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NCAPG is differentially expressed during longissimus muscle development and is associated with growth traits in Chinese Qinchuan beef cattle

Abstract

Based on RNA-seq analysis, we recently found that the bovine NCAPG (non-SMC condensin I complex, subunit G) gene is differentially expressed during development of the longissimus muscle. In the present study, we validated this result and, using quantitative real-time PCR analysis, identified two adjacent genes, LCORL and DCAF16, that are more abundant in fetal muscle tissue; further analysis of tissue-specific expression patterns indicated high abundance of NCAPG in muscle. Since no polymorphisms were detected in a previous study of Qinchuan cattle, we extended our investigation to examine the occurrence of single-nucleotide polymorphisms (SNPs) in the NCAPG gene. Three SNPs, i.e., one located in the intron region (g47747: T > G), a synonymous mutation (g52535: A > G) and a missense mutation (g53208: T > G) that leads to a change in the amino acid of interest (pIle442Met), were detected in a population of Qinchuan beef cattle (n = 300). Association analysis showed that these SNPs were significantly associated with the growth traits of Qinchuan beef cattle. Our results indicate that the bovine NCAPG gene may be involved in the development of the longissimus muscle. These polymorphisms in the NCAPG gene may be useful for marker-assisted selection of optimal body size in Qinchuan beef cattle.

Keywords:
association analysis; growth traits; longissimus muscle; NCAPG expression; single nucleotide polymorphism

Introduction

Optimal body size has been intensively investigated in beef cattle breeding and is considered to be a trait of high economic importance (Littlejohn et al., 2011). Numerous genetic studies have sought to identify quantitative trait locus (QTL) or major genes associated with body size-related characteristics, such as growth and carcass traits.

In a genome-wide association study, Snelling et al. (2010)Snelling WM, Allan MF, Keele JW, Kuehn LA, McDaneld T, Smith TPL, Sonstegard TS, Thallman RM and Bennett GL (2010) Genome-wide association study of growth in crossbred beef cattle. J Anim Sci 88:837-848. found a highly significant association between a chromosomal haplotype comprising the NCAPG (non-SMC condensin I complex, subunit G) gene and the body weight of cattle over time. The importance of the bovine NCAPG gene had previously been suggested by Setoguchi et al. (2009)Setoguchi K, Furuta M, Hirano T, Nagao T, Watanabe T, Sugimoto Y and Takasuga A (2009) Cross-breed comparisons identified a critical 591-kb region for bovine carcass weight QTL (CW-2) on chromosome 6 and the Ile-442-Met substitution in NCAPG as a positional candidate. BMC Genet 10:43., who located a QTL for body or carcass weight in cattle (known as CW-2) in a 591-kb interval on bovine chromosome 6 (BTA6); they also identified a candidate causal variant in the NCAPG gene, NCAPG: c.1326T > G, responsible for the amino acid change p. Ile442Met. Additional studies (Eberlein et al., 2009Eberlein A, Takasuga A, Setoguchi K, Pfuhl R, Flisikowski K, Fries R, Klopp N, Furbass R, Weikard R and Kuhn C (2009) Dissection of genetic factors modulating fetal growth in cattle indicates a substantial role of the non-SMC condensin I complex, subunit G (NCAPG) gene. Genetics 183:951-964.; Weikard et al., 2010Weikard R, Altmaier E, Suhre K, Weinberger KM, Hammon HM, Albrecht E, Setoguchi K, Takasuga A and Kuhn C (2010) Metabolomic profiles indicate distinct physiological pathways affected by two loci with major divergent effect on Bos taurus growth and lipid deposition. Physiol Genom 42A:79-88.) that investigated the association of the NCAPG: c.1326T > G mutation with birth weight and body weight confirmed the role of this gene locus as the CW-2 QTL. These findings support the possibility that NCAPG regulates muscle growth in cattle and thereby influences muscle performance.

Based on RNA-seq analysis, we recently found that the NCAPG gene and its neighboring gene, LCORL, are both differentially expressed in longissimus muscle of fetal and adult Chinese Qinchuan beef cattle (He and Liu, 2013He H and Liu XL (2013) Characterization of transcriptional complexity during longissimus muscle development in bovines using high-throughput sequencing. PloS One 8:e64356.). This raises the possibility that NCAPG regulates muscle growth and thus influences the performance of Qinchuan beef cattle, the best-known native cattle breed in China. In the present study, we sought to identify important single nucleotide polymorphisms (SNPs) of the NCAPG gene and use this information for haplotype construction and association analysis. This investigation may contribute to our understanding of the role that NCAPG plays in the variation of cattle growth traits. Such knowledge could be relevant to improving beef cattle breeding practices in China.

