Efficient Identification of Arabidopsis Knock-Out Mutants Using DNA-Arrays of Transposon Flanking Sequences

Abstract: Mutants obtained by insertional mutagenesis are widely used for determining gene-phenotype relationships. In Arabidopsis thaliana, several populations mutagenized either by T-DNA or transposon insertion are available for screening for knockout mutants in genes of interest. We have so far screened our Arabidopsis population mutagenized with the Zea mays transposon En-1/Spm for insertion mutations in 718 genes, using PCR on DNA pools. Although successful, this common approach is too time consuming for use in systematic screening of all 25 498 predicted genes of the Arabidopsis genome. We therefore investigated the use of DNA arrays for the direct identification of mutants in our population. All transposon-flanking regions from individual plants are amplified by PCR and subsequently spotted at high density onto nylon membranes. A single hybridization experiment with a gene-specific probe then allows one to identify candidate mutant plants. The efficiency of each separate step was determined and optimized. Screening of filters representing 2880 plants for insertions in 144 genes and subsequent investigation of some of the potential insertion mutants suggest that an overall screening efficiency of 50 % is attained.     

Site-directed point mutation in the src gene oF rous sarcoma virus results in an inactive src gene product

Site-directed mutagenesis techniques were used to construct defined point mutations within the src gene of the Prague A strain of Rous sarcoma virus. Bisulfite mutagenesis at a Bg/I restriction site in the src gene yielded three mutations which contained the same single base change, a guanine-to-adenine transition. The resulting genomes encoded an src protein containing a substitution of threonine for alanine at amino acid position 433. Transfection of chicken cells with mutagenized DNA did not result in cellular transformation even though the cells produced a pp60src. Immune complexes containing mutant pp60src did not phosphorylate immunoglobulin G heavy chain or casein.     

A general method to select for M13 clones carrying base pair substitution mutants constructed in vitro.

In this paper we describe a method to select base pair substitution mutants constructed in vitro. The mutagenesis is performed by forcing mistakes during in vitro synthesis from a primer annealed to a single stranded DNA template. The selection is based on the fact that, following transformation, the progeny of the strand elongated in vitro and the template strand have different phenotypes. The method is general and applicable to any DNA segment; the type of base pair substitution and its position can be chosen at will. The combined efficiency of mutagenesis and selection allows for 85% frequency of mutants in all analyzed clones.     

Retention of induced mutations in a Drosophila reverse-genetic resource

Targeting induced local lesions in genomes (TILLING) is a reverse-genetic method for identifying point mutations in chemically mutagenized populations. For functional genomics, it is ideal to have a stable collection of heavily mutagenized lines that can be screened over an extended period of time. However, long-term storage is impractical for Drosophila, so mutant strains must be maintained by continual propagation of live cultures. Here we evaluate a strategy in which ethylmethane sulfonate (EMS) mutagenized chromosomes were maintained as heterozygotes with balancer chromosomes for >100 generations before screening. The strategy yielded a spectrum of point mutations similar to those found in previous studies of EMS-induced mutations, as well as 2.4% indels (insertions and deletions). Our analysis of 1887 point mutations in 148 targets showed evidence for selection against deleterious lesions and differential retention of lesions among targets on the basis of their position relative to balancer breakpoints, leading to a broad distribution of mutational densities. Despite selection and differential retention, the success of a user-funded service based on screening a large collection several years after mutagenesis indicates sufficient stability for use as a long-term reverse-genetic resource. Our study has implications for the use of balancer chromosomes to maintain mutant lines and provides the first large-scale quantitative assessment of the limitations of using breeding populations for repositories of genetic variability.     

A gradient PCR-based screen for use in site-directed mutagenesis

Site-directed mutagenesis is widely used to study protein and nucleic acid structure and function. Despite recent advancements in the efficiency of procedures for site-directed mutagenesis, the fraction of site-directed mutants by most procedures rarely exceeds 50% on a routine basis and is never 100%. Hence it is typically necessary to sequence two or three clones each time a site-directed mutant is constructed. We describe a simple and robust gradient-PCR-based screen for distinguishing site-directed mutants from the starting, unmutated plasmid. The procedure can use either purified plasmid DNA or colony PCR, starting from a single colony. The screen utilizes the primer used for mutagenesis and a common outside primer that can be used for all other mutants constructed with the same template. Over 30 site-specific mutants in a variety of templates were successfully screened and all of the mutations detected were subsequently confirmed by DNA sequencing. A single base pair mismatch could be detected in an oligonucleotide of 36 bases. Detection efficiency was relatively independent of starting template concentration and the nature of the outside primer used.     

