The Murine Dilute Suppressor Gene Encodes a Cell Autonomous Suppressor

The murine dilute suppressor gene (dsu) suppresses the coat-color phenotype of three pigment mutations, dilute (d), ashen (ash) and leaden (ln), that each produce adendritic melanocytes. Suppression is due to the ability of dsu to partially restore (ash and ln), or almost completely restore (d), normal melanocyte morphology. While the ash and ln gene products have yet to be identified, the d gene encodes a novel myosin heavy chain (myosin 12), which is speculated to be necessary for the elaboration, maintenance, and/or function of melanocyte cell processes. To begin to discriminate between different models of dus action, we have produced aggregation chimeras between mice homozygous for dsu and mice homozygous for d to determine if dsu acts cell autonomously or cell nonautonomously. In addition, we have further refined the map location of dsu in order to examine a number of possible dsu candidate genes mapping in the region and to provide a genetic basis for the positional cloning of dsu.     

Coat Color Variation and Pigmentation Gene Expression in Rhesus Macaques (Macaca mulatta)

Light-dark coat color variation is a common aspect of color diversity within and across mammalian taxa. This variation in pelage brightness is associated with aspects of evolutionary ecology, particularly for primates, but little is known about the genetic mechanisms underlying light-dark differences in pelage pigmentation. Previous work, focusing particularly on macaques (Genus Macaca), has found no clear relationship between color variation and coding sequences of key pigmentation genes. This suggests that other loci and/or gene regulatory differences underlie this variation and raises the question of how patterns of gene expression differ in light verses dark hair follicles. Here, we examine relative expression levels of pigmentation genes in hair follicles from free-ranging rhesus macaques (Macaca mulatta) showing stark light-dark coat color variation. We quantified the brightness (reflectance) of plucked hair tufts using a spectrophotometer. We extracted RNA from the follicles and used quantitative RT-PCR to measure the relative amounts of gene product (mRNA) for seven candidate pigmentation genes (MITF, MC1R, MGRN1, ATRN, SLC24A5, TYRP1, and DCT). Expression values were normalized with the house-keeping gene ACTB. All candidate genes were expressed at similar levels in dark, intermediate, and light hair, and thus, light-dark variation in macaque coat color is unlikely to be due to differences in the expression of these key pigmentation genes. This study represents the first examination of gene expression and natural color variation in a non-human primate population. Our results indicate that even in a system, like pigmentation, where a candidate-gene approach is promising, identifying important intra-specific gene regulatory differences remains challenging.     

Suppression of Nonsense Mutations in the Dystrophin Gene by a Suppressor tRNA Gene

Nonsense mutations in the dystrophin gene are the cause of Duchenne muscular dystrophy (DMD) in 10–15% of patients. In such an event, one approach to gene therapy for DMD is the use of suppressor tRNAs to overcome the premature termination of translation of the mutant mRNA. We have carried out cotransfection of the HeLa cell culture with constructs containing a suptRNA gene (pcDNA3suptRNA) and a marker LacZ gene (pNTLacZhis) using their polymer VSST-525 complexes. It was found that the number of cells producing -galactosidase depends inversely on the dose of the suptRNA gene. A single in vivo injection of the construct providing for expression of the suptRNAochre gene into mdx mouse muscle resulted in the production of dystrophin in 2.5% of fibers. This suggests that suppressor tRNAs are applicable in gene therapy for hereditary diseases caused by nonsense mutations.     

猪黑素皮质素受体1(MC1R)基因与毛色表型的研究

猪的毛色表型虽然与经济性状没有直接相关,但它却对经济效益产生重要影响,在猪育种实践、商品猪生产等方面都有应用。结合PCR—AccⅡ—RFIP、PCR—BspH I—RFLP及PCR-SSCP技术,分析了16个全同胞家系和金华猪、嘉兴黑猪、玉山黑猪、乐平花猪、上高两头乌猪及嵊县花猪等6个地方猪种随机采样个体的黑素皮质素受体1(MCIR)基因型。结果显示,地方猪种在MCIR位点携带高频率的显性黑等位基因E^DI,表明我国地方猪种的黑毛色可能主要由显性黑等位基因E^DI调控。通过对嵊县花猪MCIR位点的分析,首次发现PCR-SSCP证据的新序列,与已知的其他5个等位基因带型不同。家系个体的分析结果进一步验证了E^DI对E^p、e为完全显性,E^p对e为不完全显性。     

