鸡MC4R基因的SNPs及其与屠体性状的相关研究

黑素皮质素受体(MC4R, melanocortin-4 receptor)基因的突变与猪、鼠和人等的食欲、肥胖、生长等性状有关, 而鸡MC4R基因的功能却知之甚少. 利用PCR-SSCP(single strand conformation polymorphism)和DNA测序的方法, 对资源家系F₂代鸡群MC4R基因多态性进行了分析, 发现存在4个单核苷酸多态(SNPs, single nucleotide polymorphisms)位点. 其中, 在MC4R基因5′调控区-524 nt发生了碱基的转换突变(C→T), 导致突变型基因比野生型基因多了一个NF-E2和一个cap转录因子结合位点; 在MC4R编码区(61 nt)发生了碱基的错义突变(G→A), 导致此处蛋白质的氨基酸由甘氨酸变为精氨酸; 在MC4R编码区315和336 nt发生了碱基的颠换突变(G→T)和转换突变(C→T), 这两个突变为同义突变. 通过最小二乘分析SNPs与屠体性状的关系, 结果是突变的BB, DD和FF等基因型与鸡的体重、全净膛重(或半净膛重)、腿肉重等存在显著(P<0.05)或极显著(P<0.01)的关系, 但与腹脂重不显著. 结果表明, MC4R基因可以作为影响和控制鸡体重、生长等屠体性状的主要候选基因.     

利用杂种细胞克隆板将猪CDC16基因定位于11号染色体

运用比较基因组学的方法,根据人的CDC16基因序列设计引物,从大围子猪和宁乡猪基因组DNA分离了CDC16基因内含子4和内含子8（GenBank收录号为AY880670和DQ206823）,通过扩增体细胞杂种克隆板上27个样品和辐射杂种克隆板上118个样品,确定了CDC16基因在猪染色体上的物理位置,首次将CDC16基因物理定位于猪SSC11 q11-17.该基因与微卫星SW1452标记紧密连锁,LOD值为16.08,存留率为22%,在放射杂交图谱上的图距为62 cR.CDC16基因区间定位结果与精细定位结果相一致,也与比较定位结果相一致,进一步验证了猪11号染色体和人13号染色体大部分片段存在同源性,这为该基因的克隆及和功能研究打下坚实基础.     

MC4R、POU1F1基因对京海黄鸡生长性能的遗传效应

以MC4R和POU1F1基因为候选基因, 采用PCR-SSCP和DNA测序技术检测两个候选基因在京海黄鸡群体中的单核苷酸多态性(SNPs), 同时对候选基因与京海黄鸡生长性能的相关性进行了研究。结果表明, MC4R基因编码区第662 bp位置有G→C碱基的点突变, 在京海黄鸡中检测到AA、AB、BB 3种基因型, A等位基因频率为0.929, B等位基因频率为0.071; 在POU1F1基因exon3在序列的第5 231 bp位置有一个A→T碱基的点突变, 检测到CC、CD、DD 3种基因型, C等位基因频率为0.500, D等位基因频率为0.500。采用GLM模型分析基因型对生长性能的遗传效应, 结果表明, MC4R基因AA基因型个体的4、8、12周龄体重显著地高于BB型个体(P<0.05), 16周龄体重差异极显著(P<0.01); POU1F1基因CD基因型个体体重极显著高于CC型和DD型(P<0.01)。因此推测MC4R和POU1F1基因可能是影响鸡生长性状的主效基因或与主效基因紧密连锁的标记基因, 能够在分子标记辅助选择中用于对鸡生长性状的遗传改良。     

鸡Z染色体上DMRT1基因的多重跨染色体剪接

性别决定与分化发育是同时涉及生命现象中两种细胞分裂(有丝分裂和减数分裂)形式的惟一的分化发育过程。对该过程中关键基因DMRT1的转录分析,发现位于鸡Z染色体上的DMRT1基因分别同时与4号染色体上的CENPC1基因、5号染色体上CD5R基因和2号染色体上37LRP/p40基因发生跨染色体剪接,由此构成了新的跨染色体剪接本DMRT1-CENPC1、DMRT1-CD5R和DMRT1-37LRP/p40。对其剪接位点的分析,发现两段染色体序列存在的重叠区可能在这种剪接中起着重要作用。DMRT1基因在转录过程中同时与多个染色体上基因发生多次跨染色体剪接的发现,无疑有助于对在转录水平上的多样性基因调控以及性别决定与分化发育等的认识开辟另一新途径。     

