Control of transposable elements in Arabidopsis thaliana

Arabidopsis thaliana serves as a very good model organism to investigate the control of transposable elements (TEs) by genetic and genomic approaches. As TE movements are potentially deleterious to the hosts, hosts silence TEs by epigenetic mechanisms, such as DNA methylation. DNA methylation is controlled by DNA methyltransferases and other regulators, including histone modifiers and chromatin remodelers. RNAi machinery directs DNA methylation to euchromatic TEs, which is under developmental control. In addition to the epigenetic controls, some TEs are controlled by environmental factors. TEs often affect expression of nearby genes, providing evolutionary sources for epigenetic, developmental, and environmental gene controls, which could even be beneficial for the host.     

Diversity and evolution of transposable elements in Arabidopsis

Transposable elements are mobile genetic elements that have successfully populated eukaryotic genomes and show diversity in their structure and transposition mechanisms. Although first viewed solely as selfish, transposable elements are now known as important vectors to drive the adaptation and evolution of their host genome. Transposable elements can affect host gene structures, gene copy number, gene expression, and even as a source for novel genes. For example, a number of transposable element sequences have been co-opted to contribute to evolutionary innovation, such as the mammalian placenta and the vertebrate immune system. In plants, the need to adapt rapidly to changing environmental conditions is essential and is reflected, as will be discussed, by genome plasticity and an abundance of diverse, active transposon families. This review focuses on transposable elements in plants, particularly those that have beneficial effects on the host. We also emphasize the importance of having proper tools to annotate and classify transposons to better understand their biology.     

Meiotic chromosome synapsis and recombination in Arabidopsis thaliana: new ways of integrating cytological and molecular approaches

Meiosis is an evolutionary conserved mechanism that produces haploid gametes and is essential for the sexual reproduction of higher eukaryotes. Since the late nineteenth century, meiosis has been studied in plants due their large chromosomes compared with other organisms and due to advances in microscopy and cytological approaches. On the other hand, non-plant model organisms like budding yeast have been widely used recently in order to characterise the molecular and functional aspects of meiosis. Arabidopsis arose as a new meiotic model for plants during the last decade of the twentieth century. This emergence was sustained by different molecular and genetic advances, mainly by completing the full genome sequence in 2000. Since then, further development of molecular technologies and the cytological methodologies to analyse the meiotic dynamics in Arabidopsis have permitted researchers to establish plant meiosis at the forefront of international research. Some key plant meiotic recombination events have been established in Arabidopsis. These advances have placed researchers into the position to transfer their knowledge from this plant meiotic model to crops and are likely to have an impact on plant breeding and the development of agriculture in future years.     

Effects of intentionally treated water and seeds on the growth of Arabidopsis thaliana

Objective. A previously reported experiment indicated that Arabidopsis thaliana seeds with cryptochrome mutation His-CRY2 showed more robust photomorphogenic growth when hydrated with intentionally treated water as compared to untreated water. The present study attempted to replicate that outcome, adding a condition where the seeds were also intentionally treated. Arabidopsis seeds were used because they contain a photosensitive flavoprotein called cryptochrome (CRY). CRY has been proposed as a possible “transducer” of intention in living systems because it is thought to have quantum biological properties, and as such, it might potentially be sensitive to quantum observer effects.DesignThree Buddhist monks directed their attention toward commercially bottled water and Arabidopsis seeds while holding the intention to improve the growth of the plant. As a control condition, no attention was directed at water or seeds from the same sources. Under double-blinded conditions, treated and untreated seeds were placed in an incubator, hydrated with treated or untreated water, and exposed to either continuous blue light or blue plus far-red light. The seed germination process was repeated three times, each time using new seeds. A 2 × 2 × 2 ANOVA, with water, seeds, and light as factors, was used to analyze the results.Results. Treated water was associated with enhanced photomorphogenic growth, as reflected by a shorter hypocotyl length (p = 0.04) and greater amounts of chlorophyll (p = 0.0005) and anthocyanin (p = 2 × 10^?6). Treated seeds resulted in greater amounts of chlorophyll (p = 0.04), but also a longer hypocotyl (p = 0.0004) and less anthocyanin (p = 0.01). Plants exposed to blue plus far-red light were constantly more robust than plants grown under blue light, regardless of the type of water or seed (p < 10^?10).Conclusion. Intentionally treated water improved the growth of the His-CRY2 variant of Arabidopsis, confirming results of an earlier experiment. Enhanced growth associated with exposure to blue plus far-red light also confirmed to known effects. A more complex relationship was observed with treated seeds. Further research is required to understand the latter outcome, as it may provide clues about the underlying mechanisms of intentional influences.     

