Postharvest physiology of cut Gardenia jasminoides flowers

Postharvest physiology of cut Gardenia jasminoides flowers

•Gardenia jasminoides can be used as a cut flower.•Water uptake is critical in extending longevity of gardenia flowers.•Citric acid and aluminum sulphate in the vase solution increased water uptake.•Abscisic acid increased vase life to 5 days by reducing water loss and maintaining RFW.•Benzyl adenin...

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Bibliographic Details
Published in:Scientia horticulturae Vol. 261; p. 108983
Main Authors: Çelikel, Fisun G., Reid, Michael S., Jiang, Cai-Zhong
Format: Journal Article
Language:English
Published: Elsevier B.V 05-02-2020
Subjects:
Bactericide
Bud development
Gardenia
PGR
Senescence stages
Sucrose
Vase life
Vase solutions
Water uptake
Senescence stages
Gardenia
Sucrose
Vase life
Bud development
Water uptake
PGR
Vase solutions
Bactericide
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Summary:•Gardenia jasminoides can be used as a cut flower.•Water uptake is critical in extending longevity of gardenia flowers.•Citric acid and aluminum sulphate in the vase solution increased water uptake.•Abscisic acid increased vase life to 5 days by reducing water loss and maintaining RFW.•Benzyl adenine was the most effective plant growth regulator doubling vase life to 5.5 d. We investigated the postharvest physiology of Gardenia jasminoides, and a range of postharvest treatments that might permit its use as a cut flower. The effects of different vase solution treatments, containing a range of biocides, acidulants, carbohydrate sources and/or growth regulators on the postharvest performance of cut gardenia flowers were studied by measuring water uptake (WU), water loss (WL) and relative fresh weight (RFW) of the flowers during vase life. In deionized (DI) water, gardenia flowers wilted after 2–3 days. Pulse treatment with silver thiosulfate (STS) to inhibit ethylene responses had no effect on vase life. However, abscisic acid (ABA) treatment increased vase life to 5 days by reducing WL and maintaining RFW. Including a cytokinin, benzyl adenine (BA), in the vase solution was the most effective plant growth regulator treatment, doubling vase life to 5.5 days. Vase solutions containing a commercial flower preservative, or combining citric acid, sucrose and aluminum sulfate also doubled the vase life of gardenia flowers. NaOCl in the vase solution provided little benefit, but acidification with aluminum sulfate (AS) or citric acid (CA) increased initial WU and extended vase life. The results suggest that improving water uptake is important for extending the vase life of cut gardenia flowers, and that acidification of the vase solution is an effective tool.
ISSN:0304-4238
1879-1018
DOI:10.1016/j.scienta.2019.108983