花青素合成基因bz1和bz2在莲藕染色体上的定位

Bronze 1(bz1)是编码UDP葡萄糖类黄酮葡糖基转移酶(UFGT)的基因,UFGT是种子糊粉层中的花青素生物合成酶。Bronze 2(bz2)是另一种花青素生物合成基因,与类黄酮的酰化、糖基化、转运、沉积等有关。以生物素标记的重组质粒pUC19中含有玉米bz1和bz2基因作为探针,与莲藕(Nelumbo nucifera L．)的有丝分裂染色体标本进行荧光原位杂交(fluorescence in situ hybridization,FISH)。结果显示,bz1和bz2基因分别位于莲藕的第2和第4号染色体长臂上,与着丝粒的相对距离分别为79％和67％。这是首次提供莲藕染色体上的FISH杂交信息,从而为增加莲藕染色体组中的遗传标记和建立遗传图谱奠定基础。     

薄片牡蛎的核型及18S-28S核糖体rRNA基因的染色体定位

以薄片牡蛎(Dendostrea folium)成体鳃组织为材料制备有丝分裂中期染色体标本,对其染色体核型进行了分析,并运用荧光原位杂交技术(FISH)将18S-28S核糖体RNA基因定位于中期染色体上。FISH探针是通过PCR扩增介于18S-28S rRNA基因之间的ITS和5.8S rRNA基因序列,并在PCR扩增过程中掺入了Biotin-11-dUTP进行生物素标记。结果显示,薄片牡蛎的单倍染色体数目为n=10,全部为中部着丝粒染色体。与大多数已知巨蛎属牡蛎的染色体核型相似。ITS探针在薄片牡蛎中期分裂体相上产生两簇FISH信号,分别杂交于2号染色体短臂的近端粒区域。本研究首次报道了薄片牡蛎的中期染色体核型以及18S-28S核糖体RNA基因在染色体上的定位。     

参考家系鸡黑素皮质素受体3基因多态性与体重关系研究

鼠遗传学研究显示黑素皮质素受体3（melanocortin-3 receptor,MC3R）和MC4R在能量平衡控制中具有互补作用。敲除MC3R基因鼠表现为独有的代谢综合征和增加脂肪重量。以8周龄高体重或低体重独立选择的高体重系（high weight,HW）和低体重系（low weight,LW）白洛克鸡3代参考家系群体作为实验材料,发现了5个新的MC3R基因单核苷酸多态性（single nucleotide polymorphisms,SNPs）;建立了基于限制性内切酶Dde I的MC3R基因型的PCR-RFLP分子检测方法。方差分析结果显示MC3R基因型显著影响公鸡和母鸡的体重,以及公鸡腹脂含量。该结果建议MC3R基因可以作为侯选基因解释杂交鸡体重显著差异的原因。     

人类GABARAPL2基因的染色体定位

为了确定人类GABAA受体相关蛋白相似蛋白2基因在染色体上的位置,根据该基因cDNA的3′非翻译区序列设计一对RH定位引物,以人／鼠体细胞腹辐杂种板Genebridge4(GB4)panel和G3panel试剂盒中的杂种细胞株基因组DNA为模板,在一定的条件下进行PCR扩,琼脂糖凝胶电泳结果分别插入Sanger和Stanford网站的RH定位分析系统进行统计学分析。结果PCR法在一些杂种细胞株中扩增出特异的目的片段,并经测序验证了其准确性。凝胶电泳结果在Sanger网站统计分析表明该基因与16号染色体上的AFM340ye5,AFM292xh5,AFM320wf1,AFMa066xd5,AFM249xc5位标紧密连锁;在Stanford网站统计分析表明该基因片与16号染色体上的SHGC－1457,SHGC－53415,SHGC－6782,SHGC－2228,SHGC－14629位标紧密连锁,LOD值均大于3。整合分析该染色体区带的物理图、遗传图及细胞图谱后,最终将基因定位在染色体16q22.3区带的D16s3016和D16s515位标之间。结论放射杂交定位法是一种新颖便捷的基因定位的方法,通过此法成功地进行了人类GABAA受体相关蛋白相似蛋白2基因的定位。     

