Darwin's "Abominable Mystery": the role of RNA interference in the evolution of flowering plants

Darwin was famously concerned that the sudden appearance and rapid diversification of flowering plants in the mid-Cretaceous could not have occurred by gradual change. Here, we review our attempts to resolve the relationships among the major seed plant groups, i.e., cycads, ginkgo, conifers, gnetophytes, and flowering plants, and to provide a pipeline in which these relationships can be used as a platform for identifying genes of functional importance in plant diversification. Using complete gene sets and unigenes from 16 plant species, genes with positive partitioned Bremer support at major nodes were used to identify overrepresented gene ontology (GO) terms. Posttranscriptional silencing via RNA interference (RNAi) was overrepresented at several major nodes, including between monocots and dicots during early angiosperm divergence. One of these genes, RNA-dependent RNA polymerase 6, is required for the biogenesis of trans-acting small interfering RNA (tasiRNA), confers heteroblasty and organ polarity, and restricts maternal specification of the germline. Processing of small RNA and transfer between neighboring cells underlies these roles and may have contributed to distinct mutant phenotypes in plants, and in particular in the early split of the monocots and eudicots

Nucleolar dominance and DNA methylation directed by small interfering RNA

In the December 5th issue of Molecular Cell, Preuss et al. (2008) demonstrated a link between small interfering RNA (siRNA)-directed de novo DNA methylation and rDNA silencing in nucleolar dominance

ASYMMETRIC LEAVES1 reveals knox gene redundancy in Arabidopsis

The shoot apical meristem comprises undifferentiated stem cells and their derivatives, which include founder cells for lateral organs such as leaves. Meristem maintenance and lateral organ specification are regulated in part by negative interactions between the myb domain transcription factor ASYMMETRIC LEAVES1, which is expressed in lateral organ primordia, and homeobox transcription factors which are expressed in the shoot apical meristem (knox genes). The knox gene SHOOT MERISTEMLESS (STAT) negatively regulates ASYMMETRIC LEAVES1 (AS1) which, in turn, negatively, regulates other knox genes including KNAT1 and KNAT2, and positively regulates the novel gene LATERAL ORGAN BOUNDARIES (LOB). Genetic interactions with a second gene, ASYMMETRIC LEAVES2 (AS2), indicate it acts at the same position in this hierarchy as AS1. We have used a second-site suppressor screen to isolate mutations in KNAT1 and we show that KNAT1 is partially redundant with STM in regulating stem cell function. Mutations in KNAT2 show no such interaction. We discuss the regulation and evolution of redundancy among knox genes

Sequencing the maize genome

Sequencing of complex genomes can be accomplished by enriching shotgun libraries for genes. In maize, gene-enrichment by copy-number normalization (high C(0)t) and methylation filtration (MF) have been used to generate up to two-fold coverage of the gene-space with less than 1 million sequencing reads. Simulations using sequenced bacterial artificial chromosome (BAC) clones predict that 5x coverage of gene-rich regions, accompanied by less than 1x coverage of subclones from BAC contigs, will generate high-quality mapped sequence that meets the needs of geneticists while accommodating unusually high levels of structural polymorphism. By sequencing several inbred strains, we propose a strategy for capturing this polymorphism to investigate hybrid vigor or heterosis

Noncoding RNAs and gene silencing

Noncoding RNA has long been proposed to control gene expression via sequence-specific interactions with regulatory regions. Here, we review the role of noncoding RNA in heterochromatic silencing and in the silencing of transposable elements (TEs), unpaired DNA in meiosis, and developmentally excised DNA. The role of cotranscriptional processing by RNA interference and by other mechanisms is discussed, as well as parallels with RNA silencing in imprinting, paramutation, polycomb silencing, and X inactivation. Interactions with regulatory sequences may well occur, but at the RNA rather than at the DNA level

Somatically heritable switches in the DNA modification of Mu transposable elements monitored with a suppressible mutant in maize