Materials and Methods

NCAPG expression patterns in cattle

Quantitative real-time polymerase chain reactions (qRT-PCR) were used to examine the expression levels of NCAPG in heart, liver, spleen, lung and kidney samples from three adult Chinese Qinchuan cattle, and in longissimus muscle samples from three embryos at day 135 post-fertilization and three 30-month-old female adult cattle; the expression levels of LCORL and DCAF16 in adult muscle samples were also examined. Tissue samples were obtained immediately after slaughter and were stored in liquid nitrogen until used. Total RNA was extracted with Trizol reagent (Ambion, USA). The quality (intactness) of the RNA was confirmed using a 2100 Bioanalyzer (Agilent, USA) and only samples with an RNA integrity number > 7 were used in subsequent analyses. One microgram of RNA from each sample was reverse-transcribed to cDNA using a PrimeScript RT reagent kit with gDNA Eraser (Takara, Japan). qRT-PCR was done with a CFX96 Real Time detection system (Bio-Rad) in triplicate using 2 SYBR® Premix ExTaqTM II (TaKaRa, Japan). The data derived from the real-time PCR analysis were transformed using the formula 2-ΔΔCt (Livak and Schmittgen, 2001Livak KJ and Schmittgen TD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the 2-DDCt method. Methods 25:402-408.). For normalization, the GAPDH gene was used as an endogenous control. The primers used for qRT-PCR analysis were designed using Primer 5 software (PREMIER Biosoft International) and are shown in Table S1 Table S1 Primers used for qRT-PCR. .

DNA samples and phenotypic data

A pure-bred population of 300 Qinchuan beef cattle (30 ± 2 months of age, bullocks) was used in this study to identify mutations in the bovine NCAPG gene. The cattle were from a single farm, reared under identical conditions and fed the same diet. The calves were weaned to six months of age on average and were then raised to slaughter on a diet of corn and corn silage.

Genomic DNA from the 300 Qinchuan cattle was isolated from 2% heparin-treated blood samples and stored at −80 °C as standard procedure (Sambrook and Russell, 2002Sambrook J and Russell DW (2002) Molecular Cloning: A Laboratory Manual. 3rd edition. Science Press, Beijing. Translated by Huang Pei Tang.). The DNA was diluted to 50 ng/μL in ddH2O and stored at −20 °C until further analysis.

The traits used to describe cattle body size were body height (BH, cm), body length (BL, cm), hip width (HW, cm), body weight (BW, kg) and carcass weight (CW, kg). Carcass weight was measured right after slaughter while the other parameters were measured right before slaughter. All of the traits were measured according to the GB/T17238-1998 criterion for the Cutting Standard of Fresh and Chilled Beef in China (China Standard Publishing House). All of the experimental procedures were performed according to the terms of the authorization granted by the Chinese Ministry of Agriculture.

SNP detection and genotyping

DNA sequencing was used to identify sequence variations in the NCAPG gene. Triplicate samples of DNA from each animal were used as the template to amplify the different regions of NCAPG. The primers used for amplification of the NCAPG gene were designed from a published gene sequence (GenBank accession number: AC_000163.1) using Primer 5 software and are shown in Table S2 Table S2 Primer sequences and PCR conditions used for amplifications and RFLP analysis. . The PCR amplifications were done in a final volume of 15 μL containing 50 ng of genomic DNA as the template and 10 mM Tris-HCl buffer (pH 8.8) with 50 mM KCl, 0.2 μM of each primer, 200 μM dNTP, and 0.5 U of Taq DNA polymerase (MBI Fermentas, USA). The PCR conditions were as follows: after an initial denaturation for 5 min at 95 °C, the amplicons were generated using 35 cycles of 30 s at 94 °C, 30 s at an optimized annealing temperature (Table S2 Table S2 Primer sequences and PCR conditions used for amplifications and RFLP analysis. ) and 45 s at 72 °C, and a 10 min final extension step at 72 °C. The products were sequenced in both directions using an ABI PRISM 3730 DNA analyzer (Sango, Shanghai, China). The sequences were analyzed using DNASTAR software (version 7.0).

PCR-RFLP and forced PCR-RFLP were used to genotype the cattle. The primer information and restriction enzymes (REs) are shown in Table S2 Table S2 Primer sequences and PCR conditions used for amplifications and RFLP analysis. . The PCR products were digested with their respective REs at distinct temperatures and the digested products were then separated by electrophoresis on 3% agarose gels.

