乙烷基亚硝基脲诱变获得两例新的被毛突变小鼠

采用乙烷基亚硝基脲 (Ethylnitrosourea ,ENU)诱变获得人类疾病的小鼠模型。用 1 0 0mg/KgENU腹腔注射 1 8只 8- 1 0周龄的雄性DBA小鼠 (G0 ) ,每周一次共三次 ;将在后代小鼠 (G1 )筛查到的突变个体与同品系配种 ,若异常表型传代则可能为显性突变 ;选择表型正常的G1 雄鼠与C5 7BL/ 6配种得F1 ,将F1 随机互交得到F2 ,依据F2 是否有突变鼠出现确定可能存在的隐性突变。结果表明 ,在 35 2只G1 小鼠中 ,1 4只出现异常表型 ,但均未传代 ;对 30只G1 雄鼠的隐性遗传试验获得 2只稀毛突变小鼠 ,均表现为被毛稀疏、幼鼠生长缓慢     

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。     

SNP标记对角膜混浊小鼠 突变相关基因的精细定位

为深入研究前期工作中以ENU诱变技术建立的遗传性角膜混浊突变系小鼠(B6-Co)的遗传机制, 利用 SNP标记对其突变基因进行精细定位, 将该品系中具有角膜混浊表型的小鼠(B6-CoP)与DBA/2小鼠(简称D2)配种得到F₁代, 再回交D2亲本品系得到F₂代, 提取F₂代角膜混浊小鼠鼠尾DNA。在MGI数据库中选取小鼠13号染色体已定位区间附近5个在C57BL/6(简称B6)和D2两个品系之间有差异的SNP, 应用聚合酶链反应-限制性片段长度多态性(PCR-RFLP)技术及连锁分析方法对B6-Co小鼠突变基因进行精细定位。结果表明: B6-Co小鼠突变基因定位于13号染色体上112 546 283~113 397 654 bp之间, 因该区间内有5个已知基因, 其中Map3k1基因与小鼠眼睛形态生成和眼睑闭合密切相关, 提示Map3k1是B6-Co小鼠突变的强力候选基因。     

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。     

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。     

乙酰基亚硝基脲(ENU)对C57BL/6J雄鼠睾丸组织的影响

目的 观察乙酰基亚硝基脲(ENU)对雄鼠睾丸及其他组织器官的影响,分析引起小鼠死亡的原因,探索ENU处理雄鼠后的最佳配种时间.方法 将8～10周龄的C57BL/6J雄鼠分为实验组和对照组.实验组腹腔注射ENU 100 mg/kg,每周1次,共3次,对照组以同样方法注射生理盐水.首次注射ENU后的第1周至12周,每周分别取4只实验组小鼠和对照组小鼠剖检及组织病理学观察;取其睾丸附睾称重及精子计数.记录死亡小鼠数量,并对其剖检及组织病理学观察.结果 对死亡小鼠剖检发现胸腔纵隔内有巨大肿块,明显压迫心脏;组织切片观察发现睾丸和肝脏有明显病变.实验组小鼠睾丸从ENU处理的第2周起开始萎缩,第9周开始恢复;精子数量第4周至第9周稀少.结论 ENU为小鼠的一种强诱变剂,纵隔肿瘤是导致雄鼠死亡的主要原因,雄鼠注射ENU后最佳配种时间应在首次注射后的第9周.     

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。     

花生EMS诱变后代的农艺性状与品质分析

为了研究花生EMS诱变后代的变化趋势,以期得到有益变异和创造新的花生种质,本研究以2个花生品系花U416、花U606为供试诱变亲本,利用0(CK)、0.5%、1.0%、1.5%、2.0%5个EMS浓度直接注入花生花器得到诱变后代,分析M1、M2的农艺性状与品质变化,结果表明,EMS对2个花生品系诱变效应明显,2个品系畸变率随EMS浓度增加而增大;EMS注入的当代植株结实率和M1的出苗率均低于对照,2个品系M2均产生了多种类型的突变植株,突变性状大部分可以稳定遗传。而这些遗传多样性的突变材料,为花生种质创新及品种遗传改良提供基础性材料。     