Many transposable elements in maize alternate between active and inactive phases associated with the modification of their DNA. Elements in an inactive phase lose their ability to transpose, their ability to excise from reporter alleles and, in some cases, their ability to enhance or suppress mutant phenotypes caused by their insertion. The maize mutant hcf106 is a recessive pale green seedling lethal caused by the insertion of the transposable element Mu1. We show that the hcf106 mutant phenotype is suppressed in lines that have lost Mu activity. That is, homozygous hcf106 seedlings are dark green and viable when transposable elements belonging to the Robertson's Mutator family are modified in their terminal inverted repeats, a diagnostic feature of inactive lines. This property of the mutant phenotype has been used to follow clonal leaf sectors containing modified Mu elements that arise from single somatic cells during plant development. The distribution of these sectors indicates that epigenetic switches involving Mu DNA modification occur progressively as the meristem ages

Phyllotactic pattern and stem cell fate are determined by the Arabidopsis homeobox gene BELLRINGER

Lateral organs in plants arise from the meristem in a stereotypical pattern known as phyllotaxy. Spiral patterns result from initiation of successive organs at a fixed angle of divergence but variable patterns of physical contact. Such patterns ultimately give rise to individual leaves and flowers at positions related to each other by consecutive terms in the mathematical series first described by Leonardo Fibonacci. We demonstrate that a BELL1 related homeodomain protein in Arabidopsis, BELLRINGER, maintains the spiral phyllotactic pattern. In the absence of BELLRINGER, the regular pattern of organ initiation is disturbed and lateral organs are initiated more frequently. BELLRINGER is also required for maintenance of stem cell fate in the absence of the regulatory genes SHOOT MERISTEMLESS and ASYMMETRIC LEAVES1. We propose a model whereby BELLRINGER coordinates the maintenance of stem cells with differentiation of daughter cells in stem cell lineages

The essential Mcm7 protein PROLIFERA is localized to the nucleus of dividing cells during the G(1) phase and is required maternally for early Arabidopsis development

PROLIFERA (PRL) encodes a homologue of the DNA replication licensing factor Mcm7, a highly conserved protein found in all eukaryotes. Insertions in the PROLIFERA gene are lethal, resulting in decreased transmission through the female gametophyte, and homozygous embryonic lethality. We show here that PROLIFERA is specifically expressed in populations of dividing cells in sporophytic tissues of the plant body, such as the palisade layer of the leaf and founder cells of initiating flower primordia, Gene fusions with the green fluorescent protein (GFP) reveal that the PROLIFERA protein accumulates during the G(1) phase of the cell cycle, and is transiently localized to the nucleus. During mitosis, the fusion protein rapidly disappears, returning to daughter nuclei during G(1), PROLIFERA::GUS fusions are strongly expressed in the central cell nucleus of mature megagametophytes, which have a variety of arrest points reflecting a leaky lethality. Expression is also observed in the endosperm of mutant prl embryo sacs that arrest following fertilization. Crosses with wild-type pollen result in occasional embryonic lethals that also stain for GUS activity, In contrast, embryos resulting from crosses of wild-type carpels with PRL::GUS pollen do not stain and are phenotypically normal. In situ hybridization of GUS fusion RNA indicates transcription is equivalent from maternally and paternally derived alleles, so that accumulation of maternally derived gametophytic protein is likely to be responsible for the 'maternal' effect

MicroRNA activity in the Arabidopsis male germline

Most of the core proteins involved in the microRNA (miRNA) pathway in plants have been identified, and almost simultaneously hundreds of miRNA sequences processed in the Arabidopsis sporophyte have been discovered by exploiting next-generation sequencing technologies. However, there is very limited understanding about potentially distinct mechanisms of post-transcriptional regulation between different cell lineages. In this review the focus is on the Arabidopsis male gametophyte (pollen), where the germline differentiates after meiosis giving rise to the male gametes. Based on comparative analysis of miRNAs identified in sperm cells by in-depth sequencing, their possible functions during germ cell specification and beyond fertilization are discussed. In addition, 25 potentially novel miRNAs processed in sperm cells and pollen were identified, as well as enriched variations in the sequence length of known miRNAs, which might indicate subfunctionalization by association with a putative germline-specific Argonaute complex. ARGONAUTE 5 (AGO5), by close homology to AGO1 and localizing preferentially to the sperm cell cytoplasm in mature pollen, may be part of such a complex