The KIT Gene Is Associated with the English Spotting Coat Color Locus and Congenital Megacolon in Checkered Giant Rabbits (Oryctolagus cuniculus)

The English spotting coat color locus in rabbits, also known as Dominant white spotting locus, is determined by an incompletely dominant allele (En). Rabbits homozygous for the recessive wild-type allele (en/en) are self-colored, heterozygous En/en rabbits are normally spotted, and homozygous En/En animals are almost completely white. Compared to vital en/en and En/en rabbits, En/En animals are subvital because of a dilated (“mega”) cecum and ascending colon. In this study, we investigated the role of the KIT gene as a candidate for the English spotting locus in Checkered Giant rabbits and characterized the abnormalities affecting enteric neurons and c-kit positive interstitial cells of Cajal (ICC) in the megacolon of En/En rabbits. Twenty-one litters were obtained by crossing three Checkered Giant bucks (En/en) with nine Checkered Giant (En/en) and two en/en does, producing a total of 138 F1 and backcrossed rabbits. Resequencing all coding exons and portions of non-coding regions of the KIT gene in 28 rabbits of different breeds identified 98 polymorphisms. A single nucleotide polymorphism genotyped in all F1 families showed complete cosegregation with the English spotting coat color phenotype (θ = 0.00 LOD  = 75.56). KIT gene expression in cecum and colon specimens of En/En (pathological) rabbits was 5–10% of that of en/en (control) rabbits. En/En rabbits showed reduced and altered c-kit immunolabelled ICC compared to en/en controls. Morphometric data on whole mounts of the ascending colon showed a significant decrease of HuC/D (P<0.05) and substance P (P<0.01) immunoreactive neurons in En/En vs. en/en. Electron microscopy analysis showed neuronal and ICC abnormalities in En/En tissues. The En/En rabbit model shows neuro-ICC changes reminiscent of the human non-aganglionic megacolon. This rabbit model may provide a better understanding of the molecular abnormalities underlying conditions associated with non-aganglionic megacolon.     

羊驼显性白毛调控KIT基因的分子克隆及在大肠杆菌中的表达

为研究羊驼显性白毛调控基因的结构特点及体外表达产物的生物活性,利用RT-PCR技术,首次从羊驼皮肤组织中扩增出羊驼KIT基因exon10-14 cDNA编码序列。结果表明:羊驼KIT基因exon10-14 cDNA长414bp,包括30 bp的exon10、127 bp的exon11、125 bp的exon12、91 bp的exon13和41 bp的exon14(全长151 bp),编码含138个氨基酸残基的蛋白;羊驼与牛、羊、猪、人、马等相比,核苷酸的同源性分别为94%、93%、93%、92%、92%,氨基酸的同源性均大于97%。构建了原核表达载体pET-32a( )-KIT,转化大肠杆菌DH5α,在异丙基硫代半乳糖苷诱导下表达KIT蛋白。结果表明:羊驼KIT基因在大肠杆菌中进行了高效特异性融合表达,融合蛋白分子量约为36 kD,目的蛋白约占菌体总蛋白的20%。     

Effect of Four Coat Color Mutations (Cr,S, SH,and h) on Brain Monoamine Oxidase in Mink

Activity of A and B types of monoamine oxidase (MAO) has been investigated in the brain stem and brain hemispheres of mink males of five genotypes for coat color mutations: standard dark-brown (+/+); heterozygous for the semidominant mutation Black crystal(Cr/+); homozygous for the semidominant mutation Black cross, or 95% White (S/S); heterozygous for the semidominant mutationShadow(S ^H/+); and homozygous for the semirecessive mutation hedlund white(h/h). The main changes in the activity of the A and B MAO types occur in the brain hemispheres. A reduced activity of MAO A has been recorded in the hemispheres of Black crystalminks (Cr/+) and an elevated activity, in the hemispheres of Shadow(S ^H/+) and 95% White(S/S). The activity of MAO B is reduced in the hemispheres of Black crystaland elevated in the hemispheres of hedlund white(h/h). An increased MAO A activity has also been recorded in the brain stem of Shadowminks (S ^H/+). It is suggested that genes controlling coat color have a pleiotropic effect on sexual behavior in males and the endocrine function of testicles mediated by a putative change in the metabolism of brain neurotransmitters, substrates of MAOs A and B.     

