Ectopic Expression of Retrotransposon-Derived PEG11/RTL1 Contributes to the Callipyge Muscular Hypertrophy

The callipyge phenotype is an ovine muscular hypertrophy characterized by polar overdominance: only heterozygous + ^Mat /CLPG ^Pat animals receiving the CLPG mutation from their father express the phenotype. + ^Mat /CLPG ^Pat animals are characterized by postnatal, ectopic expression of Delta-like 1 homologue (DLK1) and Paternally expressed gene 11/Retrotransposon-like 1 (PEG11/RTL1) proteins in skeletal muscle. We showed previously in transgenic mice that ectopic expression of DLK1 alone induces a muscular hypertrophy, hence demonstrating a role for DLK1 in determining the callipyge hypertrophy. We herein describe newly generated transgenic mice that ectopically express PEG11 in skeletal muscle, and show that they also exhibit a muscular hypertrophy phenotype. Our data suggest that both DLK1 and PEG11 act together in causing the muscular hypertrophy of callipyge sheep.     

Differential expression of the GTL2 gene within the callipyge region of ovine chromosome 18

The inheritance pattern of the skeletal muscle hypertrophy phenotype caused by the callipyge gene has been characterized as polar overdominance. We hypothesized that this trait may be caused by a gain or loss of gene expression because of the reversible nature of the phenotype in paternal vs. maternal inheritance. Suppression subtraction cDNA probes were made from skeletal muscle mRNA of normal (NN) and callipyge (C(Pat)N(Mat)) animals and hybridized to Southern blots containing bacterial artificial chromosomes (BACs) that comprise a physical contig of the callipyge region. The CN-NN probes hybridized to two ovine and seven bovine BACs. Sequence analysis of fragments within those BACs indicated short regions of similarity to mouse gene trap locus (gtl2). Northern blots analysis of RNA from hypertrophy-responsive muscles show a population of GTL2 mRNA centred around 2.4 kb that were abundantly expressed in 14-day prenatal NN and C(Pat)N(Mat) lambs but were down-regulated in day 14 and day 56 postnatal NN lambs. The expression of GTL2 remained elevated in 14- and 56-day-old C(Pat)N(Mat) lambs as well as in 56-day-old N(Pat)C(Mat) and CC lambs. Expression of GTL2 in the supraspinatus, which does not undergo hypertrophy, was very low for all genotypes and ages. Isolation of cDNA sequences show extensive alternative splicing and a lack of codon bias suggesting that GTL2 does not encode a protein. The mutation of the callipyge allele has altered postnatal expression of GTL2 in muscles that undergo hypertrophy and will help identify mechanisms involved in growth, genomic imprinting and polar overdominance.     

The callipyge locus: evidence for the trans interaction of reciprocally imprinted genes

The callipyge phenotype in sheep is an inherited muscular hypertrophy that affects only heterozygous individuals who receive the CLPG mutation from their father. The CLPG mutation is a single nucleotide substitution in what is probably a long-range control element (LRCE) within the DLK1-GTL2 imprinted domain. Recent results suggest that the unique mode of inheritance of callipyge, referred to as polar overdominance, results from the combination of the cis-effect of the CLPG mutation on the expression levels of genes in the DLK1-GTL2 imprinted domain, and the trans interaction between the products of reciprocally imprinted genes.     

基因组内三个信息层相互作用决定美臀表型产生

绵羊callipyge（美臀）是一种可遗传的肌肉肥厚体征,该表型以独特的方式“极化超显性”遗传给子代.绵羊18号染色体的DLK1-GTL2印记化结构域内存在1个远距离调控元件（long-range control element,LRCE）,该元件发生单个碱基突变（A→G）.A→G突变顺式作用于印记化结构域内的相关基因,印记化基因的产物包括蛋白质及非编码RNA分子,它们相互作用导致美臀表型产生.美臀表型产生及其独特的遗传方式是绵羊基因组内的蛋白质编码基因、非编码RNA基因以及表观遗传效应等3个信息层相互作用的结果,说明以前被忽略的隐藏信息发挥了极其重要的调控功能.这些现象对经典的中心法则形成了挑战,但是为基因组研究拓展了新的领域.     

Mosaicism of Solid Gold supports the causality of a noncoding A-to-G transition in the determinism of the callipyge phenotype

To identify the callipyge mutation, we have resequenced 184 kb spanning the DLK1-, GTL2-, PEG11-, and MEG8-imprinted domain and have identified an A-to-G transition in a highly conserved dodecamer motif between DLK1 and GTL2. This was the only difference found between the callipyge (CLPG) allele and a phylogenetically closely related wild-type allele. We report that this SNP is in perfect association with the callipyge genotype. The demonstration that Solid Gold-the alleged founder ram of the callipyge flock-is mosaic for this SNP virtually proves the causality of this SNP in the determinism of the callipyge phenotype.     

