MicroRNAs and trans-acting siRNAs (ta-siRNAs) have important regulatory roles in development. Unlike other developmentally important regulatory molecules, small RNAs are not known to act as mobile signals during development. Here, we show that low-abundant, conserved ta-siRNAs, termed tasiR-ARFs, move intercellularly from their defined source of biogenesis on the upper (adaxial) side of leaves to the lower (abaxial) side to create a gradient of small RNAs that patterns the abaxial determinant AUXIN RESPONSE FACTOR3. Our observations have important ramifications for the function of small RNAs and suggest they can serve as mobile, instructive signals during development.Supplemental material is available at http://www.genesdev.org.Received December 7, 2008; revised version accepted January 21, 2009. Small RNAs, such as microRNAs (miRNAs), trans-acting siRNAs (ta-siRNAs), and endogenous siRNAs, regulate diverse developmental processes in multicellular organisms. The comprehensive role of these small RNAs in mediating development is best visualized by their complex and varied expression patterns (Juarez et al. 2004;Wienholds et al. 2005;Nogueira et al. 2007). However, the mechanisms underlying the origins of these discrete accumulation patterns remain largely obscure. Direct localization of miRNA primary transcripts suggests that this complexity arises in part from transcriptional control (Aboobaker et al. 2005;Nogueira et al. 2009). Additionally, the post-transcriptional processing of small RNA precursors is contingent upon the presence of necessary biogenesis factors, the restricted activity of which can contribute to the final spatiotemporal localization of mature small RNAs (Viswanathan et al. 2008). The intercellular movement of small RNAs could also feasibly contribute to their final localization patterns. However, even though the movement of siRNAs during systemic silencing is a well-documented phenomenon (Dunoyer et al. 2005;Voinnet 2005), no instances of intercellular movement of endogenous small RNAs have as of yet been reported (Parizotto et al. 2004;Alvarez et al. 2006). ta-siRNAs, a plant-specific small RNA class with roles in development, depend for their biogenesis on both miRNA activity and siRNA pathway components (Peragine et al. 2004;Vazquez et al. 2004;Allen et al. 2005). miRNAguided cleavage triggers entry of ta-siRNA precursor transcripts into RNA-DEPENDENT RNA POLYMER-ASE6 (RDR6)-dependent and SUPPRESSOR OF GENE SILENCING3 (SGS3)-dependent pathways and sets the register for phased, 21 nucleotide ta-siRNA production by DICER-LIKE4 ( Phenotypes resulting from mutations in TAS3 ta-siRNA biogenesis factors are mediated through the misregulation of tasiR-ARF targets, especially ARF3. Expression of ARF3 trangenes insensitive to tasiR-ARF regulation produce vegetative phase change defects similar to tasiR-ARF pathway mutations (Fahlgren et al. 2006;Hunter et al. 2006). The range of pleiotropic defects observed in such plants demonstrates the importance of this pathway to multiple aspects of leaf d...
Although applied over extremely short timescales, artificial selection has dramatically altered the form, physiology, and life history of cultivated plants. We have used RNAseq to define both gene sequence and expression divergence between cultivated tomato and five related wild species. Based on sequence differences, we detect footprints of positive selection in over 50 genes. We also document thousands of shifts in gene-expression level, many of which resulted from changes in selection pressure. These rapidly evolving genes are commonly associated with environmental response and stress tolerance. The importance of environmental inputs during evolution of gene expression is further highlighted by large-scale alteration of the light response coexpression network between wild and cultivated accessions. Human manipulation of the genome has heavily impacted the tomato transcriptome through directed admixture and by indirectly favoring nonsynonymous over synonymous substitutions. Taken together, our results shed light on the pervasive effects artificial and natural selection have had on the transcriptomes of tomato and its wild relatives.domestication | biotic stress | abiotic stress D omestication has long served as an important example of severe phenotypic divergence in response to selection. Darwin recognized the parallel between the processes of domestication and adaptation in the wild and used this analogy to emphasize the power of selection in generating phenotypic diversity (1). The genetic basis of domestication-associated phenotypes has been examined in several instances, most notably in maize, rice, tomato, and dogs (reviewed in refs. 2-5). The clear conclusion from these studies is that the rapid phenotypic divergence associated with domestication is often attributable to very few genetic loci (6). Improvements to DNA sequence technologies have allowed studies of the effect of domestication at the whole-genome level. Early population genetic analyses in maize found that very few genes (∼5%) show evidence of positive selection during domestication of maize (7), and recent work using whole-genome resequencing has found a similar proportion of the genome was under positive selection (8). Evidence for strong selective sweeps at a limited number of loci has also been found in rice and dog genomes (9). Together with the previous genetic mapping work, these studies support the model that relatively few mutations experienced extremely strong selection by humans during domestication.Although not the target of direct positive selection, the rest of the genome still experiences a dramatic shift in evolutionary pressures during domestication. Most characterized domestication events are associated with an extreme genetic bottleneck and alleviation of selective constraints in the original niche (10). These factors are predicted to increase the relative rate of nonsynonymous to synonymous (dN/dS) substitution, potentially resulting in the fixation of deleterious alleles (11). Previous studies comparing the distribution ...
