Abstract
Asexual propagation in Ceratonia siliqua L. (carob), species of economic value, is difficult because of adventitious rooting recalcitrance. In Pinus radiata adventitious rooting of hypocotyl cuttings is enhanced by two urea-derivatives, 1,3-di(benzo[d]oxazol-5-yl)urea (5-BDPU) and 1,3-di(benzo[d]oxazol-6-yl)urea (6-BDPU), combined with exogenous indole-3-butyric acid (IBA). The research was aimed to define the role of these urea-derivatives in adventitious root (AR) formation of carob, and to identify morphogenic roles induced in carob, but also in pine, a distantly-related forest species. In carob, 5-BDPU (10 μM) highly promoted AR formation in combination with IBA (1 μM) when applied for 3 days, followed by a transfer onto hormone free medium (HF) up to culture end (4 weeks). IBA alone (1 μM) was more effective than IBA + kinetin (Kin, 10 nM), whereas Kin alone and 5-BDPU alone were not AR-inductive. The histological analysis showed that the cambial cells initiated the ARs, and similar numbers of AR-primordia were visible at day 12, independently of the AR-inductive treatment (i.e., IBA, IBA + 5-BDPU, IBA + Kin). No cutting treated with Kin alone, and rare HF (±5-BDPU)-treated ones, showed AR-primordia at day 12. The number of AR-forming explants increased under IBA + 5-BDPU. By contrast, the cambial cells were stimulated to initiate deuteroxylem instead of ARs under 5-BDPU alone. The histological analysis in pine microcuttings treated with IBA and/or 5-BDPU at the same concentrations confirmed that 5-BDPU applied alone enhanced xylogenesis, highlighting that this urea-derivative exhibits a dual morphogenic role being involved in the switching between adventitious rooting and xylogenesis depending on the presence of exogenous auxin in both species.
Highlights
It is well known that plants may regenerate parts of their body, e.g. adventitious roots (ARs), or even a new organism, e.g., embryos, through cellular dedifferentiation and re-differentiation events involving different pathways andPlant Cell Tiss Organ Cult (2016) 126:411–427 strategies of regeneration
The research was aimed to define the role of these ureaderivatives in adventitious root (AR) formation of carob, and to identify morphogenic roles induced in carob, and in pine, a distantly-related forest species
A first set of experiments was carried out to identify the most efficient concentration of indole-3-butyric acid (IBA) applied either alone for 7 days or in combination with either 5-BDPU or 6-BDPU at 10 lM (Brunoni et al 2014)
Summary
Plant Cell Tiss Organ Cult (2016) 126:411–427 strategies of regeneration This occurs because the fate of somatic cells can be switched into new developmental programmes by the activities of pre-existing, or de novo formed, stem cells, with the mechanisms enabling this developmental plasticity not fully understood. Xylogenesis may occur as an alternative program to adventitious rooting, as in the rooting-recalcitrant cuttings of walnut and tobacco rac mutant (Reverberi et al 2001; Faivre-Rampant et al 2003). It may occur concomitantly with adventitious rooting, as in tobacco and Arabidopsis thin cell layers (TCLs), with the prevalence of one program on the other depending on various factors, e.g., calcium ion and jasmonate concentration in the medium (Falasca et al 2004; Fattorini et al 2009). In Arabidopsis, it has been recently demonstrated that the same cells reactivated by the auxin treatments to re-differentiate and to produce ARs in planta, and in TCLs, are able to initiate xylogenesis, with SHORTROOT and SCARECROW transcription factors, and AUX1 auxin-influx carrier, controlling the switching between the programs (Della Rovere et al 2015)
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