A subtilisin-like serine protease involved in the regulation of stomatal density and distribution in Arabidopsis thaliana

Stomata are specialized cellular structures in the epidermis of aerial plant organs that control gas exchange (H(2)O release and CO(2) uptake) between leaves and the atmosphere by modulating the aperture of a pore flanked by two guard cells. Stomata are nonrandomly distributed, and their density is controlled by endogenous and environmental factors. To gain insight into the molecular mechanisms regulating stomatal distribution, Arabidopsis thaliana mutants with altered stomatal characteristics were isolated and examined. The sdd1-1 mutant exhibits a two- to fourfold increase of stomatal density and formation of clustered stomata (i.e., stomata that are not separated by intervening pavement cells), whereas the internal leaf architecture is not altered. The SDD1 gene was identified by map-based cloning. It encodes a subtilisin-like serine protease related to prokaryotic and eukaryotic proteins. We propose that SDD1 acts as a processing protease involved in the mediation of a signal that controls the development of cell lineages that lead to guard cell formation.     

Patterns of positive selection in the complete NBS-LRR gene family of Arabidopsis thaliana

Plant disease resistance genes have been shown to be subject to positive selection, particularly in the leucine rich repeat (LRR) region that may determine resistance specificity. We performed a genome-wide analysis of positive selection in members of the nucleotide binding site (NBS)-LRR gene family of Arabidopsis thaliana. Analyses were possible for 103 of 163 NBS-LRR nucleotide sequences in the genome, and the analyses uncovered substantial evidence of positive selection. Sites under positive selection were detected and identified for 10 sequence groups representing 53 NBS-LRR sequences. Functionally characterized Arabidopsis resistance genes were in these 10 groups, but several groups with extensive evidence of positive selection contained no previously characterized resistance genes. Amino acid residues under positive selection were identified, and these residues were mapped onto protein secondary structure. Positively selected positions were disproportionately located in the LRR domain (P < 0.001), particularly a nine-amino acid beta-strand submotif that is likely to be solvent exposed. However, a substantial proportion (30%) of positively selected sites were located outside LRRs, suggesting that regions other than the LRR may function in determining resistance specificity. Because of the unusual sequence variability in the LRRs of this class of proteins, secondary-structure analysis identifies LRRs that are not identified by similarity analyses alone. LRRs also contain substantial indel variation, suggesting elasticity in LRR length could also influence resistance specificity.     

Composition and formation of heterochromatin in Arabidopsis thaliana

The term heterochromatin has been applied to both large-scale, microscopically visible chromocentres and small-scale, silent genes located outside chromocentres. This may cause confusion in the interpretation of epigenetic marks for both features. The model plant Arabidopsis thaliana provides an excellent system to investigate composition and function of chromatin states at different levels of organization. In this review we will discuss recent developments in molecular networks underlying gene silencing and the relationship with visible heterochromatin in Arabidopsis.     

Heterochromatin in interphase nuclei of Arabidopsis thaliana

The eukaryotic nucleus represents a complex arrangement of heterochromatic and euchromatic domains, each with their specific nuclear functions. Somatic cells of a multicellular organism are genetically identical, yet they may differ completely in nuclear organization and gene expression patterns. Stable changes in gene expression without modifying the sequence are the result of epigenetic changes and include covalent modifications in cytosine residues of DNA and in histone tails giving rise to altered chromatin protein complexes, remodeling of chromatin and changes in chromatin compaction. Large-scale differences in chromatin structure are visible at the microscopic level as euchromatin and heterochromatin. Arabidopsis thaliana chromosomes display a relatively simple distribution of euchromatic and heterochromatic segments overlapping with gene-rich and repeat-rich regions, respectively. Recently, we have shown that Arabidopsis provides a well-defined system to study individual chromosomes and chromatin domains in interphase nuclei as well as the relationship between chromatin condensation and epigenetic mechanisms of gene silencing. This overview focuses on the organization and composition of heterochromatin in Arabidopsis nuclei.     

Presence of a chloroplast-like elongator tRNAMet gene in the mitochondrial genomes of soybean and Arabidopsis thaliana

Summary The nucleotide sequence of elongator tRNA^Met genes from soybean chloroplast and mitochondria and Arabidopsis thaliana mitochondria have been determined. The mitochondrial tRNA^Met genes from soybean and A. thaliana are identical, and they differ from the soybean chloroplast tRNA^Met gene by only four nucleotides. Analysis of the flanking regions indicates that the mitochondrial tRNA^Met gene is not present on a large chloroplast DNA insertion in the mitochondrial genome, but it suggests that they have a common origin. Comparison of the three genes and the evolutionary implications are discussed.     

