Deciphering the auxin-ethylene crosstalk in petal abscission through auxin influx carrier IpAUX1 of Itoh peony ‘Bartzella’

Abstract

Auxin gradient on either side of the abscission zone play a crucial role in regulating organ abscission during plant senescence. Yet, the impact of auxin on the opening and senescence of cut peony flowers, specifically Itoh peony ‘Bartzella’, remains elusive. We employed the frozen section method to investigate the cell morphology within the petal abscission zone. Additionally, we quantified auxin levels via enzyme immunoassay and assessed the expression of genes related to indole-3-acetic acid (IAA) levels. Through our analyses, we pinpointed the critical gene, IpAUX1. Further investigation of IpAUX1 involved virus-induced gene silencing (VIGS) and transient overexpression techniques, allowing us to assess its role both in vitro flowers, through vacuum application, and in vivo flowers, via injection. Significant alterations were observed in the structure and cell morphology of the abscission zone correlating with the process of petal abscission, alongside noticeable auxin gradient. Silencing IpAUX1 led to a noticeable delay in petal abscission for both in vitro flowers and vivo flowers, while its transient overexpression hastened this process. This silencing effect was accompanied by a reduction in IAA levels around the abscission zone and a subsequent delay in the erasure of the auxin gradient. It also resulted in the downregulation of several genes: the auxin response factor IpARF1, ethylene synthesis-related genes IpACS1 and IpACO1, and cell wall hydrolysis-related genes IpPME1 and IpPG1. Conversely, the expression of genes involved in auxin synthesis gene IpYUCCA10, auxin efflux carrier IpPIN1, and the ethylene receptor IpETR1 saw significant upregulation. This study concludes that the auxin influx carrier IpAUX1 enhances the abscission zone cells' responsiveness to ethylene by modulating the auxin gradient. This action promotes cell hydrolysis within the abscission zone, thereby encouraging petal abscission. Our findings underscore the pivotal role of IpAUX1 as a positive regulator during the process of petal abscission.