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。     

斑马鱼消化器官发育缺陷突变体的遗传筛选

目的正向遗传筛选斑马鱼肝脏、肠和胆囊发育缺陷突变体。方法 ENU诱变野生型斑马鱼并开展经典的F2代筛选,以lfabp为探针的全胚原位杂交、BES-H2O2-Ac荧光染料分别检测斑马鱼早期胚胎肝脏、肠和胆囊的表型。结果在128个突变基因组中筛选获得了源自14个F2家族的斑马鱼消化器官发育缺陷突变体品系23个,并按表型划分为6类。结论斑马鱼肝脏、肠和胆囊的发育调控机制有相似性和差异性。     

The induction of forward and reverse specific-locus mutations and dominant cataract mutations in spermatogonia of treated strain DBA/2 mice by ethylnitrosourea

The mutagenic effectiveness of ethylnitrosurea (ENU) was assessed in treated spermatogonia of DBA/2 mice. In a total of 17,515 offspring examined following 160 mg ENU/kg body weight treatment of parental males, 26 forward specific-locus mutations, 2 reverse specific-locus mutations and 9 dominant cataract mutations were recovered. ENU increased the mutation rate to all 3 genetic endpoints. However, ENU was less effective in treated DBA/2 mice than in the standard experimental protocol employing treated hybrid (102 X C3H)F1 male mice. This observed difference for a direct-acting mutagen such as ENU may result from differences in the detoxification of ENU or from differences in the DNA-repair capabilities of strain DBA/2. The first documented reverse mutation of the b allele is reported. The reversion was shown to be due to an AT to GC transition. To date, in addition to the reverse mutation of the b allele, 5 independent ENU-induced mutations recovered in germ cells of the mouse have been molecularly characterized and all have been shown to be base substitutions at an AT site. This is in contrast to the expected mechanism of ENU mutation induction due to O6-ethylguanine adduct formation which results in a GC to AT base-pair substitution and emphasizes the complexities of mutagenesis in germ cells of mammals.     

Reduced sensitivity to and ras mutation spectrum of N-ethyl-N-nitrosourea-induced thymic lymphomas in adult C.B-17 scid mice

Scid mice are defective in the ability to repair DNA double strand breaks and, as a consequence, their cells are radiosensitive. Further, they have been shown to be prone to develop thymic lymphomas (TLs) after small doses of ionizing radiation. Little is known, however, on the role of scid mutation in chemical carcinogenesis. To determine if scid mutation increased predisposition to chemical carcinogenesis, we examined both the susceptibility of scid mice to N-ethyl-N-nitrosourea (ENU)-induced lymphomagenesis and the involvement of ras gene activation. Adult female mice at 8 weeks of age were given ENU in their drinking water at 400 ppm for 2-10 weeks. Contrary to expectations, we observed a two to three-fold reduction in TL development in the scid mice. The highest incidence was achieved by ENU treatment for 8 weeks for scid and wild-type C.B-17 mice, of 42 and 85%, respectively (P<0.05). We investigated whether this was attributable to the usage of the ras mutation pathway. There was, however, no significant difference in the frequency and spectrum of K-ras mutation between the scid and wild-type C.B-17 mice. Most of the K-ras mutations were either GGT to GAT transition in codon 12 (11/23: 48%) or CAA to CCA transversion in codon 61 (8/23: 35%) that was independent of scid background. The incidence of N-ras mutation was very low. These results indicate that scid mice are less susceptible to ENU-induced lymphomagenesis and ras gene mutation frequently occurs in both scid and wild-type C.B-17 mice.     

An examination of respiratory distress and chromosomal abnormalities in the offspring of male mice treated with ethylnitrosourea

A functional defect (respiratory distress), in addition to morphological defects, was induced in the offspring of male ICR mice treated with ethylnitrosourea (ENU) before mating. ENU (100 and 50 micrograms/g) was injected intraperitoneally into adult male ICR mice that were then mated with untreated females. After the cesarian operation on the 18th day of gestation, fetuses were resuscitated. In the apneic fetuses showing respiratory distress, the lung was collapsed and the ductus arteriosus was not closed. The incidence of fetuses showing respiratory distress was significantly increased with the high dose (100 micrograms/g) of ENU, and it was higher after spermatogonial exposure than after postmeiotic exposure. There was no linearity in the dose-response relationship at the lower dose (50 micrograms/g), as was the case with the specific-locus mutation. The frequency per microgram ENU of fetuses showing respiratory distress was 3.7 X 10(-4) for spermatogonial treatment (calculated at a dose of 100 micrograms/g), the value being about 10-20 times higher than that of ordinary mutations in mice. About half of the fetuses showing respiratory distress often had specific anomalies (dwarfism and gigantic thymus), but the remainder showed no morphological changes. Spermatogonial treatment produced a zero or very low incidence of translocations in the meiotic configurations of primary spermatocytes. G-band analysis of the affected F1 fetuses also revealed no visible chromosomal abnormalities (there could be small deletions or inversions) except that trisomy 19 was found in a dwarf fetus.     