黑素皮质激素受体1（MC1R）基因与猪的毛色

猪的真黑色素与褐黑色素的合成量与分布主要受控于黑素皮质激素受体1基因。本文综述了该基因的定位、突变与多态检测,黑素皮质激素受体的作用机制,提出了对黑素皮质激素受体1基因进一步研究的看法。 Abstract：The amount and distribution of eumelanin and phaeomelanin are mainly controlled by Melanocortin Receptor 1 gene.The location、mutation and polymorphism testing of Melanocortin Receptor 1 gene and mechanism of Melanocortin Receptor 1 in pigs are discussed in the paper.The further research about the gene is also suggested.     

Recombinant Inbred Strain and Interspecific Backcross Analysis of Molecular Markers Flanking the Murine Agouti Coat Color Locus

Recombinant inbred strain and interspecific backcross mice were used to create a molecular genetic linkage map of the distal portion of mouse chromosome 2. The orientation and distance of the Ada, Emv-13, Emv-15, Hck-1, Il-1a, Pck-1, Psp, Src-1 and Svp-1 loci from the beta 2-microglobulin locus and the agouti locus were established. Our mapping results have provided the identification of molecular markers both proximal and distal to the agouti locus. The recombinants obtained provide valuable resources for determining the direction of chromosome walking experiments designed to clone sequences at the agouti locus. Comparisons between the mouse and human genome maps suggest that the human homolog of the agouti locus resides on human chromosome 20q. Three loci not present on mouse chromosome 2 were also identified and were provisionally named Psp-2, Hck-2 and Hck-3. The Psp-2 locus maps to mouse chromosome 14. The Hck-2 locus maps near the centromere of mouse chromosome 4 and may identify the Lyn locus. The Hck-3 locus maps near the distal end of mouse chromosome 4 and may identify the Lck locus.     

藏獒MC1R基因多态性与毛色表型的关联研究

目的:通过检测藏獒黑素皮质激素受体1(MC1R)基因的单链构象多态性(SSCP)在不同毛色群体中的分布,探讨MC1R基因多态性与毛色表型的相关性。方法:采用DNA测序技术,选择不同毛色藏獒的DNA为样本,根据GenBank发布的荷斯坦牛MC1R基因序列设计一对引物,采用PCR-SSCP技术分析MC1R基因在藏獒中的SSCP。结果:MC1R基因在藏獒中具有PCR-SSCP多态性,分别检测到3种基因型(AA、AB和BB);对MC1R基因多态性片段DNA克隆测序后发现,MC1R基因在编码区第313位存在单碱基突变(G→A),该突变导致第105位氨基酸发生由丙氨酸向苏氨酸的改变(T105A)。结论:MC1R基因的多态性与毛色性状不存在显著的相关性。     

猪显性白毛调控基因（KIT）的研究

猪的白毛色性状由显性基因KIT决定。本文从KIT基因的定位、突变分析、分子基础和作用机制等方面综述了对该基因的研究现状,叙述了KIT基因的研究意义。 Abstract：The dominant coat color in pigs is controlled by KIT gene.The current status of KIT gene is expressed in location、mutation、molecular basis and mechanism.Significance of KIT gene is also discussed in this paper.     

Dominant Red Coat Color in Holstein Cattle Is Associated with a Missense Mutation in the Coatomer Protein Complex,Subunit Alpha (COPA) Gene

Coat color in Holstein dairy cattle is primarily controlled by the melanocortin 1 receptor (MC1R) gene, a central determinant of black (eumelanin) vs. red/brown pheomelanin synthesis across animal species. The major MC1R alleles in Holsteins are Dominant Black (MC1R^D) and Recessive Red (MC1R^e). A novel form of dominant red coat color was first observed in an animal born in 1980. The mutation underlying this phenotype was named Dominant Red and is epistatic to the constitutively activated MC1R^D. Here we show that a missense mutation in the coatomer protein complex, subunit alpha (COPA), a gene with previously no known role in pigmentation synthesis, is completely associated with Dominant Red in Holstein dairy cattle. The mutation results in an arginine to cysteine substitution at an amino acid residue completely conserved across eukaryotes. Despite this high level of conservation we show that both heterozygotes and homozygotes are healthy and viable. Analysis of hair pigment composition shows that the Dominant Red phenotype is similar to the MC1R Recessive Red phenotype, although less effective at reducing eumelanin synthesis. RNA-seq data similarly show that Dominant Red animals achieve predominantly pheomelanin synthesis by downregulating genes normally required for eumelanin synthesis. COPA is a component of the coat protein I seven subunit complex that is involved with retrograde and cis-Golgi intracellular coated vesicle transport of both protein and RNA cargo. This suggests that Dominant Red may be caused by aberrant MC1R protein or mRNA trafficking within the highly compartmentalized melanocyte, mimicking the effect of the Recessive Red loss of function MC1R allele.     