Statistical analysis

The population genetic diversity parameters, including allele and genotype frequencies, effective number of alleles (Ne), heterozygosity (He), homozygosity (Ho), Hardy-Weinberg equilibrium (HWE) and polymorphism information content (PIC) were estimated using Popgen32 software. The linkage disequilibrium (LD) structure of three loci, as measured by D) and r2, was determined using HAPLOVIEW (Barrett et al., 2005Barrett JC, Fry B, Maller J and Daly MJ (2005) Haploview: Analysis and visualization of LD and haplotype maps. Bioinformatics 21:263-265.; Huang et al., 2013Huang YZ, Wang KY, He H, Shen QW, Lei CZ, Lan XY, Zhang CL and Chen H (2013) Haplotype distribution in the GLI3 gene and their associations with growth traits in cattle. Gene 513:141-146.). The PHASE program (Stephens et al., 2001Stephens M, Smith NJ and Donnelly P (2001) A new statistical method for haplotype reconstruction from population data. Am J Hum Genet 68:978-989.) was used to calculate the individual haplotypes. General linear models (GLMs) were generated with SPSS software (ver. 16.0) to investigate the association of NCAPG mutations with growth and carcass traits (Holzer and Precht, 1992Holzer C and Precht M (1992) Multiple comparison procedures for normally distributed ANOVA models in SAS, SPSS, BMDP and Minitab. Comput Stat Data Anal 13:351-358.; Huang et al., 2011Huang YZ, He H, Wang J, Li ZJ, Lan XY, Lei CZ, Zhang EP, Zhang CL, Wang JQ, Shen QW, et al. (2011) Sequence variants in the bovine nucleophosmin 1 gene, their linkage and their associations with body weight in native cattle breeds in China. Anim Genet 42:556-559.) using the model: Yij = μ + ai + eij, where Yij is the trait value observed for animal j and genotype i, μ is the overall population mean, ai corresponds to the fixed effect of genotype i, and eij is the residual error. A p value < 0.05 was considered to be significant. For a more detailed analysis of the results, we corrected the p values using the Bonferroni correction (a = 0.05/3) to account for multiple tests and obtain more robust comparisons.

Results

NCAPG expression levels

Figure 1A shows the levels of NCAPG gene expression during development of the longissimus muscle as assessed using qRT-PCR. NCAPG was up-regulated in fetal muscle compared with adult muscle. Among the various tissues screened, NCAPG expression was greatest in muscle followed by liver; low expression was seen in other organs (heart, kidney, lung and spleen) (Figure 1B). As with NCAPG, the expression of LCORL and DCAF16 (two neighboring genes) was also much greater in fetal muscle compared to adult muscle.

Figure 1
A. Expression levels of the NCAPG, LCORL and DCAF16 genes in fetal and adult muscle tissue, B. Tissue-specific expression patterns of the NCAPG gene in adult cattle. The columns represent the means ± SEM (n = 3).

SNP detection and diversity analyses

Three SNPs (g47747: T > C, g52535: A > G and g53208: T > G) were detected and are shown in Figure 2. The SNP g47747: T > C was located in intron six, g52535: A > G was a synonymous mutation located in exon eight, and g53208: T > G was a missense mutation leading to the amino acid change p. Ile442Met in the NCAPG protein.

Figure 2
Schematic representation of the NCAPG gene showing the location of the three SNPs. Blue blocks are gene exons.

The SNPs were successfully genotyped using PCR-RFLP and force PCR-RFLP, as shown in Figure S1 Figure S1 PCR-RFLP and force PCR-RFLP amplification products for the NCAPG gene. . Distinct genotypes were defined by distinct banding patterns. The individuals with g47747: T > C were genotyped using PCR-RFLP. Digestion of the resulting 495-bp PCR fragment of NCAPG with Eco81I resulted in fragments with band lengths of 302 and 193 bp for individuals with the CC homozygous genotype, 495, 302 and 193 bp for TC heterozygotes, and 495 bp for TT homozygotes. PCR-RFLP was also used to genotype the individuals with g52535: A > G. Digestion of the resulting 406-bp fragment with VspI resulted in fragment lengths of 296 and 110 bp for AA homozygotes, 406, 296 and 110 bp for TC heterozygotes, and 406 bp for TT homozygotes. Forced PCR-RFLP was used to genotype the individuals with g53208: T > G. Digestion of the resulting 141-bp fragment with XapI resulted in fragment lengths of 122 and 19 bp for TT homozygotes, 141, 122 and 19 bp for TG heterozygotes, and 141 bp for GG homozygotes.