Introgression lines (ILs), in which genetic material from wild tomato species is introgressed into a domesticated background, have been used extensively in tomato (Solanum lycopersicum) improvement. Here, we genotype an IL population derived from the wild desert tomato Solanum pennellii at ultrahigh density, providing the exact gene content harbored by each line. To take advantage of this information, we determine IL phenotypes for a suite of vegetative traits, ranging from leaf complexity, shape, and size to cellular traits, such as stomatal density and epidermal cell phenotypes. Elliptical Fourier descriptors on leaflet outlines provide a global analysis of highly heritable, intricate aspects of leaf morphology. We also demonstrate constraints between leaflet size and leaf complexity, pavement cell size, and stomatal density and show independent segregation of traits previously assumed to be genetically coregulated. Meta-analysis of previously measured traits in the ILs shows an unexpected relationship between leaf morphology and fruit sugar levels, which RNA-Seq data suggest may be attributable to genetically coregulated changes in fruit morphology or the impact of leaf shape on photosynthesis. Together, our results both improve upon the utility of an important genetic resource and attest to a complex, genetic basis for differences in leaf morphology between natural populations.
Small RNAs are important regulators of gene expression. In maize, adaxial/abaxial (dorsoventral) leaf polarity is established by an abaxial gradient of microRNA166 (miR166), which spatially restricts the expression domain of class III homeodomain leucine zipper (HD-ZIPIII) transcription factors that specify adaxial/upper fate. Here, we show that leafbladeless1 encodes a key component in the trans-acting small interfering RNA (ta-siRNA) biogenesis pathway that acts on the adaxial side of developing leaves and demarcates the domains of hd-zipIII and miR166 accumulation. Our findings indicate that tasiR-ARF, a ta-siRNA, and miR166 establish opposing domains along the adaxial-abaxial axis, thus revealing a novel mechanism of pattern formation.Supplemental material is available at www.genesdev.org.Received January 8, 2007; revised version accepted February 20, 2007. In both animals and plants, many developmentally important regulatory genes are predicted targets of microRNAs (miRNAs), which suggests that such small RNAs constitute a class of developmental determinants (Alvarez-Garcia and Miska 2005;Jones-Rhoades et al. 2006). Patterning and outgrowth of lateral organs in plants depend on the specification of adaxial/abaxial (dorsoventral) polarity in the incipient primordium. This asymmetry is established through the polarized expression of class III homeodomain leucine zipper (HD-ZIPIII) transcription factors that specify adaxial/upper cell fate (McConnell et al. 2001;Emery et al. 2003;Juarez et al. 2004a). The adaxial-specific expression of hd-zipIII family members is delineated by the expression pattern of a 21-nucleotide (nt) miRNA, miR166, which directs the cleavage of hd-zipIII transcripts (Juarez et al. 2004a;Kidner and Martienssen 2004). In maize, miR166 accumulates most abundantly immediately below the incipient leaf, but a gradient of miR166 extends into the abaxial side of the initiating organ that establishes organ polarity (Juarez et al. 2004a).Specification of adaxial/abaxial organ polarity in maize also requires the activity of leafbladeless1 (lbl1). Recessive mutations in lbl1 lead to a variable abaxialization of leaves (Timmermans et al. 1998). The weak lbl1-ref allele causes a partial loss of adaxial identity revealed as patches of abaxial cells on the upper leaf surface, whereas leaves of the severe ragged seedling1 allele (lbl1-rgd1) are often radially symmetric and completely abaxialized (Fig. 1A). Expression of the hd-zipIII family member rld1 is reduced in lbl1 mutants. Conversely, increased levels of hd-zipIII expression in Rld1-O mutants, which carry a miR166-insensitive allele of rld1, can fully suppress the vegetative defects of lbl1 (Juarez et al. 2004b). lbl1 thus contributes to organ polarity by regulating the accumulation of rld1 transcripts on the adaxial side of the developing leaf.Here, we show that lbl1 encodes a homolog of SUPPRESSOR-OF-GENE-SILENCING3 (SGS3), which is specifically required for the biogenesis of trans-acting small interfering RNAs (ta-siRNAs) (Peragine et al. 2...
Small interfering RNA (siRNA) guides dimethylation of histone H3 lysine-9 (H3K9me2) via the Argonaute and RNA-dependent RNA polymerase complexes, as well as base-pairing with either RNA or DNA. We show that Argonaute requires the conserved aspartate-aspartate-histidine motif for heterochromatic silencing and for ribonuclease H-like cleavage (slicing) of target messages complementary to siRNA. In the fission yeast Schizosaccharomyces pombe, heterochromatic repeats are transcribed by polymerase II. We show that H3K9me2 spreads into silent reporter genes when they are embedded within these transcripts and that spreading requires read-through transcription, as well as slicing by Argonaute. Thus, siRNA guides histone modification by basepairing interactions with RNA.
A key feature of RNA interference is its ability to spread from cell to cell. Such non-cell-autonomous gene silencing has been characterized extensively in both plants and animals, but the identity of the mobile silencing signal has remained elusive. Several recent studies now shed light on the identity of this signal in plants, and indicate that small RNA molecules-from short-interfering RNAs to microRNAs-are capable of moving between cells and through the vasculature. The movement of small, 21-24-nucleotide RNA species has implications for biological processes ranging from developmental patterning and stress responses to epigenetic inheritance.
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