ENU诱导获得一种短尾小鼠及其突变基因的初步定位

用一种化学诱变剂ENU(乙酰基亚硝基脲 )腹腔注射 3 0只 8～ 1 0周龄C5 7BL 6J(简称B6)雄鼠 (G0代 ) ,6周后与同品系正常母鼠配种繁殖后代 (G1代 )小鼠 3 5 1只。对其后代进行筛选获得一种可遗传的显性短尾突变小鼠。为了定位该突变基因 ,运用平均分布于B6和DBA 2 (简称D2 )小鼠常染色体而在这两者间又有差异的 3 9个微卫星对突变小鼠的 (D2×B6)F1代短尾突变小鼠回交D2得到的有短尾表型的[(B6×D2 )F1×D2 ]F2 代小鼠进行基因组扫描。反向运用经典的位置候选基因法 ,将短尾突变基因定位于 1 7号染色体 ,与D1 7Mit3 3的LOD值为 9 0 8。选用该染色体上与短尾表型相关基因Brachyury (T)最近的微卫星D1 7Mit1 43引物扩增 ,在 1 0 9只F2 代短尾小鼠中未发生一例交换 ,表明Brachyury基因是本例短尾突变强有力的候选基因。     

两种白斑小鼠突变基因的染色体定位

以本中心ENU诱变获得的两种白斑突变小鼠W-4Bao与Kitl-1Bao为研究对象[均为C57BL/6J(B6)背景],遗传试验表明它们都为单基因显性遗传,W-4Bao及Kitl-1Bao突变基因纯合子小鼠的表型分别为全白色及“黑头白”;将白斑杂合子小鼠与DBA/2(D2)交配获得具有白斑表型的F1小鼠,F1小鼠再回交D2繁殖[(B6×D2)F1×D2]F2小鼠,利用微卫星标记对F2代小鼠进行连锁分析。结果发现W-4Bao与微卫星D5Mit356、D5Mit308之间的LOD值分别为56.82、51.50,从而把该突变基因定位于第5号染色体D5Mit356与D5Mit308之间;Kitl-1Bao与微卫星D10Mit70、D10Mit68之间的LOD值分别为27.37、21.20,从而把该突变基因定位于第10号染色体上D10Mit70与D10Mit68之间。经过检索小鼠基因组数据库确认它们的候选基因分别为kit及kitl。     

家蚕非滞育红卵突变体Re-nd突变基因的定位克隆

【目的】家蚕Bombyx mori非滞育红卵突变体Re-nd是唯一在非滞育状态下卵色呈现鲜红色的突变品种。本研究通过基因连锁分析和定位克隆的方法确定Re-nd的突变基因所在的染色体及紧密连锁位置,为后续Re-nd的功能研究及应用奠定基础。【方法】以家蚕卵色突变体Re-nd和野生型大造进行杂交,配制基因连锁分析群体材料和定位克隆群体材料;针对家蚕全染色体进行SNP标记开发,利用BC₁代群体材料进行基因连锁分析,确定Re-nd的突变基因所在的染色体;针对定位的Re nd的突变基因所在染色体进行SNP标记开发,利用BC₁群体材料对Re-nd的突变基因进行定位克隆。【结果】基因连锁分析结果显示Re-nd的突变表型与第6号染色体上的SNP标记完全连锁;初步定位克隆结果显示Re-nd的突变基因位于SNP标记SNP7和SNP17之间,物理距离4.04 Mb;以SNP7和SNP17之间筛选出的6个SNP标记和25个重组个体进行精细定位克隆,结果显示Re-nd的突变基因所在的区域位于SNP10和SNP12两个SNP标记之间的nscaf2853上,物理距离949.3 kb左右。【结论】将Re-nd的突变基因定位于第6号染色体的2个SNP标记SNP10和SNP12之间,物理距离约949.3 kb。本研究为后续Re-nd突变基因的精细定位及功能应用研究奠定了基础。     

