Abstract
There are substantial variations in bulbing (bulb formation) efficiency among micropropagated tulip cultivars. The mechanisms involved are poorly understood, but presumably involve cytokinins (CKs) for several reasons. Therefore, we explored CK profiles and dynamics in ‘Blue Parrot’ and ‘Prominence’ cultivars (which have low and high bulbing efficiency, respectively) during the in vitro propagation stages: the last shoot multiplication subculture extended to 14 weeks (S1–S2), the shoot cooling at 5 °C for induction of bulb formation (S3–S4) and the bulb growth initiation after the end of cooling (S5–S6). The CK thidiazuron (TDZ) is routinely used in tulip micropropagation at the shoot multiplication stage, but replacing it with isopentenyladenine (iP) during the last multiplication subculture substantially changed CK dynamics in later stages, and significantly increased bulb formation rates in both cultivars. Generally, the most abundant CKs in both cultivars were the isoprenoid CK types, trans-zeatin (tZ), iP, cis-zeatin and dihydrozeatin. However, ‘Prominence’ shoots had much lower cis- to trans-Z-type CK ratios than ‘Blue Parrot’ shoots, and generally higher levels of physiologically active CKs (free bases tZ, iP and their ribosides) until the last phase of bulb formation, S6 (bulb growth initiation, i.e. swelling of shoot bases), 6 weeks after the end of cold treatment. In this phase total active CK and O-glucoside contents sharply declined in ‘Prominence’ shoots, but not in ‘Blue Parrot’ shoots pretreated with iP. In contrast, the low bulbing ability observed in ‘Prominence’ shoots pretreated with TDZ and ‘Blue Parrot’ shoots pretreated with either TDZ or iP was associated with a gradual rise in active CK and O-glucoside contents after the end of cooling. The results suggest that low bulbing efficiency may be related to down-regulation of tZ biosynthesis, and high bulbing efficiency to a transient increase in active CK forms (mainly tZs) in response to cold treatment during the bulb induction phase, S4 (at the end of cold treatment), followed by a rapid decrease during bulb formation, S6 (6 weeks after the end of cooling).
Highlights
In vitro storage organ formation has been extensively studied in numerous geophytes (Ascough et al 2008; Podwyszynska 2012)
We explored CK profiles and dynamics in ‘Blue Parrot’ and ‘Prominence’ cultivars during the in vitro propagation stages: the last shoot multiplication subculture extended to 14 weeks (S1–S2), the shoot cooling at 5 °C for induction of bulb formation (S3–S4) and the bulb growth initiation after the end of cooling (S5–S6)
We discovered that modification and prolongation of the last multiplication subculture prior to cooling, combined with applications of napthaleneacetic acid (NAA) and gibberellin biosynthesis inhibitors, enhance shoots’ bulbing capacity (Podwyszynska 2006b)
Summary
In vitro storage organ formation (tuberization) has been extensively studied in numerous geophytes (Ascough et al 2008; Podwyszynska 2012). Numerous reports suggest that two factors induce an in vitro storage organ formation in most geophytes, including bulbous plants: (1) a high sucrose concentration in in vitro media and (2) a sharp reduction in endogenous gibberellin levels in response to environmental cues (Podwyszynska 2012). The latter has been confirmed by demonstrations that application of gibberellin biosynthesis inhibitors stimulates bulb formation (inter alia) in garlic (Kim et al 2003), lily (Kumar et al 2005) and tulip (Podwyszynska 2006b). Low exogenous cytokinin to auxin ratio reportedly promote bulb growth of Hippeastrum (Huang et al 2005)
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