Control of final seed and organ size by the DA1 gene family in Arabidopsis thaliana

Although the size of an organism is a defining feature, little is known about the mechanisms that set the final size of organs and whole organisms. Here we describe Arabidopsis DA1, encoding a predicted ubiquitin receptor, which sets final seed and organ size by restricting the period of cell proliferation. The mutant protein encoded by the da1-1 allele has a negative activity toward DA1 and a DA1-related (DAR) protein, and overexpression of a da1-1 cDNA dramatically increases seed and organ size of wild-type plants, identifying this small gene family as important regulators of seed and organ size in plants.     

Variation in crossing-over rates across chromosome 4 of Arabidopsis thaliana reveals the presence of meiotic recombination "hot spots"

Crossover (CO) is a key process for the accurate segregation of homologous chromosomes during the first meiotic division. In most eukaryotes, meiotic recombination is not homogeneous along the chromosomes, suggesting a tight control of the location of recombination events. We genotyped 71 single nucleotide polymorphisms (SNPs) covering the entire chromosome 4 of Arabidopsis thaliana on 702 F2 plants, representing 1404 meioses and allowing the detection of 1171 COs, to study CO localization in a higher plant. The genetic recombination rates varied along the chromosome from 0 cM/Mb near the centromere to 20 cM/Mb on the short arm next to the NOR region, with a chromosome average of 4.6 cM/Mb. Principal component analysis showed that CO rates negatively correlate with the G+C content (P = 3x10(-4)), in contrast to that reported in other eukaryotes. COs also significantly correlate with the density of single repeats and the CpG ratio, but not with genes, pseudogenes, transposable elements, or dispersed repeats. Chromosome 4 has, on average, 1.6 COs per meiosis, and these COs are subjected to interference. A detailed analysis of several regions having high CO rates revealed "hot spots" of meiotic recombination contained in small fragments of a few kilobases. Both the intensity and the density of these hot spots explain the variation of CO rates along the chromosome.     

Effects of the rad52 gene on sister chromatid recombination in Saccharomyces cerevisiae

Summary Spontaneous and UV induced unequal mitotic sister chromatid recombination was examined in RAD+ and rad52-1 strains carrying the LEU2 gene inserted in the rDNA locus. The rad52-1 mutation does not affect spontaneous sister chromatid recombination but greatly reduces the frequency of UV induced sister chromatid recombination.     

Genetic architecture of regulatory variation in Arabidopsis thaliana

Studying the genetic regulation of expression variation is a key method to dissect complex phenotypic traits. To examine the genetic architecture of regulatory variation in Arabidopsis thaliana, we performed genome-wide association (GWA) mapping of gene expression in an F(1) hybrid diversity panel. At a genome-wide false discovery rate (FDR) of 0.2, an associated single nucleotide polymorphism (SNP) explains >38% of trait variation. In comparison with SNPs that are distant from the genes to which they were associated, locally associated SNPs are preferentially found in regions with extended linkage disequilibrium (LD) and have distinct population frequencies of the derived alleles (where Arabidopsis lyrata has the ancestral allele), suggesting that different selective forces are acting. Locally associated SNPs tend to have additive inheritance, whereas distantly associated SNPs are primarily dominant. In contrast to results from mapping of expression quantitative trait loci (eQTL) in linkage studies, we observe extensive allelic heterogeneity for local regulatory loci in our diversity panel. By association mapping of allele-specific expression (ASE), we detect a significant enrichment for cis-acting variation in local regulatory variation. In addition to gene expression variation, association mapping of splicing variation reveals both local and distant genetic regulation for intron and exon level traits. Finally, we identify candidate genes for 59 diverse phenotypic traits that were mapped to eQTL.     

A cis element in the recombination activating gene locus regulates gene expression by counteracting a distant silencer

We have identified a silencer and an antisilencing element that interact at a distance of 85 kilobases to regulate expression of the recombination activating genes Rag1 and Rag2 in thymocytes. Transgenic experiments showed that Rag promoter-proximal cis elements directed tissue-specific expression and that a Runx-dependent intergenic silencer suppressed expression in developing T cells. Deletion of the antisilencing element from the genomic Rag locus unmasked the intergenic silencer and abrogated Rag expression in developing CD4(+)CD8(+) T cells. We speculate that the Rag antisilencing element belongs to a class of cis elements that might be useful for genome diversification by activating genes encoded by otherwise silent transposable elements.