snthr-1Bao稀毛小鼠突变基因的精确定位及克隆鉴定

snthr^-1Bao稀毛小鼠是本实验室培育的呈单基因隐性遗传的突变系小鼠,突变基因已被初步定位于第9号染色体末端;为了精确定位并鉴定snthr^-1Bao稀毛小鼠的突变基因,将(C57BL/6J×snthr^-1Bao)F₁代互交繁殖F₂代小鼠4 400余只,其中稀毛小鼠1 100只,并在2个微卫星、35个可能的简单序列重复标记（simple sequence repeat,SSR）及3个酶切扩增多态性序列（c1eaved amplified polymorphic sequences,CAPS）标记中找到4个合适的基因组标记。利用这些标记及F₂代稀毛小鼠将突变基因精确定位到第9号染色体距着丝粒117.763 kb及119.129 kb之间1.367 Mb的范围内,在其间的21个基因中确定Plcd1为稀毛突变的强力候选基因。通过对基因组的直接测序,发现snthr^-1Bao稀毛小鼠基因组上有一个14 883 bp的缺失,这一缺失包含了Plcd1基因的4—15号外显子及Vill基因的10—19号外显子。推测极可能是Plcd1基因缺失导致snthr^-1Bao小鼠出现稀毛表型。     

ENU诱变获得一例巨结肠症小鼠及其突变基因的染色体定位

采用化学诱变剂乙酰基亚硝基脲(N-ethyl-N-nitrosourea,ENU)获得一种可遗传的腹部白斑突变杂合子小鼠,将该杂合子小鼠互交后获得具有花斑表型的突变纯合子小鼠,进一步研究表明突变纯合子小鼠表现为严重的巨结肠表型。肠全标本乙酰胆碱酯酶组织化学染色显示突变纯合子小鼠巨结肠段神经节细胞缺失。为定位该基因,利用微卫星标记(B6×D2)对F1互交获得的F2突变纯合子小鼠进行基因组扫描,初步将该突变基因定位于小鼠第14号染色体。     

腹侧黄斑小鼠的部分特征及其突变基因的染色体定位

腹侧黄斑小鼠(VYSlac)是在B6小鼠繁殖生产过程中被发现、分离的突变系小鼠,呈单基因显性遗传,其头颈及躯干的腹侧为黄色。VYSlac腹部表皮多巴(+)黑色素细胞及毛囊内黑色素较其背景品系B6少;腹部毛发颜色浅黄、多数无黑色素沉积,但结构正常。通过微卫星标记与48只F2小鼠(VYSlacD2F1回交D2)的连锁分析发现,突变基因与D2Mit229间的LOD值为5.79,确定连锁。随后,在突变基因附近反复多次筛选新的微卫星或SNP标记,通过对196例F2小鼠的多次连锁分析,将突变基因所在区域缩小到rs13476833(距着丝粒149804749bp)与rs27310903(距着丝粒155060764bp)间约5256015bp的范围内。     

ENU诱变获得一种多趾小鼠及其突变基因的鉴定

采用化学诱变剂乙酰基亚硝基脲(N-ethyl-N-nitrosourea,ENU)获得一种常染色体显性遗传多趾突变小鼠(Mus musculus),该突变小鼠在后趾内侧(即轴前部)多出一个脚趾,且严重程度不一,部分小鼠双侧后足都有多趾表型。阿尔新蓝-茜素红染色结果表明,多趾突变杂合子小鼠除多趾异常发育外,其余骨骼无明显异常。为定位该突变基因,利用微卫星标记对(C57BL/6J×DBA/2J)F1代多趾突变小鼠回交C57BL/6J得到的[(C57BL/6J×DBA/2J)F1×C57BL/6J]N2代多趾小鼠进行全基因组扫描,最终将本例多趾突变基因定位于小鼠第2号染色体微卫星D2mit45与D2mit184之间,并初步确定Alx4为该突变候选基因。在此基础上对Alx4进行测序分析,测序结果发现突变小鼠Alx4基因编码区第433位碱基处发生A到T的颠换,导致编码区第145位密码子AAA(编码赖氨酸)变为终止密码子TAA,引起蛋白编码提前终止,是引起多趾表型的原因。     