Induction of specific-locus mutations in female mice by 1-ethyl-1-nitrosourea and procarbazine

Using the specific-locus method, the ability of 1-ethyl-1-nitrosourea (ENU) and procarbazine hydrochloride (procarbazine) to induce gene mutations in mouse oocytes was tested and confirmed. The sensitive stage for the induction of mutations in oocytes with 160 mg/kg of ENU is 2-4 weeks post treatment. The induced mutation frequency in this mating interval was 5.1 X 10(-7) mutations/locus/gamete/mg/kg. The induction of mutations by procarbazine occurred 8-33 weeks after treatment. The induced mutation frequency in this mating interval for the 400 mg/kg group was 0.4 X 10(-7) mutations/locus/gamete/mg/kg. One third of the induced mutations was lethal in homozygous condition in both experiments. ENU and procarbazine have a lower mutational response in oocytes than in stem-cell spermatogonia.     

Towards an understanding of the nature and fitness of induced mutations in germ cells of mice: homozygous viability and heterozygous fitness effects of induced specific-locus, dominant cataract and enzyme-activity mutations

A total of 219 specific-locus, 35 dominant cataract and 44 enzyme-activity mutations induced in spermatogonia of mice by radiation or ethylnitrosourea (ENU) treatment were characterized for homozygous viability as well as fitness effects on heterozygous carriers. For all 3 genetic endpoints, the frequency of homozygous lethal mutations was higher in the group of radiation-induced mutations than in the ENU-treatment group. These observations are consistent with the hypothesis that radiation-induced mutations recovered in the mouse are mainly due to small deletions while ENU induces mainly intragenic mutations. The overall fitness of mutant heterozygotes was reduced for the group of radiation-induced specific-locus, dominant cataract and enzyme-activity mutations while the ENU-induced mutations exhibited no reduction in fitness. The fitness reduction of heterozygous carriers for a newly occurring mutation in a population is important in determining the persistence of the mutation in a population, and thus the total number of individuals affected before a mutation is eventually eliminated from the population. For the present results a maximal persistence of 12 generations and a minimal persistence of 3 generations is estimated. These results are consistent with the 6-7-generation persistence time assumed by UNSCEAR (1982) in an estimate of the overall effects of radiation-induced mutations in man.     

A phenotype-driven ENU mutagenesis screen for the identification of dominant mutations involved in alcohol consumption

The aim of this study was the application of a phenotype-driven N-ethyl-N-nitrosourea (ENU) mutagenesis screen in mice for the identification of dominant mutations involved in the regulation and modulation of alcohol-drinking behavior. The chemical mutagen ENU was utilized in the generation of 131 male ENU-mutant C57BL/6J mice (G0). These ENU-treated mice were paired with wild-type C57BL/6J mice to generate G1 and subsequent generations. In total, 3327 mice were generated. Starting with G1, mice were screened for voluntary oral self-administration of 10% (v/v) alcohol vs. water in a two-bottle paradigm. From these mice, after a total period of 5 weeks of drinking, 43 mutants fulfilled the criteria of an “alcohol phenotype,” that is, high or low ethanol intake. They were then selected for breeding and tested in a “confirmation cross” (G2–G4) for inheritance. Although we did not establish stable high or low drinking lines, several results were obtained in the context of alcohol consumption. First, female mice drank more alcohol than their male counterparts. Second, the former demonstrated greater infertility. Third, all animals displayed relatively stable alcohol intake, although significantly different in two different laboratories. Finally, seasonal and monthly variability was observed, with the highest alcohol consumption occurring in spring and the lowest in autumn. In conclusion, it seems difficult to identify dominant mutations involved in the modulation or regulation of voluntary alcohol consumption via a phenotype-driven ENU mutagenesis screen. In accordance with the findings from knockout studies, we suggest that mainly recessive mutations contribute to an alcohol-drinking or alcohol-avoiding phenotype.     

