A paternal signal induces endosperm proliferation upon fertilization in Arabidopsis

Tracking the genome-wide occupancy of Arabidopsis LEAFY COTYLEDON1 in endosperm development

Endosperm development is crucial for embryo growth and seed maturation. LEAFY COTYLEDON1 (LEC1), expressed in both endosperm and embryo, serves as a key regulator of seed development, orchestrating processes such as embryogenesis and seed maturation. LEC1 expression in the endosperm is detectable within a day after fertilization, yet its specific regulatory networks and developmental functions in this tissue remain unclear. To address this, we employed a modified INTACT system to isolate endosperm nuclei and performed ChIP-seq to map the genome-wide binding profile of LEC1 in developing endosperm. Integrating ChIP-seq with transcriptomic analyses, we uncover a critical role for LEC1 in regulating diverse biological pathways. Differential gene expression analysis in the endosperms of lec1 mutant and wild type shows substantial changes, particularly in genes involved in secondary cell wall biogenesis, photosynthesis, and lipid metabolism. Notably, LEC1's regulatory networks in the endosperm shift significantly after cellularization, with distinct genes being activated in the cellular and degeneration stages. The absence of LEC1 causes significant alterations in endosperm metabolism, particularly affecting storage lipid fatty acid composition. These findings provide insights into the essential role of LEC1 in endosperm development and its broader impact on seed formation.

Local trafficking and long-distance transport of small RNAs in plants

Canonical small RNAs in plants, including miRNAs and siRNAs, are key triggers of RNA interference and regulate nearly every major biological process in plants. To establish systemic silencing, small RNAs undergo both short-distance intracellular trafficking or intercellular communication and long-distance transport from one organ to another, even across parasites or pathogens. This enables the delivery of effector molecules throughout the plant, promoting the spread of gene silencing. Biologically, the spatiotemporal regulation of small RNAs results in gradient distributions within cells or along the direction of organogenesis. Furthermore, the spreading capacity of small RNAs, generated in somatic or nurse cells, can guide target gene silencing in germlines in plants. In this review, we summarize recent advances in understanding the regulation and the functional roles of local trafficking and long-distance transport of plant small RNAs in developmental polarity, the maintenance of cell identity, and with a particular focus, the mechanisms of small RNA movement and delivery between companion cells and gametes in plants. Additionally, we discuss the methods and challenges of monitoring small RNA transport in vivo through live imaging, as well as the potential applications of small RNA transport and delivery in the development of RNA-based pesticides.

Scalable eQTL mapping using single-nucleus RNA-sequencing of recombined gametes from a small number of individuals

Phenotypic differences between individuals of a species are often caused by differences in gene expression, which are in turn caused by genetic variation. Expression quantitative trait locus (eQTL) analysis is a methodology by which we can identify such causal variants. Scaling eQTL analysis is costly due to the expense of generating mapping populations, and the collection of matched transcriptomic and genomic information. We developed a rapid eQTL analysis approach using single-cell/nucleus RNA sequencing of gametes from a small number of heterozygous individuals. Patterns of inherited polymorphisms are used to infer the recombinant genomes of thousands of individual gametes and identify how different haplotypes correlate with variation in gene expression. Applied to Arabidopsis pollen nuclei, our approach uncovers both cis- and trans-eQTLs, ultimately mapping variation in a master regulator of sperm cell development that affects the expression of hundreds of genes. This establishes snRNA-sequencing as a powerful, cost-effective method for the mapping of meiotic recombination, addressing the scalability challenges of eQTL analysis and enabling eQTL mapping in specific cell-types.

Cell proliferation suppressor RBR1 interacts with ARID1 to promote pollen mitosis via stabilizing DUO1 in Arabidopsis

In plants, sperm cell formation involves two rounds of pollen mitoses, in which the microspore initiates the first pollen mitosis (PMI) to produce a vegetative cell and a generative cell, then the generative cell continues the second mitosis (PMII) to produce two sperm cells. DUO1, a R2R3 Myb transcription factor, is activated in the generative cell to promote S-G2/M transition during PMII. Loss-of-function of DUO1 caused a complete arrest of PMII. Despite the importance of DUO1, how DUO1 is regulated is largely unexplored. We previously demonstrated that ARID1, an ARID transcription factor, stimulates DUO1 transcription. Here, we show that cell proliferation suppressor RBR1 interacts with ARID1 to stabilize DUO1. While the C-terminus of RBR1 is dispensable for vegetative growth, it plays a crucial role in reproductive development and facilitates interaction with ARID1. Moreover, DUO1 is a short-lived protein, ARID1 promotes the RBR1-DUO1 interaction, and RBR1 stabilizes DUO1 in a proteasome-dependent manner. Thus, RBR1 promotes DUO1-dependent PMII progression via antagonizing its repressive role in the cell cycle factors CDKA;1 and CYCB1;1. Collectively, we uncover that ARID1 and RBR1 act in concert to regulate DUO1 at both the transcriptional and posttranscriptional levels, balancing cell specification and cell division.

To infinity and beyond: recent progress, bottlenecks, and potential of clonal seeds by apomixis

Apomixis - clonal seed production in plants - is a rare yet phylogenetically widespread trait that has recurrently evolved in plants to fix hybrid genotypes over generations. Apomixis is absent from major crop species and has been seen as a holy grail of plant breeding due to its potential to propagate hybrid vigor in perpetuity. Here we exhaustively review recent progress, bottlenecks, and potential in the individual components of gametophytic apomixis (avoidance of meiosis, skipping fertilization by parthenogenesis, autonomous endosperm development), and sporophytic apomixis. The Mitosis instead of Meiosis system has now been successfully set up in three species (Arabidopsis, rice, and tomato), yet significant hurdles remain for universal bioengineering of clonal gametes. Parthenogenesis has been engineered in even more species, yet incomplete penetrance still remains an issue; we discuss the choice of parthenogenesis genes (BABY BOOM, PARTHENOGENESIS, WUSCHEL) and also how to drive egg cell-specific expression. The identification of pathways to engineer autonomous endosperm development would allow fully autonomous seed production, yet here significant challenges remain. The recent achievements in the engineering of synthetic apomixis in rice at high penetrance show great potential and the remaining obstacles toward implementation in this crop are addressed. Overall, the recent practical examples of synthetic apomixis suggest the field is flourishing and implementation in agricultural systems could soon take place.

Regulation of cell cycle in plant gametes: when is the right time to divide?

Cell division is a fundamental process shared across diverse life forms, from yeast to humans and plants. Multicellular organisms reproduce through the formation of specialized types of cells, the gametes, which at maturity enter a quiescent state that can last decades. At the point of fertilization, signalling lifts the quiescent state and triggers cell cycle reactivation. Studying how the cell cycle is regulated during plant gamete development and fertilization is challenging, and decades of research have provided valuable, yet sometimes contradictory, insights. This Review summarizes the current understanding of plant cell cycle regulation, gamete development, quiescence, and fertilization-triggered reactivation.

Gamete activation for fertilization and seed development in flowering plants

Double fertilization is a defining feature of flowering plants, in which two male gametes (sperm cells) fuse with two female gametes (egg and central cell) to trigger embryogenesis and endosperm development. Gamete activation before fertilization is essential for the success of fertilization, while gamete activation after fertilization is the prerequisite for embryo and endosperm development. The two phases of activation are an associated and continuous process. In this review, we focus on current understanding of gamete activation both before and after fertilization in flowering plants, summarize and discuss the detailed cellular and molecular mechanisms underlying gamete activation for fertilization or initiation of embryogenesis and endosperm development.