家蚕油蚕oc突变体突变基因的精细定位

【目的】油蚕oc突变体是家蚕Bombyx mori油蚕突变体的一种,经典遗传学连锁图谱已经将oc突变基因定位在5号染色体40.8 c M座位。本研究旨在对oc突变体候选基因进行精细定位并克隆,探究oc性状形成的分子机制。【方法】以油蚕oc突变品系和野生型家蚕品系大造(Dz)为亲本,其杂交产生的F1代雄性个体与oc突变的雌性个体进行回交得到的1 397头BC_1代个体为定位材料,以家蚕已经报道的基因组序列为参考设计markers,通过亲本及F1代个体筛选多态性markers,并利用多态性markers和BC_1代个体对oc突变基因进行精细定位。通过半定量RT-PCR和实时荧光定量PCR(q PCR)筛选oc紧密连锁区间内的候选基因,确定目标候选基因,继而克隆和测序该基因,分析油蚕oc突变的原因。【结果】利用1 397头BC_1代个体和11对有效的多态性markers将oc突变基因定位在M10与M11两个markers之间,物理图谱距离大约为234 kb。通过家蚕基因组数据库对oc连锁区域内的基因进行检索发现该区域有5个预测基因。对这5个预测基因在10个家蚕品系中进行的表达分析发现,只有BGIBMGA003572基因在oc突变个体体壁的表达量明显比正常个体中的低。通过基因的同源分析发现该基因编码的蛋白和人类单羧酸转运蛋白9(可能的尿酸转运蛋白)是同源蛋白,推测其为oc突变的候选基因。对BGIBMGA003572进行的克隆和测序结果显示其编码序列有5个氨基酸在oc突变体中发生了突变。【结论】通过定位克隆,本研究将oc突变基因定位在了234 kb的紧密连锁区间,其中编码单羧酸转运蛋白9的BGIBMGA003572可能和oc突变体的表型有关。     

两例新的稀毛小鼠突变基因的染色体定位

用连锁分析法对乙烷基亚硝基脲(ENU) 诱变获得的两例被毛突变小鼠(snthr 1Bao及snthr 2Bao) 的突变基因进行定位。选择平均分布于小鼠基因组且在C57BL/6J和DBA/2 间有差异的39 个微卫星对B6D2F1 互交得到的稀毛F2 进行全基因组扫描。扫描了9个微卫星后发现snthr 1Bao突变基因与D9Mit243 的LOD值为7 73。突变基因被定位于9号染色体。在此基础上又选择了D9Mit355 和D9Mit18 两个微卫星进行检测, 并扩大F2 的数量至145只。结果发现, snthr 1Bao与D9Mit18间无1 例重组, 稀毛突变基因与该微卫星紧密连锁, 距着丝点71cM。同理, 将snthr 2Bao突变基因也定位在与snthr 1Bao相近的区域。检索发现snthr 1Bao是一尚未克隆的新基因。     

应用RFLP标记分析水稻株高与分蘖的遗传相关性

供试材料为高杆少分蘖梗稻品种Palawan与半矮杆籼稻品种IR42杂交F₂代.F₂株高与分蘖数呈正态分布.株高与分蘖数呈显著(P<0.01)负相关.104个分布于12条染色体的RFLP标记基因型之间表型平均值正交比较和分子标记区间作图分析结果表明,染色体1半矮杆基因位点sd-1附近有隐性加性效应,部分显性效应,和超显性效应的株高数量性状位点(QTLs).与其连锁的分子标记顺序为RG690-RZ730-RG381-RG801.另一个影响株高的显性加性QTL位于染色体2RZ166-RG157之间.影响分蘖数两个加性显性QTLs位于染色体4RG91-RZ656之间和染色体12RG457-RG241A之间.RG801与RG264(染色体6)位点之间具有显著(P<0.001)的加显与显加交互效应.     