Radiation-induced forward and reverse specific locus mutations and dominant cataract mutations in treated strain BALB/c and DBA/2 male mice

Strain BALB/c and DBA/2 mice were chosen to investigate the effects of genetic background on the radiation-induced mutation rate since they exhibit differences in their radiation sensitivity. Males were exposed to 3 + 3-Gy X-irradiation and mated to untreated specific locus Test-stock females. Offspring resulting from treated spermatogonia were screened for induced specific locus forward and reverse mutations and dominant cataract mutations. Since BALB/c mice are homozygous brown and albino, specific locus forward mutations could be screened at 5 of the 7 specific loci (a, d, se, p, s), while reverse mutations could be screened at the b and c loci. Strain DBA/2 is homozygous non-agouti, brown and dilute. Therefore, specific locus forward mutations could be screened at 4 loci (c, se, p, s) and reverse mutations were screened at the a, b and d loci. Results indicate no effect of genetic background on the sensitivity to mutation induction of specific locus forward mutations, while for the dominant cataract alleles strain DBA/2 exhibited a higher mutation rate than either strain BALB/c or similarly treated (101/El X C3H/El)F1 mice. If, by confirmation, these differences should be demonstrated to be real, it is interesting that strain DBA/2 should exhibit a greater sensitivity to radiation-induced dominant mutations. First, strain DBA/2 was chosen as radiation resistant or repair competent. The observation that DBA/2 exhibited a higher sensitivity to radiation-induced mutation may indicate a role for repair, albeit misrepair, in the mutation process. Second, that the effect of genotype was only observed for the mutation rate to dominant cataract alleles may reflect a difference in the spectrum of DNA alterations which result in dominant or recessive alleles. A dominant allele is more likely misinformation, such that as heterozygote it interferes with the wild-type allele. By comparison, a recessive allele may result from any DNA alteration leading to the loss of a functional gene product. One reverse mutation at each of the a and d loci was recovered in the present experiments. The similarities of the present results for radiation-induced reverse mutations with the extensive data on the spontaneous reverse mutation rates are interesting. Reverse mutations were recovered only at the a and d loci. Further, the reverse mutations recovered at the a locus were to alternate alleles (at, Aw or Asy) while true reverse mutations were apparently recovered at the d locus.     

The induction of recessive mutations in mouse primordial germ cells with N-ethyl-N-nitrosourea

A specific-locus test was carried out to examine the mutagenic activity of N-ethyl-N-nitrosourea (ENU) on mouse primordial germ cells (PGC). Embryos of C3H/He mice were treated transplacentally with 30 or 50 mg ENU per kg of maternal body weight on day 8.5, 10.5, or 13.5 of gestation (G8.5 day, G10.5 day, or G13.5 day). Male and female mice that had been treated with ENU in embryonic stages were mated with female or male tester PW mice to detect recessive mutations induced in PGC.

ENU induced recessive mutations at a relatively high rate in PGC at these developmental stages. The most sensitive stage was G10.5 day. On G8.5 day, the induced mutation rate in males and females was not significantly different. Cluster mutations, which originate from the limited number of PGC and cell killing, were more frequently induced at an earlier developmental stage. The induced mutation rate per unit dose of ENU (1 mg/kg) was higher in G8.5 and G10.5 day PGC than in stem-cell spermatogonia. It can be concluded that mouse PGC are more sensitive than stem-cell spermatogonia to the induction of recessive mutations by ENU.     

Induction of specific-locus and dominant lethal mutations in male mice by 1-methyl-1-nitrosourea (MNU)

1-Methyl-1-nitrosourea (MNU) induced specific-locus mutations in mice in all spermatogenic stages except spermatozoa. After intraperitoneal injection of 70 mg/kg body weight of MNU a high yield of specific-locus mutations was observed in spermatids (21.8 × 10⁻⁵ mutations per locus per gamete). The highest mutational yield was induced in differentiating spermatogonia. In 1954 offspring we observed 5 specific-locus mutants (44.8 × 10⁻ mutations per locus per gamete). In addition, 2 mosaics were recovered, which gave a combined mutation rate of 62.7 × 10⁻⁵. In A_s spermatogonia the mutation rate was 3.9 × 10⁻⁵. The same dose of 70 mg/kg of MNU induced dominant lethal mutations 5–48 days post treatment, mainly due to post-implantation loss in spermatids and spermatocytes. It is interesting to compare the induction pattern of mutations by MNU with methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS) and ethylnitrosourea (ENU). Based on the different spermatogenic response of the induction of specific-locus mutations we can characterize the 4 mutagens in the following way: EMS = MMS ≠ MNU ≠ ENU.