The allele and genotype frequencies and the genetic diversity parameters (Ho, He, Ne and PIC) of the three SNPs are shown in Table 1. The three loci identified in Qinchuan cattle were in Hardy-Weinberg equilibrium (p > 0.05). Our results suggest that Qinchuan cattle are in equilibrium with regard to artificial selection, migration and genetic drift. The PIC values ranged from 0.3541 to 0.3688, indicating an intermediate genetic diversity for the NCAPG gene in the population analyzed.

Table 1
Genetic diversity parameters for the SNPs detected in this study.

Linkage disequilibrium and haplotype analysis

The linkage disequilibrium between the polymorphism pairs and the haplotype structure of the NCAPG gene are summarized in Tables 2 and 3, respectively. The linkage disequilibrium between the three SNPs was expressed as D) and r2 using HAPLOVIEW. The values of D) ranged from 0.184 to 0.323, and the r2 values ranged from 0.017 to 0.05. These results indicated that the three SNPs were in low linkage disequilibrium. The haplotype structure analysis was done using PHASE. Six haplotypes were identified in the population. Hap11 (-TGT-) had the highest haplotype frequency (29%) and Hap12 (-CAG-) had the lowest haplotype frequency (5%).

Table 2
Linkage equilibrium parameters estimated for the three NCAPG gene SNPs detected in this study.
Table 3
Haplotype frequencies for the three NCAPG gene SNPs detected in Qinchuan beef cattle.

Association study

The association analysis focused mainly on the statistical correlation between genetic markers (SNPs) and traits (Botstein and Risch, 2003Botstein D and Risch N (2003) Discovering genotypes underlying human phenotypes: Past successes for Mendelian disease, future approaches for complex disease. Nat Genet 33:228-237.). In particular, we analyzed the associations of the three SNPs with growth traits in Qinchuan cattle. Table 4 summarizes the results of the association analyses between individual markers and growth traits.

Table 4
Effects of NCAPG genotypes on growth and carcass traits in Qinchuan beef cattle.

In agreement with our previous results for g47747: T > C, the animals with the TT genotype had longer bodies than those with the CC genotype (p < 0.05). In contrast, the analysis of g52535: A > G showed that individuals with the AA genotype tended to have longer bodies and heavier carcasses than those with the GG genotype (p < 0.05). The analysis of g53208: T > G revealed that individuals with genotype GG had significantly greater body length, hip width and carcass weight compared with AA homozygote (p < 0.05); the association between g53208: T > G and body length remained significant after the Bonferroni correction, which suggested that this was the most important association detected in our analysis.

Discussion

The bovine NCAPG gene is located on chromosome BTA6 and has attracted much attention because of its effect on cattle growth traits. RNA-seq and qRT-PCR analyses have shown a high abundance of NCAPG transcripts in muscle compared to other tissues, with greater abundance in fetal compared to adult muscle. The greater expression of NCAPG in fetal muscle suggests that this gene may play an important role in early muscle development. Metzger et al. (2013)Metzger J, Schrimpf R, Philipp U and Distl O (2013) Expression levels of LCORL are associated with body size in horses. PloS One 8:e56497. investigated the relative expression levels of LCORL and its two neighboring genes, NCAPG and DCAF16, and demonstrated a significant association of the relative LCORL expression levels with horse size. Lindholm-Perry et al. (2014) also identified a relationship between NCAPG expression in LD (linkage disequilibrium) muscle and average daily gain for cows. As shown here, NCAPG, LCORL and DCAF16 were all expressed at low levels in adult muscle tissue. This finding suggests that NCAPG expression may be associated with the development of bovine muscle, although further research is required to elucidate the causal mechanism.

Since we had previously identified no SNPs in the LCORL gene of Qinchuan beef cattle, in the present study we focused on the NCAPG gene. Three SNPs were detected by sequencing: an intron mutation (g47747: T > C), a synonymous mutation (g52535: A > G) and a missense mutation (g53208: T > G) that leads to the amino acid change p. Ile442Met in the NCAPG protein. The ancestral population structure, which is reflected in the distribution of haplotypes, can occasionally provide greater power than single-marker analysis for studying genetic diseases and trait associations (Akey et al., 2001Akey J, Jin L and Xiong MM (2001) Haplotypes vs single marker linkage disequilibrium tests: What do we gain? Eur J Hum Genet 9:291-300.). As shown here, six haplotypes were present at varying frequencies. One explanation for this variation in haplotype frequency is that new mutants are derived from several common haplotypes and common high-frequency haplotypes have persisted in the population for a long time (Posada and Crandall, 2001Posada D and Crandall KA (2001) Intraspecific gene genealogies: Tree grafting into networks. Trends Ecol Evol 16:37-45.).