Identification and genetic mapping for <Emphasis Type="Italic">rht-DM</Emphasis>, a dominant dwarfing gene in mutant semi-dwarf maize using QTL-seq approach

Semi-dwarfism is an agronomically important trait in breeding for stable high yields and for resistance to damage by wind and rain (lodging resistance). Many QTLs and genes causing dwarf phenotype have been found in maize. However, because of the yield loss associated with these QTLs and genes, they have been difficult to use in breeding for dwarf stature in maize. Therefore, it is important to find the new dwarfing genes or materials without undesirable characters. The objectives of this study were: (1) to figure out the inheritance of semi-dwarfism in mutants; (2) mapping dwarfing gene or QTL. Maize inbred lines ‘18599’ and ‘DM173’, which is the dwarf mutant derived from the maize inbred line ‘173’ through ⁶⁰Co-γ ray irradiation. F₂ and BC₁F₁ population were used for genetic analysis. Whole genome resequencing-based technology (QTL-seq) were performed to map dwarfing gene and figured out the SNP markers in predicted region using dwarf bulk and tall bulk from F₂ population. Based on the polymorphic SNP markers from QTL-seq, we were fine-mapping the dwarfing gene using F₂ population. In F₂ population, 398 were dwarf plants and 135 were tall plants. Results of χ² tests indicated that the ratio of dwarf plants to tall plants was fitted to 3:1 ratio. Furthermore, the χ² tests of BC₁F₁ population showed that the ratio was fitted to 1:1 ratio. Based on QTL-seq, the dwarfing gene was located at the region from 111.07 to 124.56 Mb of chromosome 9, and we named it rht-DM. Using traditional QTL mapping with SNP markers, the rht-DM was narrowed down to 400 kb region between SNP-21 and SNP-24. The two SNPs were located at 0.43 and 0.11 cM. Segregation analysis of F₂ and BC₁F₁ indicated that the dwarfing gene was likely a dominant gene. This dwarfing gene was located in the region between 115.02 and 115.42 Mb on chromosome 9.     

Comparison of linkage maps from F2 and three times intermated generations in two populations of European flint maize (Zea mays L.)

Intermated mapping populations are expected to result in high mapping resolution for tightly linked loci. The objectives of our study were to (1) investigate the consequences of constructing linkage maps from intermated populations using mapping methods developed for F₂ populations, (2) compare linkage maps constructed from intermated populations (F₂Syn3) with maps generated from corresponding F₂ and F₃ base populations, and (3) investigate the advantages of intermated mapping populations for applications in plant breeding programs. We constructed linkage maps for two European flint maize populations (A × B, C × D) by mapping 105 SSR markers in generations F₂ and F₂Syn3 of population A × B, and 102 SSR markers in generations F₃ and F₂Syn3 of population C × D. Maps for F₂Syn3 were constructed with mapping methods for F₂ populations (Map A) as well as with those specifically developed for intermated populations (Map B). Both methods relate map distances to recombination frequencies in a single meiosis and, therefore, did not show a map expansion in F₂Syn3 compared with maps constructed from the respective F₂ or F₃ base populations. Map A and B differed considerably, presumably because of theoretical shortcomings of Map A. Since loosely linked markers could not unambiguously be mapped in the F₂Syn3 populations, they may hamper the construction of linkage maps from intermated populations.     

Genetic Analysis and Molecular Tagging on a Novel Excessive Tillering Mutant in Rice

A rice (Oryza sativa L.) mutant with an excessive tiller number, designated ext-M1B, was found in the F₂ progenies generated from the cross between M1B and GMS-1 (a genetic male sterile), whose number of tillers was 121. The excessive tillering mutant also resulted in significant changes in plant height, flag leaf, stem, filled grains per panicle, and productive panicles per plant. The inbreeding progenies of ext-M1B exhibited the same mutant phenotype. The crosses from ext-M1B/M1B, M1B/ext-M1B, 2480B/ext-M1B, D62B/ext-M1B, G46B/ext-M1B, and G683B/ext-M1B expressed normal tillering in F₁, and segregated into two different phenotypes of normal tillering type and excessive tillering type in a ratio of 3:1 in F₂. Inheritance analysis indicated that the excessive tillering character was controlled by a single recessive nucleic gene. By BSA (bulked segregants analysis) and microsatellite makers with the F₂ population of 2480B/ext-M1B as the mapping population, RM197, RM584, and RM225, all of which were located on the short arm of rice chromosome 6, were identified to be linked with the excessive tillering gene with genetic distance of 3.8 cM, 5.1 cM, and 5.2 cM, respectively. This gene is probably a new excessive tillering gene in rice and is designated tentatively ext-M1B (t).     