Localized mutagenesis of the tetracycline gene in the plasmid pBR322 induced by sodium bisulfite in vitro

The technique of localized in vitro mutagenesis in the cohesive ends of plasmid pBR322 DNA has been elaborated (separately for BamHI and HindIII sites). Plasmid DNA digested by restriction endonucleases has been treated with sodium bisulphite deaminating cytosine to form uracil in single stranded DNA (cohesive ends of the plasmid). The mutagenized plasmid DNA, free of mutagen, has been treated with bacteriophage T4 ligase. E. coli C600 cells were subsequently transformed by the ligated DNA preparation. The clones having tetracycline gene mutagenized represented 4.0-11.1% and 1.2-3.1% among HindIII and BamHI mutants, respectively, selected as TcR----TcS transformants. Selection of mutagenized DNA by the second endonuclease restriction has increased the mutant yields up to 55.6-78.0% and 10.0-75.4%, respectively. The yield of TcS mutations in the control DNA treated at all stages of experiment, except for mutagen treatment, has reached 0.06% and 0.2%, respectively.     

A single amino acid substitution in the enzyme 5-enolpyruvylshikimate-3-phosphate synthase confers resistance to the herbicide glyphosate

The enzyme 5-enolpyruvylshikimate-3-phosphate synthase (EC 2.5.1.19), encoded by the aroA locus, is a target site of glyphosate inhibition in bacteria. A glyphosate-resistant aroA allele has been cloned in Escherichia coli from a mutagenized strain of Salmonella typhimurium. Subcloning of this mutant aroA allele shows the gene to reside on a 1.3-kilobase segment of S. typhimurium DNA. Nucleotide sequence analysis of this mutant gene indicates a protein-coding region 427 amino acids in length. Comparison of the mutant and wild type aroA gene sequences reveals a single base pair change resulting in a Pro to Ser amino acid substitution at the 101st codon of the protein. A hybrid gene fusion between mutant and wild type aroA gene sequences was constructed. 5-Enolpyruvylshikimate-3-phosphate synthase was prepared from E. coli cells harboring this construct. The glyphosate-resistant phenotype is shown to be associated with the single amino acid substitution described above.     

AraC proteins with altered DNA sequence specificity which activate a mutant promoter in Escherichia coli

We examined the recognition of the araBAD promoter by the AraC protein in the Escherichia coli arabinose operon. A mutant promoter, with base substitutions at positions contacted by AraC, was used to isolate suppressor mutations in araC by direct selection. Two hydroxylamine-induced araC mutations were isolated repeatedly; each contained a single amino acid substitution. When tested against a set of base substitution promoter mutants, one revertant, an Arg to His substitution at residue 250, displayed altered base specificity for a single position within the araBAD promoter. The other revertant, a Cys to Tyr substitution at residue 204, did not show consistent base-specific suppression. Neither demonstrated a higher affinity than the wild type protein for the mutant promoter in vitro. Both proteins suppress mutant sequences by a mechanism that does not appear to involve the formation of new net favorable contacts with the mutant base pairs of the promoter.     

DNA base sequence changes induced by ultraviolet light mutagenesis of a gene on a chromosome in Chinese hamster ovary cells

The DNA base sequence changes induced by mutagenesis with ultraviolet light have been determined in a gene on a chromosome of cultured Chinese hamster ovary (CHO) cells. The gene was the Escherichia coli gpt gene, of which a single copy was stably incorporated and expressed in the CHO cell genome. The cells were irradiated with ultraviolet light and gpt- colonies were selected by resistance to 6-thioguanine. The gpt gene was amplified from chromosomal DNA by use of the polymerase chain reaction (PCR), and the amplified DNA sequenced directly by the dideoxy method. Of the 58 sequenced mutants of independent origin 53 were base change mutations. Forty-one base substitutions were single base changes, ten had two adjacent (or tandem) base changes, and one had two base changes separated by a single base-pair. Only one mutant had a multiple base change mutation with two or more well separated base changes. In contrast much higher levels of such mutations were reported in ultraviolet mutagenesis of genes on a shuttle vector in primate cells. Two deletions of a single base-pair were observed and three deletions ranging from 6 to 37 base-pairs. The mutation spectrum in the gpt gene had similarities to the ultraviolet mutation spectra for several genes in prokaryotes, which suggests similarities in mutational mechanisms in prokaryotes and eukaryotes.     