In this study, meaningful associations were found between SNPs and growth traits. Based on our statistical analysis, individuals with the TT genotype at locus g47747: T > C, the AA genotype at locus g52535: A > G and the GG genotype at locus g53208: T > G could be selected to obtain the optimal body size. The SNPs g47747: T > C and g52535: A > G are silent mutations that do not change the amino acid composition of the expressed protein but are nonetheless associated with the growth traits of Qinchuan cattle. In agree with this, there have been several reports on the effects of silent mutations on cattle development. Three silent mutations of the bovine GL13 gene are associated with body weight at birth and at six months of age in Nanyang cattle (Huang et al., 2013Huang YZ, Wang KY, He H, Shen QW, Lei CZ, Lan XY, Zhang CL and Chen H (2013) Haplotype distribution in the GLI3 gene and their associations with growth traits in cattle. Gene 513:141-146.). Silent mutations in the bovine INSIG1 gene have also been associated with growth traits in Qinchuan beef cattle (Liu et al., 2012Liu Y, Liu XL, He H and Gu YL (2012) Four SNPs of insulin-induced gene 1 associated with growth and carcass traits in Qinchuan cattle in China. Genet Mol Res 11:1209-1216.). The mechanism underlying the association between silent mutations and growth traits in beef cattle has yet to be determined.

The g53208: T > G SNP is a missense mutation that encodes a change from Ile to Met (p. Ile442Met). In a previous study, Dej et al. (2004)Dej KJ, Ahn C and Orr-Weaver TL (2004) Mutations in the Drosophila condensin subunit dCAP-G: Defining the role of condensin for chromosome condensation in mitosis and gene expression in interphase. Genetics 168:895-906. found that the NCAPG gene encodes a protein of the condensin I complex that has an important function in regulating mitotic cell division. Additionally, Seipold et al. (2009)Seipold S, Priller FC, Goldsmith P, Harris WA, Baier H and Abdelilah-Seyfried S (2009) Non-SMC condensin I complex proteins control chromosome segregation and survival of proliferating cells in the zebrafish neural retina. BMC Dev Biol 9:e40. previously reported that an NCAPG mutation predominantly affects the highly proliferative progenitor cells of the zebrafish neural retina. This mutation in cattle may also participate in this biological process but its mechanism needs further research. Previous investigations have focused on the association of this missense mutation with the phenotypic traits of cattle. Weikard et al. (2010)Weikard R, Altmaier E, Suhre K, Weinberger KM, Hammon HM, Albrecht E, Setoguchi K, Takasuga A and Kuhn C (2010) Metabolomic profiles indicate distinct physiological pathways affected by two loci with major divergent effect on Bos taurus growth and lipid deposition. Physiol Genom 42A:79-88. found that this SNP in NCAPG was associated with the time course of average daily gain in Japanese Black and Charolais German Holstein populations. Eberlein et al. (2009)Eberlein A, Takasuga A, Setoguchi K, Pfuhl R, Flisikowski K, Fries R, Klopp N, Furbass R, Weikard R and Kuhn C (2009) Dissection of genetic factors modulating fetal growth in cattle indicates a substantial role of the non-SMC condensin I complex, subunit G (NCAPG) gene. Genetics 183:951-964. found that this SNP was associated with birth weight in a Charolais German Holstein cross population. In our study, this missense mutation was significantly associated with body length, hip width and carcass weight, a finding in general agreement with previous reports. These results suggest that the g53208: T > G SNP is significantly associated with growth traits of numerous cattle breeds, although the mechanism underlying this relationship requires further research. Interestingly, this SNP is significantly associated with body length, hip width and carcass weight, but not body weight. Nevertheless, the GG genotype tended to have a greater body weight than the TT genotype, although this difference may reflect the small sample size in our research. An association analysis with a larger sample group should yield more robust results.