Intersubspecific subcongenic mouse strain analysis reveals closely linked QTLs with opposite effects on body weight

A previous genome-wide QTL study revealed many QTLs affecting postnatal body weight and growth in an intersubspecific backcross mouse population between the C57BL/6J (B6) strain and wild Mus musculus castaneus mice captured in the Philippines. Subsequently, several closely linked QTLs for body composition traits were revealed in an F₂ intercross population between B6 and B6.Cg-Pbwg1, a congenic strain on the B6 genetic background carrying the growth QTL Pbwg1 on proximal chromosome 2. However, no QTL affecting body weight has been duplicated in the F₂ population, except for mapping an overdominant QTL that causes heterosis of body weight. In this study, we developed 17 intersubspecific subcongenic strains with overlapping and nonoverlapping castaneus regions from the B6.Cg-Pbwg1 congenic strain in order to search for and genetically dissect QTLs affecting body weight into distinct closely linked loci. Phenotypic comparisons of several developed subcongenic strains with the B6 strain revealed that two closely linked but distinct QTLs that regulate body weight, named Pbwg1.11 and Pbwg1.12, are located on an 8.9-Mb region between D2Mit270 and D2Mit472 and on the next 3.6-Mb region between D2Mit205 and D2Mit182, respectively. Further analyses using F₂ segregating populations obtained from intercrosses between B6 and each of the two selected subcongenic strains confirmed the presence of these two body weight QTLs. Pbwg1.11 had an additive effect on body weight at 6, 10, and 13?weeks of age, and its castaneus allele decreased it. In contrast, the castaneus allele at Pbwg1.12 acted in a dominant fashion and surprisingly increased body weight at 6, 10, and 13?weeks of age despite the body weight of wild castaneus mice being 60% of that of B6 mice. These findings illustrate the complex genetic nature of body weight regulation and support the importance of subcongenic mouse analysis to dissect closely linked loci.     

Genetic characterization of the 44D-45B region of the Drosophila melanogaster genome based on an F2 lethal screen

We have performed an F₂ genetic screen to identify lethal mutations that map to the 44D-45B region of the Drosophila melanogaster genome. By screening 8500 mutagenized chromosomes for lethality over Df(2R)Np3, a deficiency which encompasses nearly 1% of the D. melanogaster euchromatic genome, we recovered 125 lines with lethal mutations that represent 38 complementation groups. The lethal mutations have been mapped to deficiencies that span the 44D-45B region, producing an approximate map position for each complementation group. Lethal mutations were analyzed to determine the phase of development at which lethality occurred. In addition, we have linked some of the complementation groups to P element-induced lethals that map to 44D-45B, thus possibly providing new alleles of a previously tagged gene. Some of the complementation groups represent potentially novel alleles of previously identified genes that map to the region. Several genes have been mapped by molecular means to the 44D-45B region, but do not have any reported mutant alleles. This screen may have uncovered mutant alleles of these genes. The results of complementation tests with previously identified genes in 44D-45B suggests that over half of the complementation groups identified in this screen may be novel. Received: 13 July 1999 / Accepted: 4 November 1999     

Localization to chromosome 10 of a locus influencing morphine analgesia in crosses derived from C57BL/ and DBA/2 strains

A quantitative trait locus (QTL) was detected and mapped to proximal chromosome 10 near the markers Mpmv5 and D10Mit51 with a strong influence on morphine-induced analgesia in the BXD recombinant inbred (Rl) strains and in an F₂ cross (B6D2F2) between the BXD progenitor strains, C57BL/6 and DBA/2. A LOD score of 3.9 (p <. 00002) was seen for analgesia using the hot plate assay. Naloxone Bmax was also associated with this chromosome region in BXD RI mice. The mu opioid receptor gene (Oprm) has recently been mapped to this same chromosome region. The observation that several morphine-related traits and naloxone Bmax appear to be partly determined by this presumed single locus is consistent with the hypothesis that the mu opioid receptor gene, or one of its modulators, is the basis for the QTL.     

