ROSINA (RSI), a novel protein with DNA-binding capacity, acts during floral organ development in Antirrhinum majus

Impact of transposable elements on the evolution of complex living systems and their epigenetic control

Transposable elements (TEs) contribute to genomic innovations, as well as genome instability, across a wide variety of species. Popular designations such as 'selfish DNA' and 'junk DNA,' common in the 1980s, may be either inaccurate or misleading, while a more enlightened view of the TE-host relationship covers a range from parasitism to mutualism. Both plant and animal hosts have evolved epigenetic mechanisms to reduce the impact of TEs, both by directly silencing them and by reducing their ability to transpose in the genome. However, TEs have also been co-opted by both plant and animal genomes to perform a variety of physiological functions, ranging from TE-derived proteins acting directly in normal biological functions to innovations in transcription factor activity and also influencing gene expression. Their presence, in fact, can affect a range of features at genome, phenotype, and population levels. The impact TEs have had on evolution is multifaceted, and many aspects still remain unexplored. In this review, the epigenetic control of TEs is contextualized according to the evolution of complex living systems.

A noncanonical auxin-sensing mechanism is required for organ morphogenesis in Arabidopsis

Tissue patterning in multicellular organisms is the output of precise spatio-temporal regulation of gene expression coupled with changes in hormone dynamics. In plants, the hormone auxin regulates growth and development at every stage of a plant's life cycle. Auxin signaling occurs through binding of the auxin molecule to a TIR1/AFB F-box ubiquitin ligase, allowing interaction with Aux/IAA transcriptional repressor proteins. These are subsequently ubiquitinated and degraded via the 26S proteasome, leading to derepression of auxin response factors (ARFs). How auxin is able to elicit such a diverse range of developmental responses through a single signaling module has not yet been resolved. Here we present an alternative auxin-sensing mechanism in which the ARF ARF3/ETTIN controls gene expression through interactions with process-specific transcription factors. This noncanonical hormone-sensing mechanism exhibits strong preference for the naturally occurring auxin indole 3-acetic acid (IAA) and is important for coordinating growth and patterning in diverse developmental contexts such as gynoecium morphogenesis, lateral root emergence, ovule development, and primary branch formation. Disrupting this IAA-sensing ability induces morphological aberrations with consequences for plant fitness. Therefore, our findings introduce a novel transcription factor-based mechanism of hormone perception in plants.

What makes up plant genomes: The vanishing line between transposable elements and genes

The ultimate source of evolution is mutation. As the largest component in plant genomes, transposable elements (TEs) create numerous types of mutations that cannot be mimicked by other genetic mechanisms. When TEs insert into genomic sequences, they influence the expression of nearby genes as well as genes unlinked to the insertion. TEs can duplicate, mobilize, and recombine normal genes or gene fragments, with the potential to generate new genes or modify the structure of existing genes. TEs also donate their transposase coding regions for cellular functions in a process called TE domestication. Despite the host defense against TE activity, a subset of TEs survived and thrived through discreet selection of transposition activity, target site, element size, and the internal sequence. Finally, TEs have established strategies to reduce the efficacy of host defense system by increasing the cost of silencing TEs. This review discusses the recent progress in the area of plant TEs with a focus on the interaction between TEs and genes.

A transposon-mediate inactivation of a CYCLOIDEA-like gene originates polysymmetric and androgynous ray flowers in Helianthus annuus

