An AFLP-based genome-wide mapping strategy.

To efficiently determine the chromosomal location of phenotypic mutants, we designed a genome-wide mapping strategy that can be used in any crop for which a dense AFLP (Amplified Fragment Length Polymorphism) map is available or can be made. The AFLP technique is particularly suitable to initiate map-based cloning projects because it detects many markers per reaction. First a standard set of AFLP primer combinations that results in a framework of AFLP markers well dispersed over the genome is selected. These primer combinations are applied to a limited number of mutant individuals from a segregating population to register linkage and non-linkage of the AFLP markers to the gene-of-interest. Further delineation of the area of interest is accomplished by analyzing the remaining recombinants and additional mutant individuals with AFLP markers that lie within the identified region. We illustrate the usefulness of the method by mapping three rotunda ( ron) leaf-form mutant loci of Arabidopsis thaliana and show that in the initial phase of map-based cloning projects a 400-600 kb interval can be identified for the average mutant locus within a few weeks. Once such an area is identified and before initiating the more time-consuming fine-mapping procedure, it is essential to examine publicly available databases for candidate genes and known mutants in the identified region. The 390-kb interval on chromosome 4 that harbors the ron2 mutation, also carries a known flower mutant, leunig ( lug); upon crossing, the two mutants appeared to be allelic. When no such candidates are found, the mapping procedure should be continued. We present a strategy to efficiently select recombinants that can be used for fine mapping.

AtCSLD3, a cellulose synthase-like gene important for root hair growth in arabidopsis.

A member of the cellulose synthase-like (subfamily D) gene family of Arabidopsis, AtCSLD3, has been identified by T-DNA tagging. The analysis of the corresponding mutant, csld3-1, showed that the AtCSLD3 gene plays a role in root hair growth in plants. Root hairs grow in phases: First a bulge is formed and then the root hair elongates by polarized growth, the so-called "tip growth." In the mutant, root hairs were initiated at the correct position and grew into a bulge, but their elongation was severely reduced. The tips of the csld3-1 root hairs easily leaked cytoplasm, indicating that the tensile strength of the cell wall had changed at the site of the tip. Based on the mutant phenotype and the functional conservation between CSLD3 and the genuine cellulose synthase proteins, we hypothesized that the CSLD3 protein is essential for the synthesis of polymers for the fast-growing primary cell wall at the root hair tip. The distinct mutant phenotype and the ubiquitous expression pattern indicate that the CSLD3 gene product is only limiting at the zone of the root hair tip, suggesting particular physical properties of the cell wall at this specific site of the root hair cell.

The drl1 gene, a signal identified by transposon tagging is important for leaf growth.

Control of leaf shape and size was studied at the molecular level by a mutational approach in Arabidopsis thaliana. Mutations that affected leaf growth allowed the identification of genes that are important in that morphological process. The Activator/Dissociation (Ac/Ds) transposable element system of maize was modified to be used as mutagen of the Arabidopsis genome. We isolated the drl 1-2 mutation that is characterized by narrow leaf blades. We describe the mutant phenotype and have cloned and analyzed the gene. These combined analyses will give insight into the molecular mechanisms that control leaf growth.

Tornado1 and tornado2 are required for the specification of radial and circumferential pattern in the Arabidopsis root.

The cell layers of the Arabidopsis primary root are arranged in a simple radial pattern. The outermost layer is the lateral root cap and lies outside the epidermis that surrounds the ground tissue. The files of epidermal and lateral root cap cells converge on a ring of initials (lateral root cap/epidermis initial) from which the epidermal and lateral root cap tissues of the seedling are derived, once root growth is initiated after germination. Each initial gives rise to a clone of epidermal cells and a clone of lateral root cap cells. These initial divisions in the epidermal/lateral root cap initial are defective in tornado1 (trn1) and trn2 plants indicating a requirement for TRN1 and TRN2 for initial cell function. Furthermore, lateral root cap cells develop in the epidermal position in trn1 and trn2 roots indicating that TRN1 and TRN2 are required for the maintenance of the radial pattern of cell specification in the root. The death of these ectopic lateral root cap cells in the elongation zone (where lateral root cap cells normally die) results in the development of gaps in the epidermis. These observations indicate that TRN1 and TRN2 are required to maintain the distinction between the lateral root cap and epidermis and suggest that lateral root cap fate is the default state. It also suggests that TRN1 and TRN2 repress lateral root cap fate in cells in the epidermal location. Furthermore, the position-dependent pattern of root hair and non-root hair cell differentiation in the epidermis is defective in trn1 and trn2 mutants. Together these results indicate that TRN1 and TRN2 are required for the maintenance of both the radial pattern of tissue differentiation in the root and for the subsequent circumferential pattern within the epidermis.

The SERRATE locus controls the formation of the early juvenile leaves and phase length in Arabidopsis.

