Endogenous auxin is an important regulator of in vivo organ development,but its role in in vitro organogenesis is unclear.It has been observed that the basal end of epicotyl cuttings of juvenile citrus seedlings produ...Endogenous auxin is an important regulator of in vivo organ development,but its role in in vitro organogenesis is unclear.It has been observed that the basal end of epicotyl cuttings of juvenile citrus seedlings produces fewer shoots than the apical end.Here,we report that elevated endogenous auxin levels in the basal end of citrus epicotyl cuttings are inhibitory for in vitro shoot organogenesis.Using transgenic citrus plants expressing an auxin-inducible GUS reporter gene,we have observed elevated levels of auxin at the basal end of stem cuttings that are mediated by polar auxin transport.Depleting endogenous auxin or blocking polar auxin transport enhances shoot organogenesis.An auxin transport inhibitor,N-1-naphthylphthalamic acid(NPA),can also enhance shoot organogenesis independent of its action on polar auxin transport.Finally,we demonstrate that the promotional effects of depleting endogenous auxin or blocking polar auxin transport on shoot organogenesis are cytokinin-dependent.Our study thus provides meaningful insights into possible roles of endogenous auxin and polar auxin transport,as well as auxin–cytokinin interactions,in in vitro shoot organogenesis.Meanwhile,our results may also provide practical strategies for improving in vitro shoot organogenesis for citrus and many other plant species.展开更多
基金The work and WH are financially supported by the Citrus Research and Development Foundation(Projects Li-749 and 16-001 to YL).
文摘Endogenous auxin is an important regulator of in vivo organ development,but its role in in vitro organogenesis is unclear.It has been observed that the basal end of epicotyl cuttings of juvenile citrus seedlings produces fewer shoots than the apical end.Here,we report that elevated endogenous auxin levels in the basal end of citrus epicotyl cuttings are inhibitory for in vitro shoot organogenesis.Using transgenic citrus plants expressing an auxin-inducible GUS reporter gene,we have observed elevated levels of auxin at the basal end of stem cuttings that are mediated by polar auxin transport.Depleting endogenous auxin or blocking polar auxin transport enhances shoot organogenesis.An auxin transport inhibitor,N-1-naphthylphthalamic acid(NPA),can also enhance shoot organogenesis independent of its action on polar auxin transport.Finally,we demonstrate that the promotional effects of depleting endogenous auxin or blocking polar auxin transport on shoot organogenesis are cytokinin-dependent.Our study thus provides meaningful insights into possible roles of endogenous auxin and polar auxin transport,as well as auxin–cytokinin interactions,in in vitro shoot organogenesis.Meanwhile,our results may also provide practical strategies for improving in vitro shoot organogenesis for citrus and many other plant species.