In several eudicots, including members of the Asteraceae family, the CYCLOIDEA (CYC) genes, which belong to the TCP class of transcription factors, are key players for floral symmetry. The sunflower inflorescence is heterogamous (radiate capitulum) with sterile monosymmetric ray flowers located in the outermost whorl of the inflorescence and hermaphrodite polysymmetric disk flowers. In inflorescence of Heliantheae tribe, flower primordia development initiates from the marginal ray flowers while disk flowers develop later in an acropetal fashion in organized parastichies along a number found to be one of Fibonacci patterns. Mutants for inflorescence morphology can provide information on the role of CYC-like genes in radiate capitulum evolution. The tubular ray flower (turf) mutant of sunflower shows hermaphrodite ray flowers with a nearly polysymmetric tubular-like corolla. Here, we demonstrate that this mutation is caused by the insertion in the TCP motif of a sunflower CYC-like gene (HaCYC2c) of non-autonomous transposable element (TE), belonging to the CACTA superfamily of transposons. We named this element Transposable element of turf1 (Tetu1). The Tetu1 insertion changes the reading frame of turf-HaCYC2c for the encoded protein and leads to a premature stop codon. Although in Tetu1 a transposase gene is lacking, our results clearly suggest that it is an active TE. The excision of Tetu1 restores the wild type phenotype or generates stable mutants. Co-segregation and sequence analysis in progenies of F(2) and self-fertilized plants derived from reversion of turf to wild type clearly identify HaCYC2c as a key regulator of ray flowers symmetry. Also, HaCYC2c loss-of-function promotes the developmental switch from sterile to hermaphrodite flowers, revealing a novel and unexpected role for a CYC-like gene in the repression of female organs.

The CACTA transposon Bot1 played a major role in Brassica genome divergence and gene proliferation

We isolated and characterized a Brassica C genome-specific CACTA element, which was designated Bot1 (Brassica oleracea transposon 1). After analysing phylogenetic relationships, copy numbers and sequence similarity of Bot1 and Bot1 analogues in B. oleracea (C genome) versus Brassica rapa (A genome), we concluded that Bot1 has encountered several rounds of amplification in the oleracea genome only, and has played a major role in the recent rapa and oleracea genome divergence. We performed in silico analyses of the genomic organization and internal structure of Bot1, and established which segment of Bot1 is C-genome specific. Our work reports a fully characterized Brassica repetitive sequence that can distinguish the Brassica A and C chromosomes in the allotetraploid Brassica napus, by fluorescent in situ hybridization. We demonstrated that Bot1 carries a host S locus-associated SLL3 gene copy. We speculate that Bot1 was involved in the proliferation of SLL3 around the Brassica genome. The present study reinforces the assumption that transposons are a major driver of genome and gene evolution in higher plants.

Give-and-take: interactions between DNA transposons and their host plant genomes

Recent genome sequencing efforts have revealed how extensively transposable elements (TEs) have contributed to the shaping of present day plant genomes. DNA transposons associate preferentially with the euchromatic or genic component of plant genomes and have had the opportunity to interact intimately with the genes of the plant host. These interactions have resulted in TEs acquiring host sequences, forming chimeric genes through exon shuffling, replacing regulatory sequences, mobilizing genes around the genome, and contributing genes to the host. The close interaction of transposons with genes has also led to the evolution of intricate cellular mechanisms for silencing transposon activity. Transposons have thus become important subjects of study in understanding epigenetic regulation and, in cases where transposons have amplified to high numbers, how to escape that regulation.

ROSINA (RSI) is part of a CACTA transposable element, TamRSI, and links flower development to transposon activity

ROSINA (RSI) was isolated as a DNA binding factor able to bind to the CArG-box present in the promoter of the MADS-box gene DEFICIENS of Antirrhinum majus. The mosaic nature of RSI and its multi-copy presence in the A. majus genome indicated that RSI could be a part of a mobile genetic element. Here we show that RSI is a part of a CACTA transposable element system of A. majus, named TamRSI, which has evolved and is still evolving within the terminal inverted repeats (TIRs) of this CACTA transposon. Interestingly, RSI is always found in opposite orientation with respect to the transcription of a second gene present within the CACTA transposon, which encodes a putative TRANSPOSASE (TNP). This structural configuration has not yet been described for any member of the CACTA transposons superfamily. Internal deletion derivatives of the TamRSI produce aberrant RSI transcripts (RSI-ATs) that carry parts of the RSI RNA fused to parts of the TNP RNA. In addition, an intriguing seed phenotype shown by RNAi transgenic lines generated to silence RSI, relate TamRSI to epigenetic mechanisms and associate the control of flower development to transposon activity.