A fast neutron deletion mutagenesis-based reverse genetics system for plants

A new reverse genetics method has been developed to identify and isolate deletion mutants for targeted plant genes. Deletion mutant libraries are generated using fast neutron bombardment. DNA samples extracted from the deletion libraries are used to screen for deletion mutants by polymerase chain reaction (PCR) using specific primers flanking the targeted genes. By adjusting PCR conditions to preferentially amplify the deletion alleles, deletion mutants were identified in pools of DNA samples, each pool containing DNA from 2592 mutant lines. Deletion mutants were obtained for 84% of targeted loci from an Arabidopsis population of 51 840 lines. Using a similar approach, a deletion mutant for a rice gene was identified. Thus we demonstrate that it is possible to apply this method to plant species other than Arabidopsis. As fast neutron mutagenesis is highly efficient, it is practical to develop deletion mutant populations with more complete coverage of the genome than obtained with methods based on insertional mutagenesis. Because fast neutron mutagenesis is applicable to all plant genetic systems, this method has the potential to enable reverse genetics for a wide range of plant species.     

利用DREAM设计和同源重组进行一步定点突变

目的：建立基于DREAM设计和同源重组的简便、快速定点突变方法。方法：设计两条包含突变的反向PCR（inverse PCR）引物,使其5'端互补从而产生同源重组,同时使用DREAM设计方案在上述引物中引入限制性内切酶位点以便突变子筛选。用能扩增长片段的高保真耐热 DNA聚合酶扩增全长的质粒DNA,直接转化大肠杆菌。转化到细菌中的全长质粒DNA PCR产物可利用其末端同源序列发生同源重组而环化。利用引入的酶切位点方便地进行突变子的筛选。结果：我们用该方法成功地对长度大于7 kb的质粒进行了定点突变。结论：本定点突变无需任何突变试剂盒和特殊的试剂,只需一步反应即可完成;利用DREAM设计使克隆筛选简便可靠,高保真耐热DNA聚合酶可保证多数突变子克隆不发生意外突变,而该酶扩增长片段的能力使该方法适合于大多数质粒不经亚克隆直接突变。     

Targeted recovery of mutations in Drosophila

Reverse genetic techniques will be necessary to take full advantage of the genomic sequence data for Drosophila and other experimental organisms. To develop a method for the targeted recovery of mutations, we combined an EMS chemical mutagenesis regimen with mutation detection by denaturing high performance liquid chromatography (DHPLC). We recovered mutant strains at the high rate of approximately 4.8 mutations/kb for every 1000 mutagenized chromosomes from a screen for new mutations in the Drosophila awd gene. Furthermore, we observed that the EMS mutational spectrum in Drosophila germ cells shows a strong preference for 5'-PuG-3' sites, and for G/C within a stretch of three or more G/C base pairs. Our method should prove useful for targeted mutagenesis screens in Drosophila and other genetically tractable organisms and for more precise studies of mutagenesis and DNA repair mechanisms.     

Cloning of the rec-2 locus of Haemophilus influenzae

A collection of transposon mutants of Haemophilus influenzae was constructed by additive transformation with mutagenized chromosomal DNA. A rec-2::miniTn10 km mutation was cloned from a transformation-defective member of the mutant collection, followed by the reconstruction of the wild-type rec-2 locus by recombination to create pDM62. Southern blots showed that the commonly studied Rec-2 mutant, Rd(DB117)rec-, contained either a large deletion or a substitution that removed part of rec-2 locus. A collection of transposon mutations in pDM62 was used to characterize the rec-2 locus by complementation. A corresponding collection of mutants was also constructed. A single segment was required to complement the transformation defect in Rd(DB117)rec-. All of the transformation-defective transposon mutants failed to translocate donor DNA into then cell, in agreement with previous studies of Rd(DB117)rec-.     

TOMATOMA: a novel tomato mutant database distributing Micro-Tom mutant collections