利用鸡F2资源群体构建1号染色体遗传连锁图谱

在鸡1号染色体上选取23个微卫星标记,利用东北农业大学鸡F2资源群体构建了遗传连锁图谱。选用369只F2个体用于基因型测定。结果表明23个微卫星位点除MCW0058为低度多态,其他位点均为中高度多态。构建的连锁图谱覆盖1号染色体全长,总共637.9 cM。MCW0115和ROS0025标记顺序与EL图谱不同,但与WAU图谱一致。其他标记顺序与3大参考家系标记顺序一致,图谱总长和标记间距离大于3大参考家系。此连锁图谱的构建为数量性状位点（QTL）定位奠定了良好的基础。     

黑腹果蝇3号染色体裂翅平衡致死位点的发现及2号、3号染色体裂卷翅双平衡染色体的建立

果蝇的平衡染色体在遗传研究中被广泛应用.文章通过分析黑腹果蝇裂翅新突变体与野生型、982紫眼及黑檀体杂交后代裂翅性状情况,首次将裂翅基因定位于3号染色体上,并阐明了裂翅平衡致死、杂合子纯繁的遗传机制,获得了以裂翅为显性标记的3号平衡染色体品系.探索了双平衡染色体显性标记基因聚合的杂交模式,成功建立了以裂翅和卷翅为标记的2号、3号双平衡染色体.裂翅的发现为3号染色体平衡子提供了更加方便识另0的显性翅型标记,同时裂卷翅双平衡体的建立丰富了果蝇常用工具平衡子,可以广泛用于基因定位及突变筛选过程.     

Remarkable synteny conservation of melanocortin receptors in chicken,human, and other vertebrates

The melanocortin receptors (MCR) belong to the superfamily of G-protein-coupled receptors that participate in both peripheral and central functions, including regulation of energy balance. Genomic clones of the five chicken (GGA) MCRs were isolated and used to find the chromosomal location of each of the loci. The genes encoding MC2R and MC5R mapped to the middle part of the long arm of chromosome 2 (GGA2q22-q26) and MC4R proximally on the same chromosome arm, close to the centromere (2q12). This arrangement seems to be conserved on chromosome 18 in the human (HSA18). The MC1R and MC3R genes mapped to different microchromosomes that also appear to share homology with the respective human localization. The conserved synteny of the MC2R, MC5R, and MC4R cluster in chicken (GGA2), human (HSA18), and other mammals suggests that this cluster is ancient and was formed by local gene duplications that most likely occurred early in vertebrate evolution. Analysis of conserved synteny with mammalian genomes and paralogon segments prompted us to predict an ancestral gene organization that may explain how this family was formed through both local duplication and tetraploidization processes.     

Haplosufficiency of the melanocortin-4 receptor gene in individuals with deletions of 18q

The melanocortin-4 receptor (MC4R) is a seven, transmembrane G-protein-coupled receptor whose ligand, alpha-melanocyte-stimulating hormone (alpha-MSH), is a post-translational derivative of pro-opiomelanocortin (POMC). The regulatory pathway, of which MC4R is a part, has become an area of intense interest because of its potential role in obesity. Three studies have identified individuals with dominantly inherited obesity segregating with mutations in the MC4R gene. It has been hypothesized that the mutation found in these subjects resulted in a loss of gene function resulting in obesity due to haploinsufficiency of the MC4R gene. We have been studying the molecular basis of the phenotype of individuals with large deletions of chromosome 18q. Due to its location at 18q21.3, the MC4R gene is hemizygous in approximately one-third of the individuals in our study. If hemizygosity of the MC4R gene results in haploinsufficiency-induced obesity, then individuals with deletions of 18q whose deletions include the MC4R gene should be obese in comparison with those individuals whose deletion does not include the gene. Our data indicate no difference in obesity among those deleted and not deleted for the gene. This supports the hypothesis that the MC4R gene product is haplosufficient and the involvement of MC4R in obesity may reflect a dominant negative effect.     