In conclusion, the results of this study indicate a significant difference in the expression of the NCAPG, LCORL and DCAF16 genes in fetal and adult bovine longissimus muscle, which suggests that they may be involved in muscle development. Three SNPs in NCAPG were associated with bovine growth traits. Together, these findings suggest that NCAPG gene polymorphisms could be potentially useful genetic markers for breeding programs aimed at improving Qinchuan beef cattle. However, further studies are needed to establish the functional effects of the various alleles and the mechanisms involved. Such information will improve our understanding of the role of NCAPG in the genetic regulation of cattle growth.

Acknowledgments

This research was supported by the National 12th “Five-Year” National Science and Technology Key Project (grant no. 2011AA100307), the National 11th “Five-Year” National Science and Technology Key Project (grant no. 2008AA101010), and the “13115” Sci-Tech Innovation Program of Shaanxi Province (grant no. 2008ZDKG-11).

  • Associate Editor: Alexandre R. Caetano

References

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  • Barrett JC, Fry B, Maller J and Daly MJ (2005) Haploview: Analysis and visualization of LD and haplotype maps. Bioinformatics 21:263-265.
  • Botstein D and Risch N (2003) Discovering genotypes underlying human phenotypes: Past successes for Mendelian disease, future approaches for complex disease. Nat Genet 33:228-237.
  • Dej KJ, Ahn C and Orr-Weaver TL (2004) Mutations in the Drosophila condensin subunit dCAP-G: Defining the role of condensin for chromosome condensation in mitosis and gene expression in interphase. Genetics 168:895-906.
  • Eberlein A, Takasuga A, Setoguchi K, Pfuhl R, Flisikowski K, Fries R, Klopp N, Furbass R, Weikard R and Kuhn C (2009) Dissection of genetic factors modulating fetal growth in cattle indicates a substantial role of the non-SMC condensin I complex, subunit G (NCAPG) gene. Genetics 183:951-964.
  • He H and Liu XL (2013) Characterization of transcriptional complexity during longissimus muscle development in bovines using high-throughput sequencing. PloS One 8:e64356.
  • Holzer C and Precht M (1992) Multiple comparison procedures for normally distributed ANOVA models in SAS, SPSS, BMDP and Minitab. Comput Stat Data Anal 13:351-358.
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  • Huang YZ, Wang KY, He H, Shen QW, Lei CZ, Lan XY, Zhang CL and Chen H (2013) Haplotype distribution in the GLI3 gene and their associations with growth traits in cattle. Gene 513:141-146.
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  • Liu Y, Liu XL, He H and Gu YL (2012) Four SNPs of insulin-induced gene 1 associated with growth and carcass traits in Qinchuan cattle in China. Genet Mol Res 11:1209-1216.
  • Livak KJ and Schmittgen TD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the 2-DDCt method. Methods 25:402-408.
  • Metzger J, Schrimpf R, Philipp U and Distl O (2013) Expression levels of LCORL are associated with body size in horses. PloS One 8:e56497.
  • Posada D and Crandall KA (2001) Intraspecific gene genealogies: Tree grafting into networks. Trends Ecol Evol 16:37-45.
  • Sambrook J and Russell DW (2002) Molecular Cloning: A Laboratory Manual. 3rd edition. Science Press, Beijing. Translated by Huang Pei Tang.
  • Seipold S, Priller FC, Goldsmith P, Harris WA, Baier H and Abdelilah-Seyfried S (2009) Non-SMC condensin I complex proteins control chromosome segregation and survival of proliferating cells in the zebrafish neural retina. BMC Dev Biol 9:e40.
  • Setoguchi K, Furuta M, Hirano T, Nagao T, Watanabe T, Sugimoto Y and Takasuga A (2009) Cross-breed comparisons identified a critical 591-kb region for bovine carcass weight QTL (CW-2) on chromosome 6 and the Ile-442-Met substitution in NCAPG as a positional candidate. BMC Genet 10:43.
  • Snelling WM, Allan MF, Keele JW, Kuehn LA, McDaneld T, Smith TPL, Sonstegard TS, Thallman RM and Bennett GL (2010) Genome-wide association study of growth in crossbred beef cattle. J Anim Sci 88:837-848.
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Supplementary Material

The following online material is available for this article:

Figure S1

PCR-RFLP and force PCR-RFLP amplification products for the NCAPG gene.

Table S1

Primers used for qRT-PCR.

Table S2

Primer sequences and PCR conditions used for amplifications and RFLP analysis.

This material is available as part of the online version of this article from http://scielo.br/gmb.

Publication Dates

  • Publication in this collection
    Oct-Dec 2015

History

  • Received
    10 Oct 2014
  • Accepted
    02 Apr 2015
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