Polymorphism of <Emphasis Type="Italic">DLK1</Emphasis> and <Emphasis Type="Italic">CLPG</Emphasis> gene and their association with phenotypic traits in Chinese cattle

DLK1 and CLPG were located in DLK1-GTL2 imprinted cluster. They all affected muscle growth and meat tenderness. The functional importance of DLK1 and CLPG imply that the variation of the genes could affect the growth traits of animal. PCR-SSCP and sequencing were used to analyze the four loci of DLK1 gene and CLPG gene in 1109 individuals, which belong to eight breeds/species of bovidae, including cattle, buffalo and yak. A synonymous mutation (C451T) was detected in exon 5 of DLK1 in Qinchuan cattle, but didn’t change significantly with phenotypic traits. Three genotypes AA, AB and AC of CLPG were identified in Jiaxian cattle. The associations analyst of different genotypes showed that the individuals with genotypes AA and AC had a greater body weight and longer body length than those with genotype AB (P < 0.05 and P < 0.01, respectively); the AA individuals were different from those AB (P < 0.05) in the circumference of cannon bone. No polymorphism was observed in the other populations at other loci. These results were in agreement with the homology analysis: DLK1 and CLPG genes were in a highly conserved.     

Molecular characteristics of the porcine DLK1 and MEG3 genes

Imprinted genes play important roles in embryo survival and postnatal growth regulation. The DLK1 and MEG3 (previously GTL2) genes are linked and reciprocally imprinted in several mammals, but their imprinting status is still unknown in pigs. In this study, we report polymorphisms, imprinting status and QTL analyses of the porcine DLK1 and MEG3 genes. Muscle and adipose DNA and RNA samples from 30-day-old animals generated with reciprocal crosses between the Korean native pig (KNP) and Yorkshire breeds were used to analyse DLK1 and MEG3 variation and expression. The samples exhibited paternal expression of DLK1 and maternal expression of MEG3 in pigs. These results indicated that the imprinting status of the DLK1 and MEG3 genes is conserved across mammalian species. By linkage analyses, we assigned the DLK1 and MEG3 genes to the telomeric region of SSC7. By QTL analyses, we confirmed a significant polar overdominance (POD) effect in DLK1 , which was previously detected for several growth traits in pigs. However, no significant POD effect was found with the MEG3 locus.     

Abnormal postnatal maintenance of elevated DLK1 transcript levels in callipyge sheep

The underlying mechanism of the callipyge muscular hypertrophy phenotype in sheep (Ovis aries) is not presently understood. This phenotype, characterized by increased glycolytic type II muscle proportion and cell size accompanied by decreased adiposity, is not visibly detectable until approximately three to eight weeks after birth. The muscular hypertrophy results from a single nucleotide change located at the telomeric end of ovine Chromosome 18, in the region between the imprinted MATERNALLY EXPRESSED GENE 3 (MEG3) and DELTA, DROSOPHILA, HOMOLOG-LIKE 1 (DLK1) genes. The callipyge phenotype is evident only when the mutation is paternally inherited by a heterozygous individual. We have examined the pre- and postnatal expression of MEG3 and DLK1 in sheep of all four possible genotypes in affected and unaffected muscles as well as in liver. Here we show that the callipyge phenotype correlates with abnormally high DLK1 expression during the postnatal period in the affected sheep and that this elevation is specific to the hypertrophy-responsive fast-twitch muscles. These results are the first to show anomalous gene expression that coincides with both the temporal and spatial distribution of the callipyge phenotype. They suggest that the effect of the callipyge mutation is to interfere with the normal postnatal downregulation of DLK1 expression.     

Methylation analysis of the imprinted DLK1-GTL2 domain supports the random parental origin of the IGH-involving del(14q) in B-cell malignancies

Leukemias/lymphomas with IGH-involving del(14q)¹ commonly lose the DLK1-GTL2 imprinted domain that comprises several paternally and maternally expressed genes, including a cluster of microRNAs. Given that deletion of this region could lead to inactivation of a monoallelically expressed tumor suppressor gene, our study aimed at determination of the parental origin of del(14q/IGH). The designed allele-specific methylation study of the DLK1/GTL2 intergenic differentially methylated region allowed us to determine the parental origin of del(14q/IGH) in 9/20 analyzed cases. In six cases del(14q/IGH) was of the paternal origin and in three cases of the maternal origin. These findings argue against the concept that a TSG/anti-oncomir located in the imprinted region is systematically inactivated by a targeted deletion of its functional allele.     