The tomato is an excellent model for studies of plants bearing berry-type fruits and for experimental studies of the Solanaceae family of plants due to its conserved genetic organization. In this study, a comprehensive mutant tomato population was generated in the background of Micro-Tom, a dwarf, rapid-growth variety. In this and previous studies, a family including 8,598 and 6,422 M(2) mutagenized lines was produced by ethylmethane sulfonate (EMS) mutagenesis and γ-ray irradiation, and this study developed and investigated these M(2) plants for alteration of visible phenotypes. A total of 9,183 independent M(2) families comprising 91,830 M(2) plants were inspected for phenotypic alteration, and 1,048 individual mutants were isolated. Subsequently, the observed mutant phenotypes were classified into 15 major categories and 48 subcategories. Overall, 1,819 phenotypic categories were found in 1,048 mutants. Of these mutants, 549 were pleiotropic, whereas 499 were non-pleiotropic. Multiple different mutant alleles per locus were found in the mutant libraries, suggesting that the mutagenized populations were nearly saturated. Additionally, genetic analysis of backcrosses indicated the successful inheritance of the mutations in BC(1)F(2) populations, confirming the reproducibility in the morphological phenotyping of the M(2) plants. To integrate and manage the visible phenotypes of mutants and other associated data, we developed the in silico database TOMATOMA, a relational system interfacing modules between mutant line names and phenotypic categories. TOMATOMA is a freely accessible database, and these mutant recourses are available through the TOMATOMA (http://tomatoma.nbrp.jp/index.jsp).     

Microsatellite instability induced by hydrogen peroxide in Escherichia coli

Damage to DNA by reactive oxygen species may be a significant source of endogenous mutagenesis in aerobic organisms. Using a selective assay for microsatellite instability in E. coli, we have asked whether endogenous oxidative mutagenesis can contribute to genetic instability. Instability of repetitive sequences, both in intronic sequences and within coding regions, is a hallmark of genetic instability in human cancers. We demonstrate that exposure of E. coli to low levels of hydrogen peroxide increases the frequency of expansions and deletions within dinucleotide repetitive sequences. Sequencing of the repetitive sequences and flanking non-repetitive regions in mutant clones demonstrated the high specificity for alterations with the repeats. All of the 183 mutants sequenced displayed frameshift alterations within the microsatellite repeats, and no base substitutions or frameshift mutations occurred within the flanking non-repetitive sequences. We hypothesize that endogenous oxidative damage to DNA can increase the frequency of strand slippage intermediates occurring during DNA replication or repair synthesis, and contribute to genomic instability.     

Screening for thermostable mutant of kanamycin nucleotidyltransferase by the use of a transformation system for a thermophile, Bacillus stearothermophilus

A structural gene of kanamycin nucleotidyltransferase cloned into a single-stranded bacteriophage M13 was subjected to mutagenesis with hydroxylamine. Having recloned the mutagenized gene of the enzyme in a vector plasmid pTB922, the recombinant plasmid was used to transform Bacillus stearothermophilus with a purpose of screening for the more thermostable enzyme than the wild type. Out of greater than 8 X 10(3) transformants, 12 clones that were suspected to harbor the mutant gene encoding the more thermostable enzyme were isolated by shifting from a permissive (55 degrees C) to a nonpermissive (61 degrees C) temperature that inactivates the wild-type enzyme. DNA sequence analysis of the mutant genes revealed two types of mutation of single base substitution and hence a single amino acid replacement. The first type was the replacement of an aspartate by a tyrosine at position 80 of the wild-type enzyme, while the second was that of a threonine by a lysine at position 130. Purified enzymes from the two mutant genes were confirmed to be substantially more thermostable than the wild type in vitro. The method of screening for a thermostable kanamycin nucleotidyltransferase presented here could be applied to any other enzyme, if a transformation system of a thermophile were available. Indeed, thermostable mutants with a subtle amino acid change would be of value for better understanding of forces and interactions that contribute to the stability of a protein.     

The nucleotide sequence of the first externally suppressible--1 frameshift mutant, and of some nearby leaky frameshift mutants

Nine mutants within a 23 nucleotide sequence of the trpE gene of Salmonella typhimurium have been characterized. trpE91, a mutant which is externally suppressible has a single base deletion. Eight (or nine) nucleotides upstream of this deletion, two independently isolated mutations have the same transversion. In combination with trpE91 these mutations lead to partial restoration of synthesis of anthranilate synthetase in the absence of external suppressors. In the transversion the sequence A CA is changed to A AA and this new sequence may be the site where frameshifting occurs to allow leakiness. Leakiness is displayed by two further mutants of the same sign as trpE91, and one of the opposite sign, in the absence of any base substitution or external suppressors. Specific sequences, e.g., UUUC, may be especially prone to frameshifting and this sequence is created at the site of the +1 frameshift mutant which displays leakiness. In the new reading frame generated by the two -1 frame leaky mutants, a tryptophan codon is encountered. Leakiness is necessarily detected in the absence of tryptophan and under these conditions there will be a shortage of charged tryptophan tRNA. The possibility of such functional imbalance leading to frameshifting in these mutants is discussed.