The Diversity of Plant Small RNAs Silencing Mechanisms.

Small RNAs gene regulation was first discovered about 20 years ago. It represents a conserve gene regulation mechanism across eukaryotes and is associated to key regulatory processes. In plants, small RNAs tightly regulate development, but also maintain genome stability and protect the plant against pathogens. Small RNA gene regulation in plants can be divided in two canonical pathways: Post-transcriptional Gene Silencing (PTGS) that results in transcript degradation and/or translational inhibition or Transcriptional Gene Silencing (TGS) that results in DNA methylation. In this review, we will focus on the model plant Arabidopsis thaliana. We will provide a brief overview of the molecular mechanisms involved in canonical small RNA pathways as well as introducing more atypical pathways recently discovered.

Non-cell-autonomous small RNA silencing in Arabidopsis female gametes.

In recent years, small RNA movement has been both hypothesized and shown to be an integral part of the epigenetic DNA methylation reprogramming occurring during plant reproduction.1It was suggested that the release of epigenetic silencing in accessory cell types or tissues is necessary to reinforce epigenetic silencing in the gametes (egg cell and sperm cells), which would in turn ensure the genomic stability of the next generation plant.2,3 In Arabidopsis thaliana, small RNA (sRNA) movement was indeed shown to occur during male gametogenesis.4,5,6 However, the situation within the female gametophyte and in early seed development is mostly unknown. Here, we show that small RNAs can induce non-cell-autonomous silencing from the central cell toward the egg cell but also from the synergids to the egg cell and central cell. Our data show that in addition to the movement of sRNAs during pollen development, hairpin RNAs can have non-cell-autonomous effects in the female gametes.