE were measured according to the Japanese meat grading system by certified graders from the Japan Meat Grading Association (Tokyo, Japan) [1]. The predicted breeding values of the BMS, SFT, CWT, REA, RT and YE for the progeny steers were used as the phenotypic values in this study. The breeding values were predicted using carcass records of Japanese Black steers and heifers fattened in the Niigata prefecture, and obtained from the Niigata Prefectural Headquarters, National Federation of Agricultural Cooperative Association (Niigata, Japan).
This study conformed to the guidelines for animal experimentation of the Graduate School of Science and Technology, Niigata University (Niigata, Japan).
2.2. SNP Genotyping
The rs41648172 SNP was genotyped by the PCR-restriction fragment length polymorphism method as described previously [6]. Using this method, 546-bp PCR fragments containing the SNP site were amplified and HpyCH4IV-digested into 131- and 415-bp fragments at the C allele, but not the T allele: the TT homozygotes, the CC homozygotes and the CT heterozygotes yielded 1 band (546-bp), 2 bands (131- and 415-bp) and 3 bands (131-, 415-, and 546-bp), respectively. PCR amplifications were performed using 25 ng of the prepared DNA as template in a final volume of 25 ml containing 0.5 mM of each primer, 0.2 mM of each dNTP, 0.625 U of Ex Taq polymerase (Takara, Shiga, Japan), and 1 × Ex Taq buffer (Takara). The PCR conditions were as follows: 94˚C for 3 min, 35 cycles of 94˚C for 50 s, 66˚C for 50 s, and 72˚C for 50 s, followed by a further 5-min extension at 72˚C. An aliquot of PCR-amplified product was digested at 37˚C for 1 h with restriction enzyme HpyCH4IV and electrophoresed on a 3.0% agarosegel. Agarose gels were stained with ethidium bromide and photographed under an ultraviolet light.
2.3. Statistical Analyses
Departures from the Hardy-Weinberg equilibrium were tested for the SNP by chi-square test. Statistical comparisons between the allele frequencies at the SNP in the progeny steers or estimated by maternal alleles in half-sib progeny steers in the Niigata prefecture population and the previous date obtained in Japanese Black cattle population of the Oita prefecture, Japanese Brown, Japanese Short Horn, Holstein, or Brown Swiss cattle populations [7] were also performed by chi-square test. The effect of genotypes at the SNP on the predicted breeding values for the BMS, SFT, CWT, REA, RT and YE was analyzed with the model that included the SNP genotype as the fixed effect and the sire as the random effect. Statistical analysis was performed by the MIXED procedures of the SAS program (SAS Institute, Inc., Cary, NC).
3. RESULTS AND DISCUSSION
Genotyping the 134 progeny steers for the rs41648172 SNP revealed 46 animals homozygous for the C allele, 56 animals heterozygous for the C allele and the T allele and 32 animals homozygous for the T allele for the rs41648172 (Table 1). The observed frequencies of the SNP genotypes in the Niigata population are shown in Table 1. The observed and expected heterozygosity values at the SNP conformed to the Hardy-Weinberg equilibrium in the Niigata population. The frequency of the T allele of rs41648172 SNP in the Niigata prefecture population was higher than the frequencies of this allele of Japanese Brown, Japanese Short Horn, Holstein, or Brown Swiss cattle populations that have not been strongly selected for high marbling [7], but lower than the frequency of this allele in Japanese Black cattle population of the Oita prefecture determined in our previous study [7] (data not shown). However, no statistic cally significant difference was detected between the allele frequencies estimated by maternal alleles in half-sib progeny steers in the Niigata population and obtained in Japanese Black cattle population of the Oita prefecture [7], and those frequencies were higher thanthose of Japanese Brown, Japanese Short Horn, HolsteinTable 1. Frequencies of the rs41648172 SNP genotypes in Japanese Black cattle population of the Niigata prefecture.
Table 2. Effects of the rs41648172 SNP genotypes on BMS, SFT, CWT, REA, RT and YE in Japanese Black cattle population of the Niigata prefecture.
1BMS, beef marbling score (unit); SFT, subcutaneous fat thickness (cm); CWT, carcass weight (kg); REA, rib eye area (cm2); RT, rib thickness (cm); YE, yield estimate (%). 2the breeding values are given as least squares means ± SE. mean values at different genotypes without a common superscript letter significantly differ (P < 0.10).
or Brown Swiss cattle populations [7] (data not shown).
Marginally significant differences in the BMS level were detected among the genotypes of the rs41648172 SNP in the Niigata prefecture population, by analysis using a model that included the SNP genotype as the fixed effect and the sire as the random effect (Table 2). The BMS level in the TT homozygotes was marginally higher than that in the CC homozygotes, and the values in the heterozygotes were intermediate between those in the 2 homozygotes (Table 2). These results were consistent with the data obtained in our previous study in the Oita prefecture population [5]. These results suggest that the association of the rs41648172 SNP with the BMS level was replicated in the general Japanese Black beef cattle populations.
In previous study, we showed that the rs41648172 SNP in PNLIP is associated with growth-related traits of the CWT, REA, RT and daily gain in the Oita prefecture population [8]. In this study, the rs41648172 SNP genotype had no significant effects on the CWT, REA and RT, as well as YE and SFT, in the Niigata prefecture population. Many quantitative trait loci (QTL) for the growthrelated trait are thought to be fixed in the Oita prefecture population, but not in the Niigata prefecture population. Our present study might not have sufficient power to detect the association of the rs41648172 SNP with the growth-related trait in the Niigata prefecture population, because of the larger number of segregating QTL for the growth-related trait in the Niigata prefecture population as compared with that in the Oita prefecture population. Further study using a larger number of samples will be needed for the Niigata prefecture population.
In this study, we demonstrated replication of the association of the rs41648172 SNP with the BMS level, and revealed a favorable effect of the T allele on the beef quality in general Japanese Black beef cattle populations. Together with the results of our previous study [5], these findings suggest that the rs41648172 SNP in the PNLIP is a useful marker for effective marker-assisted selection to increase the level of marbling in Japanese Black beef cattle.
4. CONCLUSION
In this study, we showed that the rs41648172 SNP in the PNLIP replicated association with marbling in Japanese Black beef cattle population of Niigata prefecture, and that the T allele at the SNP had a favorable effect on the beef quality. This study will provide useful information for the establishment of effective marker-assisted selection to increase the levels of marbling in Japanese Black beef cattle.
5. ACKNOWLEDGEMENTS
This work was supported by a Grant-in-Aid for Scientific Research (B) (no. 14360166) from the Ministry of Education, Culture, Sports, Science and Technology of Japan, and by the research funds of Japanese Livestock Technology Association.