Genetic and Molecular Analysis of the Soe1 Gene: A Trna(3)(glu) Missense Suppressor of Yeast Cdc8 Mutations

The CDC8 gene of Saccharomyces cerevisiae encodes deoxythymidylate (dTMP) kinase and is required for nuclear and mitochondrial DNA replication in both the mitotic and meiotic cell cycles. All cdc8 temperature-sensitive mutants are partially defective in meiotic and mitochondrial functions at the permissive temperature. In a study of revertants of temperature-sensitive cdc8 mutants, the SOE201 and SOE1 mutants were isolated. The SOE201 mutant is a disome of chromosome X to which the cdc8 gene maps. Using the chromosome X aneuploids to vary cdc8 gene dosage, we demonstrate that different levels of dTMP kinase activity are required for mitotic, meiotic or mitochondrial DNA replication. The SOE1 mutant contains a dominant suppressor that suppresses five different cdc8 alleles but does not suppress a complete cdc8 deletion. The SOE1 gene is located less than 1.5 cM from the CYH2 gene on chromosome VII and is adjacent to the TSM437-CYH2 region, with the gene order being SOE1-TSM437-CYH2. SOE1 is an inefficient suppressor that can neither suppress the cdc8 hypomorphic phenotype nor restore dTMP kinase activity in vitro. SOE1 is a single C to T mutation in the anticodon of a tRNA(3Glu) gene and thereby, produces a missense suppressor tRNA capable of recognizing AAA lysine codons. We propose that the resultant lysine to glutamate change stabilizes thermo-labile dTMP kinase molecules in the cell.     

Polymorphism of the Goat Agouti Signaling Protein Gene and Its Relationship with Coat Color in Italian and Spanish Breeds

Agouti signaling protein (ASIP) is one of the key players in the modulation of hair pigmentation in mammals. Binding to the melanocortin 1 receptor, ASIP induces the synthesis of phaeomelanin, associated with reddish brown, red, tan, and yellow coats. We have sequenced 2.8?kb of the goat ASIP gene in 48 individuals and identified two missense (Cys126Gly and Val128Gly) and two intronic polymorphisms. In silico analysis revealed that the Cys126Gly substitution may cause a structural change by disrupting a highly conserved disulfide bond. We studied its segregation in 12 Spanish and Italian goat breeds (N?=?360) with different pigmentation patterns and found striking differences in the frequency of the putative loss-of-function Gly(126) allele (Italian 0.43, Spanish Peninsular 0.08), but we did not observe a clear association with coat color. This suggests that the frequency of this putative loss-of-function allele has evolved under the influence of demographic rather than selection factors in goats from these two geographical areas.     

Structural Basis for the Disruption of the Cerebral Cavernous Malformations 2 (CCM2) Interaction with Krev Interaction Trapped 1 (KRIT1) by Disease-associated Mutations

Familial cerebral cavernous malformations (CCMs) are predominantly neurovascular lesions and are associated with mutations within the KRIT1, CCM2, and PDCD10 genes. The protein products of KRIT1 and CCM2 (Krev interaction trapped 1 (KRIT1) and cerebral cavernous malformations 2 (CCM2), respectively) directly interact with each other. Disease-associated mutations in KRIT1 and CCM2 mostly result in loss of their protein products, although rare missense point mutations can also occur. From gene sequencing of patients known or suspected to have one or more CCMs, we discover a series of missense point mutations in KRIT1 and CCM2 that result in missense mutations in the CCM2 and KRIT1 proteins. To place these mutations in the context of the molecular level interactions of CCM2 and KRIT1, we map the interaction of KRIT1 and CCM2 and find that the CCM2 phosphotyrosine binding (PTB) domain displays a preference toward the third of the three KRIT1 NPX(Y/F) motifs. We determine the 2.75 Å co-crystal structure of the CCM2 PTB domain with a peptide corresponding to KRIT1^NPX(Y/F)3, revealing a Dab-like PTB fold for CCM2 and its interaction with KRIT1^NPX(Y/F)3. We find that several disease-associated missense mutations in CCM2 have the potential to interrupt the KRIT1-CCM2 interaction by destabilizing the CCM2 PTB domain and that a KRIT1 mutation also disrupts this interaction. We therefore provide new insights into the architecture of CCM2 and how the CCM complex is disrupted in CCM disease.