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Apical hook opening is crucial for seedling establishment and is regulated by unequal distribution of the hormone auxin through unknown mechanisms. In this issue of Developmental Cell, Walia et al. 4 demonstrate that apical hook opening is an output of tissue-wide forces; auxin and cell wall integrity (CWI) signaling interact to restrict elongation to the concave side of the apical hook. 

Abstract Understanding how evolution shapes genetic networks to create new developmental forms is a central question in biology. Flowering shoot (inflorescence) architecture varies significantly across plant families and is a key target of genetic engineering efforts in many crops^1–4. Asteraceae (sunflower family), comprising 10% of flowering plants, all have capitula, a novel inflorescence that mimics a single flower^5,6. Asteraceae capitula are highly diverse but are thought to have evolved once via unknown mechanisms^7,8. During capitulum development, shoot stem cells undergo prolonged proliferation to accommodate the formation of intersecting spirals of flowers (florets) along the disk-shaped head^9,10. Here we show that capitulum evolution paralleled decreases in CLAVATA3 (CLV3) peptide signaling, a conserved repressor of stem cell proliferation. We trace this to novel amino acid changes in the mature CLV3 peptide which decrease receptor binding and downstream transcriptional outputs. Using genetically tractable Asteraceae models, we show that reversion ofCLV3to a more active form impairs Asteraceae stem cell regulation and capitulum development. Additionally, we trace the evolution ofCLV3and its receptors across the Asterales allowing inferences on capitulum evolution within this lineage. Our findings reveal novel mechanisms driving evolutionary innovation in plant reproduction and suggest new approaches for genetic engineering in crop species. 

Cell division is often regulated by extracellular signaling networks to ensure correct patterning during development. In Arabidopsis , the SHORT-ROOT (SHR)/SCARECROW (SCR) transcription factor dimer activates CYCLIND6 ; 1 ( CYCD6;1 ) to drive formative divisions during root ground tissue development. Here, we show plasma-membrane-localized BARELY ANY MERISTEM1/2 (BAM1/2) family receptor kinases are required for SHR -dependent formative divisions and CYCD6;1 expression, but not SHR -dependent ground tissue specification. Root-enriched CLE ligands bind the BAM1 extracellular domain and are necessary and sufficient to activate SHR -mediated divisions and CYCD6;1 expression. Correspondingly, BAM-CLE signaling contributes to the restriction of formative divisions to the distal root region. Additionally, genetic analysis reveals that BAM-CLE and SHR converge to regulate additional cell divisions outside of the ground tissues. Our work identifies an extracellular signaling pathway regulating formative root divisions and provides a framework to explore this pathway in patterning and evolution. 

Summary In flowering plants, cell–cell communication plays a key role in reproductive success, as both pollination and fertilization require pathways that regulate interactions between many different cell types. Some of the most critical of these interactions are those between the pollen tube (PT) and the embryo sac, which ensure the delivery of sperm cells required for double fertilization. Synergid cells function to attract thePTthrough secretion of small peptides and inPTreception via membrane‐bound proteins associated with the endomembrane system and the cell surface. While many synergid‐expressed components regulatingPTattraction and reception have been identified, few tools exist to study the localization of membrane‐bound proteins and the components of the endomembrane system in this cell type. In this study, we describe the localization and distribution of seven fluorescent markers that labelled components of the secretory pathway in synergid cells ofArabidopsis thaliana. These markers were used in co‐localization experiments to investigate the subcellular distribution of the twoPTreception componentsLORELEI, aGPI‐anchored surface protein, andNORTIA, aMILDEW RESISTANCE LOCUSO protein, both found within the endomembrane system of the synergid cell. These secretory markers are useful tools for both reproductive and cell biologists, enabling the analysis of membrane‐associated trafficking within a haploid cell actively involved in polar transport.