Multiple non-LTR retrotransposons in the genome of Arabidopsis thaliana.

DNA sequence analysis near the Arabidopsis thaliana ABI3 gene revealed the presence of a non-LTR retrotransposon insertion that we have designated Ta11-1. This insertion is 6.2 kb in length and encodes two overlapping reading frames with similarity to non-LTR retrotransposon proteins, including reverse transcriptase. A polymerase chain reaction assay was developed based on conserved amino acid sequences shared between the Ta11-1 reverse transcriptase and those of non-LTR retrotransposons from other species. Seventeen additional A. thaliana reverse transcriptases were identified that range in nucleotide similarity from 48-88% (Ta12-Ta28). Phylogenetic analyses indicated that the A. thaliana sequences are more closely related to each other than to elements from other organisms, consistent with the vertical evolution of these sequences over most of their evolutionary history. One sequence, Ta17, is located in the mitochondrial genome. The remaining are nuclear and of low copy number among 17 diverse A. thaliana ecotypes tested, suggesting that they are not highly active in transposition. The paucity of retrotransposons and the small genome size of A. thaliana support the hypothesis that most repetitive sequences have been lost from the genome and that mechanisms may exist to prevent amplification of extant element families.

Isolation of the Arabidopsis ABI3 gene by positional cloning.

Arabidopsis abi3 mutants are altered in various aspects of seed development and germination that reflect a decreased responsiveness to the hormone abscisic acid. The ABI3 gene has been isolated by positional cloning. A detailed restriction fragment length polymorphism (RFLP) map of the abi3 region was constructed. An RFLP marker closely linked to the abi3 locus was identified, and by analyzing an overlapping set of cosmid clones containing this marker, the abi3 locus was localized within a 35-kb region. An 11-kb subfragment was then shown to complement the mutant phenotype in transgenic plants, thereby further delimiting the position of the locus. A candidate ABI3 gene was identified within this fragment as being expressed in developing fruits. The primary structure of the encoded protein was deduced from sequence analysis of a corresponding cDNA clone. In the most severe abi3-4 allele, the size of this predicted protein was reduced by 40% due to the presence of a point mutation that introduced a premature stop codon. The predicted ABI3 protein displays discrete regions of high similarity to the maize viviparous-1 protein.

Identification and map position of YAC clones comprising one-third of the Arabidopsis genome.

YAC clones corresponding to 125 Arabidopsis thaliana RFLP markers have been identified. At least one YAC clone has been isolated for each of the RFLP markers tested. Based on CHEF gel analysis of 196 clones, the mean insert size of the available Arabidopsis YAC libraries is approximately 160 kb. The YACs of known genetic map location encompass about 30% of the Arabidopsis genome. The results presented here represent a first step towards assembly of an overlapping YAC library of the A. thaliana genome.

Mapping the Arabidopsis genome.

We are engaged in a project to assemble a complete physical map of the Arabidopsis thaliana (L.) Heynh. genome. The first stage of this project involved the analysis of approximately 20,000 random cosmid clones representing an 8- to 10-fold sampling redundancy. Using computer matching programs, these clones have been assembled into some 750 contigs, encompassing 90-95% of the Arabidopsis genome. We are currently attempting to bridge the gaps by selecting the missing clones by hybridization. As a complement to this project we have constructed an RFLP map which currently contains 175 markers. The RFLP map provides contact points between the physical map and classical genetic map. Our main objective for undertaking this project is to simplify the cloning of genes where only the locus and not the product of the gene is known. In other words, the combined RFLP/physical map serves as a general cloning tool by simplifying the movement from the genetic locus to the cloned gene.

Restriction Fragment Length Polymorphism Linkage Map of Arabidopsis thaliana.

We have constructed a restriction fragment length polymorphism (RFLP) linkage map of the nuclear genome of the small flowering plant Arabidopsis thaliana. The map is based on the meiotic segregation of both RFLP and morphological genetic markers from five independent crosses. The morphological markers on each of the five chromosomes were included in the crosses to allow alignment of the RFLP map with the established genetic map. The map contains 94 new randomly distributed molecular markers (nine identified cloned Arabidopsis genes and 85 genomic cosmid clones) that detect polymorphisms between the Landsberg erecta and Columbia races. In addition, 17 markers from an independently constructed RFLP map of the Arabidopsis genome [Chang, C., Bowman, J.L., DeJohn, A.W., Lander, E.S., and Meyerowitz, E.M. (1988). Proc. Natl. Acad. Sci. USA 85, 6856-6860] have been included to permit integration of the two RFLP maps.

A cautionary note on the use of blot hybridization for RNA size determination.

The ease with which RNA blot hybridization analysis can be performed makes it among the most widely used analytical tools in molecular biology. Hybridization with a labeled probe, subsequent to size fractionation and immobilization on a filter, allows one to approximate both the size and abundance of a given RNA in a single experiment. This communication demonstrates that dramatic differences in the electrophoretic mobility of the yeast GCN2 transcript are observed when size fractionation on formaldehyde gels is compared to fractionation of glyoxalated RNA. Both routinely used systems are considered to be fully denaturing. The anomalous mobilities therefore pose a potential problem when size determination is performed using a single gel system.

Transcriptional-translational regulatory circuit in Saccharomyces cerevisiae which involves the GCN4 transcriptional activator and the GCN2 protein kinase.

GCN4 protein mediates the transcriptional activation of amino acid biosynthetic genes in Saccharomyces cerevisiae by specifically binding to DNA sequences in their 5'-regulatory regions. GCN4 expression is regulated at the level of translation, with translational derepression occurring under conditions of amino acid starvation. The product of the GCN2 gene is essential for translational derepression of GCN4. Sequence analysis of the GCN2 gene reveals that the GCN2 protein has a domain highly homologous to the catalytic domain of all known protein kinases. Furthermore, gcn2 strains are deficient in a protein kinase activity corresponding to a protein with the calculated molecular weight deduced from the GCN2 open reading frame. Therefore it is likely that GCN2 encodes a protein kinase, which may be directly involved in translational regulation of the GCN4 mRNA. Transcription of the GCN2 gene is increased when cells are cultured in amino acid starvation medium. This transcriptional activation is mediated by the GCN4 protein, which binds to the promoter region of the GCN2 gene. Thus, this system is modulated by a transcriptional-translational regulatory circuit, which is activated by amino acid starvation. Activation is not the result of a simple quantitative increase of either one of the identified components of the circuit.