2019
DOI: 10.1016/j.scienta.2018.12.021
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Somatic embryogenesis from stamen filaments of Aesculus flava Sol. and peroxidase activity during the transition from friable to embryogenic callus

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Cited by 5 publications
(23 citation statements)
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“…The increase in activity in the ECs could be due to the fact that POXs have an important role during the formation of embryo cell walls [ 59 ]. In a proteomic analysis of the ECs and NECs in maize, Varhaníková et al [ 60 ] suggested that increased POX activity correlated with the acquisition of regeneration capacity. However, there are opposite examples, where the reduction in POX activity typified ECs.…”
Section: Discussionmentioning
confidence: 99%
“…The increase in activity in the ECs could be due to the fact that POXs have an important role during the formation of embryo cell walls [ 59 ]. In a proteomic analysis of the ECs and NECs in maize, Varhaníková et al [ 60 ] suggested that increased POX activity correlated with the acquisition of regeneration capacity. However, there are opposite examples, where the reduction in POX activity typified ECs.…”
Section: Discussionmentioning
confidence: 99%
“…The callusing and regeneration were rapid and profuse on explants cultivated in darkness, whereas photoperiod conditions suppressed differentiation. This adverse effect of light is thought provoking, although darkness-promoting somatic embryogenesis [ 39 ], bulblet regeneration [ 40 ] and rooting [ 41 ] have been previously observed. It was also proved that early exposure to light can prevent callus formation and decrease adventitious shoot regeneration [ 42 ].…”
Section: Discussionmentioning
confidence: 99%
“…Aesculus species are prone to somatic embryogenesis, thus it is not surprising that somatic embryogenesis was successfully achieved with almost all horse chestnut plant organs used as initial explants: stamen filaments [76][77][78], immature zygotic embryos [77,79], seedling's primary leaves [80] and cotyledons [81], and stem [82] and bark fragments [83] isolated from young terminal branches of adult trees. Somatic embryogenesis was also initiated from stems [84] and shoots [85] of A. glabra, stamen filaments of A. flava [86] and A. carnea [87], shoots and roots of 4-week-old seedlings and shoots of a 30-year-old tree of a hybrid A. x arnoldiana [85]. In all the studies, somatic embryogenesis was induced indirectly through a callus phase, with the exception of stamen filaments of A. hippocastanum, in which SEs regenerated directly from filaments in 10% of the explants, while in the remaining 90% of the explants SEs regenerated indirectly from embryogenic callus [77].…”
Section: Somatic Embryogenesismentioning
confidence: 99%
“…In A. flava, combinations of 1, 5 or 10 µM 2,4-D with 0, 1, 5 or 10 µM Kin were tested in order to determine the most efficient combination of these PGRs for callus induction and subsequent SE regeneration from filament explants [86]. In contrast to horse chestnut filaments [78,88], 2,4-D as a sole PGR was not sufficient to trigger efficient callus induction in A. flava [86]. At the highest tested concentration, 10 µM 2,4-D without Kin, only 36% of the explants produced small calli (that remained non-embryogenic throughout the duration of the experiment).…”
Section: Initiation Of Embryogenic Culturesmentioning
confidence: 99%
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