新疆肉羊18号染色体上与后臀肌发育相关基因的多态性分析

通过对新疆肉羊18号染色体与后臀肌发育相关基因的多态性分析,试图找到与新疆肉羊后臀肌性状发达相关基因,为肉羊分子标记辅助选择提供理论线索。运用PCR-SSCP、PCR-RFLP方法,对陶赛特和萨福克两个肉羊品种群体及其与本地细毛羊杂交1代和2代群体Callipyge（CLPG）基因的多态性进行分析,结果表明：位于18号染色体内的DLK1和GTL2间的103849 bp处没有发现PCR-RFLP多态性,表明新疆肉羊后臀肌过度发育与CLPG基因无关。随后,实验进一步对18号染色体Meg3.9位点158520处进行PCR-SSCP分析,发现扩增片段存在着多态性;Meg3.9扩增片段多态性位点在肉羊群体中的基因型有AA、AB和AC,以AA型为主。其中AA、AB基因型与新疆肉羊后臀肌肉发达的表型无关（P>0.05）,AC基因型与新疆肉羊后臀肌肉发达的表型相关（P<0.05）。在陶赛特与本地细毛羊杂交1代群体中,AC基因型的屠体重和屠宰率与AA、AB基因型差异显著（P<0.05）,但三种基因型的各月龄体重没有差异(P>0.05)。通过以上分析可以推断,引起新疆肉用绵羊后臀肌过度发育的性状不是CLPG基因内9571-268.3位点突变导致,可能还存在其他基因或与其连锁的多个QTL的共同作用。     

Expression of <Emphasis Type="Italic">PEG11</Emphasis> and <Emphasis Type="Italic">PEG11AS</Emphasis> transcripts in normal and callipyge sheep

Background  

The callipyge mutation is located within an imprinted gene cluster on ovine chromosome 18. The callipyge trait exhibits polar overdominant inheritance due to the fact that only heterozygotes inheriting a mutant paternal allele (paternal heterozygotes) have a phenotype of muscle hypertrophy, reduced fat and a more compact skeleton. The mutation is a single A to G transition in an intergenic region that results in the increased expression of several genes within the imprinted cluster without changing their parent-of-origin allele-specific expression.     

Characterization of OAR1 and OAR18 QTL associated with muscle depth in British commercial terminal sire sheep

This study aimed at verifying previously identified QTL affecting growth and carcass traits on ovine chromosome 18 (OAR18) in Texel sheep (n = 1844), and on OAR1 in Charollais (n = 851) and Suffolk (n = 998) sheep. The QTL were investigated using regression and variance component mapping (VCA) of body weight, muscle and fat depth measurements. In addition, the mode of inheritance of the Texel OAR18 QTL was explored, using data from 4376 Texel sheep, fitting VCA models testing for additive and imprinting effects. We also simulated a 480‐sheep population with different QTL imprinting models and various available levels of marker information to understand the behaviour of the VCA results under different assumed genetic models. In summary, the previously identified QTL were successfully verified using both interval mapping and VCA in the three breeds. We propose a polar overdominance mode of inheritance for the OAR18 QTL in Texel sheep, and we present methods to dissect the QTL mode of inheritance, using the Texel OAR18 QTL as an example.     

QTL mapping for resistance to root-knot nematodes in the M-120 RNR Upland cotton line (Gossypium hirsutum L.) of the Auburn 623 RNR source

Root-knot nematodes Meloidogyne incognita (Kofoid and White) can cause severe yield loss in cotton (Gossypium hirsutum L.). The objectives of this study were to determine the inheritance and genomic location of genes conferring root-knot nematode resistance in M-120 RNR, a highly resistant G. hirsutum line with the Auburn 623 RNR source of resistance. Utilizing two interspecific F₂ populations developed from the same M-120 RNR by Gossypium barbadense (cv. Pima S-6) cross, genome-wide scanning with RFLP markers revealed a marker on Chromosome 7 and two on Chromosome 11 showing significant association with the resistant phenotype. The association was confirmed using SSR markers with the detection of a minor and a major dominant QTL on Chromosome 7 and 11, respectively. Combined across the two populations, the major QTL on Chromosome 11 Mi-C11 had a LOD score of 19.21 (9.69 and 9.61 for Pop1 and Pop2, respectively) and accounted for 63.7% (52.6 and 65.56% for Pop1 and Pop2, respectively) of the total phenotypic variation. The minor QTL locus on Chromosome 7 Mi ₁ -C07 had a LOD score of 3.48 and accounted for 7.7% of the total phenotypic variation in the combined dataset but was detected in only one population. The allele from the M-120 RNR parent contributed to increased resistance in the Mi-C11 locus, but surprisingly, the Pima S-6 allele contributed to increased resistance in the Mi-C07 locus. The M-120 RNR allele in the Mi-C11 locus, derived from the Auburn 623 RNR, is likely to have originated from the Clevewilt 6 cultivar. Results from this study indicated that the SSR marker CIR316 may replace the laborious greenhouse screening in breeding programs to identify genotypes resistant to M. incognita.