The Chloroplast Function Database: a large-scale collection of Arabidopsis Ds/Spm- or T-DNA-tagged homozygous lines for nuclear-encoded chloroplast proteins, and their systematic phenotype analysis.

A majority of the proteins of the chloroplast are encoded by the nuclear genome, and are post-translationally targeted to the chloroplast. From databases of tagged insertion lines at international seed stock centers and our own stock, we selected 3246 Ds/Spm (dissociator/suppressor-mutator) transposon- or T-DNA-tagged Arabidopsis lines for genes encoding 1369 chloroplast proteins (about 66% of the 2090 predicted chloroplast proteins) in which insertions disrupt the protein-coding regions. We systematically observed 3-week-old seedlings grown on agar plates, identified mutants with abnormal phenotypes and collected homozygous lines with wild-type phenotypes. We also identified insertion lines for which no homozygous plants were obtained. To date, we have identified 111 lines with reproducible seedling phenotypes, 122 lines for which we could not obtain homozygotes and 1290 homozygous lines without a visible phenotype. The Chloroplast Function Database presents the molecular and phenotypic information obtained from this resource. The database provides tools for searching for mutant lines using Arabidopsis Genome Initiative (AGI) locus numbers, tagged line numbers and phenotypes, and provides rapid access to detailed information on the tagged line resources. Moreover, our collection of insertion homozygotes provides a powerful tool to accelerate the functional analysis of nuclear-encoded chloroplast proteins in Arabidopsis. The Chloroplast Function Database is freely available at http://rarge.psc.riken.jp/chloroplast/. The homozygous lines generated in this project are also available from the various Arabidopsis stock centers. We have donated the insertion homozygotes to their originating seed stock centers.

A heterocomplex of iron superoxide dismutases defends chloroplast nucleoids against oxidative stress and is essential for chloroplast development in Arabidopsis.

There are three iron superoxide dismutases in Arabidopsis thaliana: FE SUPEROXIDE DISMUTASE1 (FSD1), FSD2, and FSD3. Their biological roles in chloroplast development are unknown. Here, we show that FSD2 and FSD3 play essential roles in early chloroplast development, whereas FSD1, which is found in the cytoplasm, does not. An fsd2-1 fsd3-1 double mutant had a severe albino phenotype on agar plates, whereas fsd2 and fsd3 single knockout mutants had pale green phenotypes. Chloroplast development was arrested in young seedlings of the double mutant. The mutant plants were highly sensitive to oxidative stress and developed increased levels of reactive oxygen species (ROS) during extended darkness. The FSD2 and FSD3 proteins formed a heteromeric protein complex in the chloroplast nucleoids. Furthermore, transgenic Arabidopsis plants overexpressing both the FSD2 and FSD3 genes showed greater tolerance to oxidative stress induced by methyl viologen than did the wild type or single FSD2- or FSD3-overexpressing lines. We propose that heteromeric FSD2 and FSD3 act as ROS scavengers in the maintenance of early chloroplast development by protecting the chloroplast nucleoids from ROS.

The FOX hunting system: an alternative gain-of-function gene hunting technique.

We have developed a novel gain-of-function system that we have named the FOX hunting system (Full-length cDNA Over-eXpressing gene hunting system). We used normalized full-length cDNA and introduced each cDNA into Arabidopsis by in planta transformation. About 10 000 independent full-length Arabidopsis cDNAs were expressed independently under the CaMV 35S promoter in Arabidopsis. Each transgenic Arabidopsis contained on average 2.6 cDNA clones and was monitored under various categories such as morphological changes, fertility and leaf color. We found 1487 possible morphological mutants from 15 547 transformants. When 115 pale green T(1) mutants were analyzed, 59 lines represented the mutant phenotypes in more than 50% of the T(2) progeny. Characterization of two leaf color mutants revealed the significance of this approach. We also document mutants from several categories and their corresponding full-length cDNAs.

Sequence database of 1172 T-DNA insertion sites in Arabidopsis activation-tagging lines that showed phenotypes in T1 generation.

Plant genomic resources harbouring gain-of-function mutations remain rare, even though this type of mutation is believed to be one of the most useful for elucidating the function of unknown genes that have redundant partners in the genome. An activation-tagging T-DNA was introduced into the genome of Arabidopsis creating 55,431 independent transformed lines. Of these T1 lines, 1,262 showed phenotypes different from those of wild-type plants. We called these lines 'AT1Ps' (activation T1 putants). The phenotypes observed include abnormalities in morphology, growth rate, plant colour, flowering time and fertility. Similar phenotypes re-appeared either in dominant or semi-dominant fashion in 17% of 177 AT2P plants tested. Plasmid rescue or an adaptor-PCR method was used to identify 1172 independent genomic loci of T-DNA integration sites in the AT1P plants. Mapping of the integration sites revealed that the chromosomal distribution of these sites is similar to that observed in conventional T-DNA knock-out lines, except that the intragenic type of integration is slightly lower (27%) in the AT1P plants compared to that observed in other random knock-out populations (30-35%). Ten AT2P lines that showed dominant phenotypes were chosen to monitor expression levels of genes adjacent to the T-DNA integration sites by RT-PCR. Activation was observed in 7 out of 17 of the adjacent genes detected. Genes located up to 8.2 kb away from the enhancer sequence were activated. One of the seven activated genes was located close to the left-border sequence of the T-DNA, having an estimated distance of 5.7 kb from the enhancer. Surprisingly, one gene, the first ATG of which is located 12 kb away from the enhancer, showed reduced mRNA accumulation in the tagged line. Application of the database generated to Arabidopsis functional genomics research is discussed. The sequence database of the 1172 loci from the AT1P plants is available (http://pfgweb.gsc.riken.go.jp/index.html).