The development of the shoot can be divided into a series of distinct developmental phases based on leaf character-istics and inflorescence architecture. The relationship between phase length, defined by the number of organs produced, and the timing of the floral induction (V3-I1 transition) is relatively ill defined. Characterization of the serrate mutant (CS3257; Arabidopsis Biological Research Center) revealed defects in both vegetative and inflores-cence phase lengths, the timing of phase transitions, leaf number, the leaf initiation rate, and phyllotaxy. The timing of floral induction, however, is the same as in wild-type in extended short days as well as in short days, whereas the flowering time response to photoperiod is unaffected. SERRATE is shown to be required for the development of early juvenile leaves (V1) and to promote late juvenile leaf development (V2), while suppressing adult leaf (V3) and inflorescence development (I1 and I2). The se mutation supports the hypothesis that the timing of floral induction is independent of vegetative and inflorescence phase lengths. The role of SERRATE in the regulation of phase length and leaf identity is discussed.

Chromosome landing at the Arabidopsis TORNADO1 locus using an AFLP-based strategy.

The Arabidopsis tornado1 (trn1) mutation causes severe dwarfism combined with twisted growth of all organs. We present a chromosome landing strategy, using amplified restriction fragment length polymorphism (AFLP) marker technology, for the isolation of the TRN1 gene. The recessive trn1 mutation was identified in a C24 transgenic line and is located 5 cM from a T-DNA insertion. We mapped the TRN1 locus to the bottom half of chromosome 5 relative to visible and restriction fragment length polymorphism (RFLP) markers. Recombinant classes within a 3-cM region around TRN1 were used to build a high-resolution map in this region, using the AFLP technique. Approximately 300 primer combinations have been used to test about 26,000 fragments for polymorphisms. Seventeen of these AFLP markers were identified in the 3-cM region around TRN1. These markers were mapped within this region using individual recombinants. Four of these AFLP markers co-segregate with TRN1 whereas one maps at one recombinant below TRN1. We isolated and cloned three of these AFLP markers. These markers identified two yeast artificial chromosome (YAC) clones, containing the RFLP marker above and the AFLP marker below TRN1, demonstrating that these YACs span the TRN1 locus and that chromosome landing has been achieved, using an AFLP-based strategy.

Transgenic Arabidopsis tester lines with dominant marker genes.

The map positions of a set of eight T-DNA insertions in the Arabidopsis genome have been determined by using closely linked visible markers. The insertions are dispersed over four of the five chromosomes. Each T-DNA insert contains one or more of the chimeric marker genes neomycin phosphotransferase (neo), hygromycin phosphotransferase (hpt), phosphinothricin acetyltransferase (bar), beta-glucuronidase (gusA) and indole-3-acetamide hydrolase (iaaH). The neo, hpt and bar marker genes are dominant in a selective germination assay or when used as DNA markers in a polymerase chain reaction. These dominant markers will allow recombinants to be discerned in a germinating F2 population, one generation earlier than with a conventional recessive marker. The transgenic marker lines will speed up and simplify the isolation of recombinants in small genetic intervals, a rate-limiting step in positional cloning strategies. The transgenic lines containing the hpt marker will also be of interest for the isolation of deletion mutants at the T-DNA integration sites.

An S18 ribosomal protein gene copy at the Arabidopsis PFL locus affects plant development by its specific expression in meristems.

In Arabidopsis, mutation at PFL causes pointed first leaves, reduced fresh weight and growth retardation. We have cloned the wild-type PFL gene by T-DNA tagging, and demonstrate that it complements the mutant phenotype. PFL codes for ribosomal protein S18, based on the high homology with rat S18 and on purification of S18-equivalent peptides from plant ribosomes. pfl represents the first mutation in eukaryotic S18 proteins or their S13 prokaryotic counterparts, involved in translation initiation. Arabidopsis contains three S18 gene copies dispersed in the genetic map; they are all transcribed and code for completely identical proteins. No transcript is detected from the mutated gene, S18A. The activity of the S18A promoter is restricted to meristems, with a markedly high expression at the embryonic heart stage, and to wounding sites. This means that plants activate an extra copy of this ribosomal protein gene in tissues with cell division activity. We postulate that in meristematic tissues plants use transcriptional control to synthesize extra ribosomes to increase translational efficiency. In analogy with this, an additional, developmentally regulated gene copy might be expected for all ribosomal proteins.

Insertional mutagenesis in Arabidopsis thaliana: isolation of a T-DNA-linked mutation that alters leaf morphology.

