The <i>ERECTA</i>, <i>CLAVATA</i> and class <i>III HD-ZIP</i> Pathways Display Synergistic Interactions in Regulating Floral Meristem Activities

<div><p>In angiosperms, the production of flowers marks the beginning of the reproductive phase. At the emergence of flower primordia on the flanks of the inflorescence meristem, the <i>WUSCHEL (WUS)</i> gene, which encodes a homeodomain transcription factor starts to be expressed and establishes <i>de novo</i> stem cell population, founder of the floral meristem (FM). Similarly to the shoot apical meristem a precise spatial and temporal expression pattern of <i>WUS</i> is required and maintained through strict regulation by multiple regulatory inputs to maintain stem cell homeostasis. However, following the formation of a genetically determined fixed number of floral organs, this homeostasis is shifted towards organogenesis and the FM is terminated. In here we performed a genetic study to test how a reduction in <i>ERECTA</i>, <i>CLAVATA</i> and <i>class III HD-ZIP</i> pathways affects floral meristem activity and flower development. We revealed strong synergistic phenotypes of extra flower number, supernumerary whorls, total loss of determinacy and extreme enlargement of the meristem as compared to any double mutant combination indicating that the three pathways, <i>CLV3</i>, <i>ER</i> and <i>HD-ZIPIII</i> distinctively regulate meristem activity and that they act in parallel. Our findings yield several new insights into stem cell-driven development. We demonstrate the crucial requirement for coupling floral meristem termination with carpel formation to ensure successful reproduction in plants. We also show how regulation of meristem size and alternation in spatial structure of the meristem serve as a mechanism to determine flower organogenesis. We propose that the loss of FM determinacy due to the reduction in CLV3, ER and HD-ZIPIII activity is genetically separable from the <i>AGAMOUS</i> core mechanism of meristem termination.</p>