Resolution of conflicting assignments for the bovine casein kinase II alpha (CSNK2A2) gene

The casein kinase II alpha' gene (CSNK2A2), which physically maps to human chromosome 16 (HSA16), has previously been mapped to bovine chromosome 5 (BTA5). Based on these results, a new segment of homology between the human and bovine genomes was suggested. In this paper we demonstrate linkage between CSNK2A2 and several markers on BTA18. Our result is supported by the extensive conservation of synteny between HSA16q and BTA18. Bovine chromosome 18 markers used in this study included several microsatellites, as well as the MC1R gene previously mapped to HSA16q24.3. Sequencing of the PCR-fragment mapped to BTA5 reveals that a CSNK-like retroposon was responsible for the conflicting assignments. The present results further extend the observed conservation of synteny between HSA16q and BTA18.     

Absence of Linkage Between Human Obesity and the Mouse Agouti Homologous Region (20q11.2) or Other Markers Spanning Chromosome 20q

XU, WEIZHEN, DANIELLE R REED, YUAN DING AND R ARLEN PRICE. Absence of linkage between human obesity and the mouse agouti homologous region (20q11.2) or other markers spanning chromosome 20q. Obes Res. Mutant alleles of the agouti gene cause obesity in the mouse and the homologous gene in humans has been mapped to chromosome 20q11.2. An allelic variant of the agouti gene could account for obesity in humans and we tested this hypothesis by genotyping 210 sibling pairs from 45 families segregating an obesity phenotype. Using sibling pair linear regression analysis, evidence for linkage between obesity and markers flanking the agouti locus and other markers spanning chromosome 20q was assessed. We found no correlation between identity-by-descent at these markers and obesity differences within pairs. In the mouse, obesity caused by mutations of the agouti gene develops later in life, so a subset of families with adult-onset obesity were also tested for linkage, with negative results. Although it is not possible to exclude alleles of the agouti gene as a contributor to obesity in humans, the absence of positive linkage in this study suggests that either the agouti gene has small effects or the allele frequency is low.     

Profound obesity secondary to hyperphagia in mice lacking kinase suppressor of ras 2

The kinase suppressor of ras 2 (KSR2) gene resides at human chromosome 12q24, a region linked to obesity and type 2 diabetes (T2D). While knocking out and phenotypically screening mouse orthologs of thousands of druggable human genes, we found KSR2 knockout (KSR2(-/-)) mice to be more obese and glucose intolerant than melanocortin 4 receptor(-/-) (MC4R(-/-)) mice. The obesity and T2D of KSR2(-/-) mice resulted from hyperphagia which was unresponsive to leptin and did not originate downstream of MC4R. The kinases AMP-activated protein kinase (AMPK) and mammalian target of rapamycin (mTOR) are each linked to food intake regulation, but only mTOR had increased activity in KSR2(-/-) mouse brain, and the ability of rapamycin to inhibit food intake in KSR2(-/-) mice further implicated mTOR in this process. The metabolic phenotype of KSR2 heterozygous (KSR2(+/minus;)) and KSR2(-/-) mice suggests that human KSR2 variants may contribute to a similar phenotype linked to human chromosome 12q24.     