We investigated the potential of the Agrobacterium tumefaciens T-DNA as an insertional mutagen in Arabidopsis thaliana. Arabidopsis lines transformed with different T-DNA vectors were generated using a leaf disc infection procedure adapted for efficient selection on either kanamycin or hygromycin medium. A standardized screening procedure was developed for the detection of recessive mutations in T2 populations of regenerated and/or transformed lines. Recessive mutations originating from the tissue culture procedure occurred at a low frequency - between 2% and 5%. Within 110 transformed lines that contained a total of about 150 T-DNA inserts, one recessive mutation, named pfl, cosegregated with a specific T-DNA copy. This pfl mutation mainly affected the morphology of the first seedling leaves under normal growth conditions and was mapped to chromosome 1. No recombination between the pfl locus and the kanamycin resistance marker on the T-DNA was detected when screening F2 and F3 populations of a mutant crossed to the wild type. The maximal genetic distance between the pfl locus and the kanamycin resistance gene, determined as 0.4±0.4 cMorgan, strongly suggests that the pfl mutation is induced by the insertion of the T-DNA. Our finding of one T-DNA-linked recessive mutation in 110 transgenic lines indicates that T-DNA can be used for mutagenization of the Arabidopsis genome under tissue culture conditions.

Agrobacterium rhizogenes-mediated transformation of Echinacea purpurea.

Echinacea purpurea seedlings were inoculated with several Agrobacterium rhizogenes strains in order to obtain hairy roots. Infection with A. rhizogenes strains LMG63 and LMG150 resulted in callus formation. Upon infection with strains ATCC 15834 and R1601 hairy roots were obtained. Opine detection confirmed transformation of E. purpurea. Comparative HPLC fingerprint analysis of the alkamides from natural plant source, control tissues, and transformed callus and roots indicated that transformed callus and hairy roots might be a promising source for continuous and standardized production of the dodeca-2E,4E,8Z,10E/Z-tetraenoic acid isobutylamide and related amides.

Agrobacterium tumefaciens-mediated transformation of Arabidopsis thaliana root explants by using kanamycin selection.

Culture conditions were developed that induce Arabidopsis thaliana (L.) Heynh. root cuttings to regenerate shoots rapidly and at 100% efficiency. The shoots produce viable seeds in vitro or after rooting in soil. A transformation procedure for Arabidopsis root explants based on kanamycin selection was established. By using this regeneration procedure and an Agrobacterium tumor-inducing Ti plasmid carrying a chimeric neomycin phosphotransferase II gene (neo), transformed seed-producing plants were obtained with an efficiency between 20% and 80% within 3 months after gene transfer. F(1) seedlings of these transformants showed Mendelian segregation of the kanamycin-resistance trait. The transformation method could be applied to three different Arabidopsis ecotypes. In addition to the neo gene, a chimeric bar gene conferring resistance to the herbicide Basta was introduced into Arabidopsis. The expression of the bar gene was shown by enzymatic assay.

A binary vector for transferring genomic libraries to plants.

The transformation of mutant plants with a complete recombinant library derived from wild-type DNA followed by assay of transformed plants for complementation of the mutant phenotype is a promising method for the isolation of plant genes. The small genome of Arabidopsis thaliana is a good candidate for attempting this so-called shotgun transformation. We present the properties of an A. thaliana genomic library cloned in a binary vector, pC22. This vector, designed to introduce genomic libraries into plants, contains the oriV of the Ri plasmid pRiHR1 by which it replicates perfectly stably in Agrobacterium. Upon transfer of the library from E. coli to A. tumefaciens large differences in transfer efficiencies of individual recombinant clones were observed. There is a direct relation between transfer efficiency and stability of the recombinant clones both in E. coli and A. tumefaciens. The stability is independent of the insert size, but seems to be related to the nature of the insert DNA. The feasibility of shotgun transformation and problems of statistical sampling are discussed.

Transformed cell clones as a tool to study T-DNA integration mediated by Agrobacterium tumefaciens.

A large number of tobacco SR1 cell clones transformed by the wild-type Agrobacterium C58 have been analysed for the presence of screenable markers such as tumour morphology, opine synthesis and hormone dependence. Distinct phenotypic classes were observed depending upon whether the cell clones were isolated from primary tumours or were obtained via cocultivation of protoplasts. These classes of tobacco SR1-C58 transformants appear to arise from errors in the Ti plasmid (T-DNA) transfer and integration mechanism itself rather than from subsequent T-DNA rearrangements, since 900 subclones, obtained by recloning a wild-type SR1-C58-transformed cell clone, yielded no variation in the phenotypes. A detailed genomic T-DNA analysis showed the presence of characteristic, abnormally short T-DNAs in the teratoma-forming, Acs- class and also in the Nos- class. The abnormal right border in two Nos- clones ends close to a sequence that resembles the normal T-DNA terminus and lies adjacent to the nos promoter, suggesting that this sequence could have functioned as a recognition site directing these particular T-DNA transfers. On the basis of the phenotypic and genomic blotting data it is clear that the short T-DNAs are characteristic of the cocultivation method. Other phenomena causing phenotypic variation, such as the loss of the T-DNA, and the gradual repression of T-DNA gene expression by methylation, are the main causes of aberrations in primary tumours. Moreover, the physical data suggest that early in the transformation cycle of Agrobacterium a replication step of a preselected T-DNA occurs before integration into the plant genome.