Carla Schommer scite author profile

Plants with altered microRNA metabolism have pleiotropic developmental defects, but direct evidence for microRNAs regulating specific aspects of plant morphogenesis has been lacking. In a genetic screen, we identified the JAW locus, which produces a microRNA that can guide messenger RNA cleavage of several TCP genes controlling leaf development. MicroRNA-guided cleavage of TCP4 mRNA is necessary to prevent aberrant activity of the TCP4 gene expressed from its native promoter. In addition, overexpression of wild-type and microRNA-resistant TCP variants demonstrates that mRNA cleavage is largely sufficient to restrict TCP function to its normal domain of activity. TCP genes with microRNA target sequences are found in a wide range of species, indicating that microRNA-mediated control of leaf morphogenesis is conserved in plants with very different leaf forms.Although much is known about how organs acquire their particular fate, we are only starting to learn how organs are sculpted, even if they are just flat sheets such as wings or leaves. An elegant study recently demonstrated that making a flat organ is not a trivial problem: snapdragon leaves are normally flat, but they become crinkly in plants lacking the CINCINNATA (CIN) gene 1 . In cin mutants, differential regulation of cell division across the leaf is disturbed, causing negative leaf curvature. CIN RNA itself is expressed in a dynamic pattern, in front of and perhaps overlapping the mitotic arrest zone, suggesting a direct role of CIN in regulating leaf morphogenesis.Although it is unknown how expression of CIN, which encodes a TCP transcription factor 2 , is regulated, a specific RNA pattern can result from differential transcription or changes in transcript stability. A post-transcriptional mechanism that has only recently been recognized is that of plant mRNA cleavage initiated by partially or fully complementary microRNAs (miRNAs) 3,4 . The mechanism of cleavage is similar, or identical, to cleavage guided by short interfering RNAs (siRNAs) 5 .The double-stranded ribonucleases Dicer in animals and DICER-LIKE1 (DCL1) in plants process miRNAs-which are usually 21-22 nucleotides long-from longer precursor RNAs with fold-back structure 4,6,7 . Additional factors required for accumulation of miRNAs include members of the Argonaute family and HEN1 protein 8,9 . The importance of miRNAs for plant development is supported by the abnormalities seen in several mutants or transgenic plants with general defects in miRNA accumulation or activity [9][10][11][12] . However, although biochemical studies have demon- Fig. 2b). b, Seedlings, individual leaves and leaf rosettes of Columbia wild-type and jaw-1D plants. Leaves were mounted between glass plates and illuminated from below. Dark green areas indicate overlapping leaf parts after flattening. c, Expression changes of TCP genes in jaw-1D estimated from Affymetrix arrays (grey bars) or from RT-qPCR (black bars). See Supplementary Information for absolute values. NP, termed 'not present' by MAS software. Note th...

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Specific Effects of MicroRNAs on the Plant Transcriptome

Schwab

et al. 2005

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Most plant microRNAs (miRNAs) have perfect or near-perfect complementarity with their targets. This is consistent with their primary mode of action being cleavage of target mRNAs, similar to that induced by perfectly complementary small interfering RNAs (siRNAs). However, there are natural targets with up to five mismatches. Furthermore, artificial siRNAs can have substantial effects on so-called off-targets, to which they have only limited complementarity. By analyzing the transcriptome of plants overexpressing different miRNAs, we have deduced a set of empirical parameters for target recognition. Compared to artificial siRNAs, authentic plant miRNAs appear to have much higher specificity, which may reflect their coevolution with the remainder of the transcriptome. We also demonstrate that miR172, previously thought to act primarily by translational repression, can efficiently guide mRNA cleavage, although the effects on steady-state levels of target transcripts are obscured by strong feedback regulation. This finding unifies the view of plant miRNA action.

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Control of Jasmonate Biosynthesis and Senescence by miR319 Targets

et al. 2008

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Considerable progress has been made in identifying the targets of plant microRNAs, many of which regulate the stability or translation of mRNAs that encode transcription factors involved in development. In most cases, it is unknown, however, which immediate transcriptional targets mediate downstream effects of the microRNA-regulated transcription factors. We identified a new process controlled by the miR319-regulated clade of TCP (TEOSINTE BRANCHED/CYCLOIDEA/PCF) transcription factor genes. In contrast to other miRNA targets, several of which modulate hormone responses, TCPs control biosynthesis of the hormone jasmonic acid. Furthermore, we demonstrate a previously unrecognized effect of TCPs on leaf senescence, a process in which jasmonic acid has been proposed to be a critical regulator. We propose that miR319-controlled TCP transcription factors coordinate two sequential processes in leaf development: leaf growth, which they negatively regulate, and leaf senescence, which they positively regulate.

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Control of cell proliferation in Arabidopsis thaliana by microRNA miR396

et al. 2010

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SUMMARYCell proliferation is an important determinant of plant form, but little is known about how developmental programs control cell division. Here, we describe the role of microRNA miR396 in the coordination of cell proliferation in Arabidopsis leaves. In leaf primordia, miR396 is expressed at low levels that steadily increase during organ development. We found that miR396 antagonizes the expression pattern of its targets, the GROWTH-REGULATING FACTOR (GRF) transcription factors. miR396 accumulates preferentially in the distal part of young developing leaves, restricting the expression of GRF2 to the proximal part of the organ. This, in turn, coincides with the activity of the cell proliferation marker CYCLINB1;1. We show that miR396 attenuates cell proliferation in developing leaves, through the repression of GRF activity and a decrease in the expression of cell cycle genes. We observed that the balance between miR396 and the GRFs controls the final number of cells in leaves. Furthermore, overexpression of miR396 in a mutant lacking GRF-INTERACTING FACTOR 1 severely compromises the shoot meristem. We found that miR396 is expressed at low levels throughout the meristem, overlapping with the expression of its target, GRF2. In addition, we show that miR396 can regulate cell proliferation and the size of the meristem. Arabidopsis plants with an increased activity of the transcription factor TCP4, which reduces cell proliferation in leaves, have higher miR396 and lower GRF levels. These results implicate miR396 as a significant module in the regulation of cell proliferation in plants.

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Carla Schommer

Control of leaf morphogenesis by microRNAs

Specific Effects of MicroRNAs on the Plant Transcriptome

Control of Jasmonate Biosynthesis and Senescence by miR319 Targets

Control of cell proliferation in Arabidopsis thaliana by microRNA miR396

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