The protein kinase genes MAP3K epsilon 1 and MAP3K epsilon 2 are required for pollen viability in Arabidopsis thaliana.

We have used reverse-genetic analysis to investigate the function of MAP3K epsilon 1 and MAP3K epsilon 2, a pair of closely related Arabidopsis thaliana genes that encode protein kinases. Plants homozygous for either map3k epsilon 1 or map3k epsilon 2 displayed no apparent mutant phenotype, whereas the double-mutant combination caused pollen lethality. Transmission of the double-mutant combination through the female gametophyte was normal. Tetrad analysis performed using the Arabidopsis quartet mutation demonstrated that the pollen-lethal phenotype segregated at meiosis with the map3k epsilon 1;map3k epsilon 2 genotype. We used transmission electron microscopy to determine that double-mutant pollen grains develop plasma membrane irregularities following pollen mitosis I. Analysis of the subcellular localization of a yellow fluorescent protein (YFP):MAP3Kepsilon1 fusion protein using confocal microscopy and biochemical fractionation indicated that a substantial portion of the MAP3Kepsilon1 present in Arabidopsis cells is localized to the plasma membrane. Taken together, our results suggest that MAP3Kepsilon1 is required for the normal functioning of the plasma membrane in developing Arabidopsis pollen.

Characterization of T-DNA insertion sites in Arabidopsis thaliana and the implications for saturation mutagenesis.

A key component of a sound functional genomics infrastructure is the availability of a knockout mutant for every gene in the genome. A fruitful approach to systematically knockingout genes in the plant Arabidopsis thaliana has been the use of transferred-DNA (T-DNA) from Agrobacterium tumefaciens as an insertional mutagen. One of the assumptions underlying the use of T-DNA as a mutagen is that the insertion of these DNA elements into the Arabidopsis genome occurs at randomly selected locations. We have directly investigated the distribution of T-DNA insertions sites in populations of transformed Arabidopsis using two different approaches. To begin with, we utilized a polymerase chain reaction (PCR) procedure to systematically catalog the precise locations of all the T-DNA elements inserted within a 65 kb segment of chromosome IV. Of the 47 T-DNA insertions identified, 30% were found within the coding regions of genes. We also documented the insertion of T-DNA elements within the centromeric region of chromosome IV. In addition to these targeted T-DNA screens, we also mapped the genomic locations of 583 randomly chosen T-DNA elements by sequencing the genomic DNA flanking the insertion sites from individual T-DNA-transformed lines. 35% of these randomly chosen T-DNA insertions were located within the coding regions of genes. For comparison, coding sequences account for 44% of the Arabidopsis genome. Our results demonstrate that there is a small bias towards recovering T-DNA insertions within intergenic regions. However, this bias does not limit the utility of T-DNA as an effective insertional mutagen for use in reverse-genetic strategies.