Fine mapping of the muscular dystrophy (AM) gene on chicken chromosome 2q

Our previous studies revealed that the genetic locus for chicken muscular dystrophy of abnormal muscle (AM) mapped to chromosome 2q, and that the region showed conserved synteny with human chromosome 8q11-24.3. In the current study, we mapped the chicken orthologues of genes from human chromosome 8q11-24 in order to identify the responsible gene. Polymorphisms in the chicken orthologues were identified in the parents of the resource family. Twenty-three genes and expressed sequence tags (ESTs) were mapped to chicken chromosome 2 by linkage analysis. The detailed comparative map shows a high conservation of synteny between chicken chromosome 2q and human chromosome 8q. The AM locus was mapped between [inositol(myo)-1(or4)-monophosphatase 1] (IMPA1) gene and [core-binding factor, runt domain, alpha-subunit 2; translocated to 1; cyclin D-related] (CBFA2T1) gene. The genes located between IMPA1 and CBFA2T1 are the most likely candidates for chicken muscular dystrophy.     

A comparative analysis of MC4R gene sequence, polymorphism, and chromosomal localization in Chinese raccoon dog and Arctic fox

Numerous mutations of the human melanocortin receptor type 4 (MC4R) gene are responsible for monogenic obesity, and some of them appear to be associated with predisposition or resistance to polygenic obesity. Thus, this gene is considered a functional candidate for fat tissue accumulation and body weight in domestic mammals. The aim of the study was comparative analysis of chromosome localization, nucleotide sequence, and polymorphism of the MC4R gene in two farmed species of the Canidae family, namely the Chinese raccoon dog (Nycterutes procyonoides procyonoides) and the arctic fox (Alopex lagopus). The whole coding sequence, including fragments of 3'UTR and 5'UTR, shows 89% similarity between the arctic fox (1276 bp) and Chinese raccoon dog (1213 bp). Altogether, 30 farmed Chinese raccoon dogs and 30 farmed arctic foxes were searched for polymorphisms. In the Chinese raccoon dog, only one silent substitution in the coding sequence was identified; whereas in the arctic fox, four InDels and two single-nucleotide polymorphisms (SNPs) in the 5'UTR and six silent SNPs in the exon were found. The studied gene was mapped by FISH to the Chinese raccoon dog chromosome 9 (NPP9q1.2) and arctic fox chromosome 24 (ALA24q1.2-1.3). The obtained results are discussed in terms of genome evolution of species belonging to the family Canidae and their potential use in animal breeding.     

Evolutionarily-conserved gene CKAP2,located in region 13q14.3 of the human genome, is frequently rearranged in various tumors

The human CKAP2 gene, which is involved in diffuse large B-cell lymphomas, was localized via screening the GeneBridge 4 somatic cell radiation hybrid panel by means of the polymerase chain reaction (PCR). The CKAP2 gene was mapped between the WI-15460 and WI-3673 markers at the boundary between regions 13q14.3 and 13q21.1, at the distance of 14.39 cR (with 4.8 cR per cM) from the WI-5867 framework marker (lod score > 2.26). The human CKAP2 gene displayed high homology to mouse and rat expressed orthologs, A CKAP2-like sequence was found in human chromosome 14 and assumed to be a pseudogene resulting from duplication and subsequent mutations of the CKAP2 gene on chromosome 13. A possible role of the CKAP2 gene in oncogenesis associated with deletions and rearrangements of region 13q14.3-21.1 is discussed.     

Mapping of EST- and STS-markers in the human genome using a panel fo radiation hybrids

Ten DNA markers were localized in the human genome by a screening procedure against the radiation hybrid somatic cell panel (GeneBridge 4 RH Panel) using polymerase chain reaction (RH mapping method). DNA markers were developed to nucleotide sequences adjacent to NotI sites of human chromosome 3 (NotI-STS markers) and also to nucleotide sequences of human cDNA (EST markers). Three EST markers mapped (B10164, S16R and 18F5R) were localized in the human genome for the first time. Marker B10164 was found to be homologous to the nucleotide sequence of the BASP1 gene coding a major receptor protein. Markers S16R and 18F5R presumably tagged new genes, because no homologies were revealed among the nucleotide sequences presented in the databases. For four NotI-STS, more precise localization on human chromosome 3 was determined. On the basis of the data obtained, the NotI map may be integrated with other types of physical maps of human chromosome 3. RH mapping with a standard commercial panel of radiation hybrid somatic cells provided a chance to integrate the data obtained into international databases and existing integrated human chromosomal maps.