A genome-wide association analysis for susceptibility of pigs to enterotoxigenic Escherichia coli F41

Enterotoxigenic Escherichia coli (ETEC) is a type of pathogenic bacteria that cause diarrhea in piglets through colonizing pig small intestine epithelial cells by their surface fimbriae. Different fimbriae type of ETEC including F4, F18, K99 and F41 have been isolated from diarrheal pigs. In this study, we performed a genome-wide association study to map the loci associated with the susceptibility of pigs to ETEC F41 using 39454 single nucleotide polymorphisms (SNPs) in 667 F₂ pigs from a White Duroc×Erhualian F₂ cross. The most significant SNP (ALGA0022658, P=5.59×10⁻¹³) located at 6.95 Mb on chromosome 4. ALGA0022658 was in high linkage disequilibrium (r²>0.5) with surrounding SNPs that span a 1.21 Mb interval. Within this 1.21 Mb region, we investigated ZFAT as a positional candidate gene. We re-sequenced cDNA of ZFAT in four pigs with different susceptibility phenotypes, and identified seven coding variants. We genotyped these seven variants in 287 unrelated pigs from 15 diverse breeds that were measured with ETEC F41 susceptibility phenotype. Five variants showed nominal significant association (P<0.05) with ETEC F41 susceptibility phenotype in International commercial pigs. This study provided refined region associated with susceptibility of pigs to ETEC F41 than that reported previously. Further works are needed to uncover the underlying causal mutation(s).     

Genetic Analysis of Aspartate Aminotransferase Isozymes from Hybrids between DROSOPHILA MELANOGASTER and DROSOPHILA SIMULANS and Mutagen-Induced Isozyme Variants

The aspartate aminotransferases (designated GOT1 and GOT2) are two enzymes of Drosophila melanogaster for which naturally occurring electrophoretic variants were not found. There is an electrophoretic difference between D. melanogaster and D. simulans. Since the F ₁ hybrid offspring of these species are sterile, a genetic analysis of the ordinary type cannot be done on differences between the two species. A method was devised to make "partial hybrids" in which one chromosome arm is homozygous for melanogaster genes in an otherwise hybrid background. By using this method, Got1 was localized to 2R and Got2 to 2L. Once a gene can be assigned to a chromosome, it may be followed in crossing schemes and mutations from mutagen treatments may be looked for. At the locus of Got1 a mutation with low activity was recovered and designated Got1^lo. It was located at a genetic map position of 75 on 2R. A Got2 mutant with a greater migration to the anode was recovered and designated Got2 ^J. It was located at a genetic map position of 3.0, and in the salivary chromosome was between 22B1 and 22B4 inclusive.     

Impact of diet and genes on murine autoimmune pancreatitis

The impact of environmental factors, such as diet, and the genetic basis of autoimmune pancreatitis (AIP) are largely unknown. Here, we used an experimental murine AIP model to identify the contribution of diet to AIP development, as well as to fine‐map AIP‐associated genes in outbred mice prone to develop the disease. For this purpose, we fed mice of an autoimmune‐prone intercross line (AIL) three different diets (control, calorie‐reduced and western diet) for 6 months, at which point the mice were genotyped and phenotyped for AIP. Overall, 269 out of 734 mice (36.6%) developed AIP with signs of parenchymal destruction, equally affecting mice of both sexes. AIP prevalence and severity were reduced by approximately 50% in mice held under caloric restriction compared to those fed control or western diet. We identified a quantitative trait locus (QTL) on chromosome 4 to be associated with AIP, which is located within a previously reported QTL. This association does not change when considering diet or sex as an additional variable for the mapping. Using whole‐genome sequences of the AIL founder strains, we resolved this QTL to a single candidate gene, namely Map3k7. Expression of Map3k7 was largely restricted to islet cells as well as lymphocytes found in the exocrine pancreas of mice with AIP. Our studies suggest a major impact of diet on AIP. Furthermore, we identify Map3k7 as a novel susceptibility gene for experimental AIP. Both findings warrant clinical translation.