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Determining the optimal nighttime air temperature for Phalaenopsis during the vegetative stage

Bruno Pollet UGent, Els Storme UGent, Raoul Lemeur UGent, Pieter Dambre, Marie-Christine Van Labeke UGent and Kathy Steppe UGent (2011) Acta Horticulturae. 893. p.865-871
abstract
Daytime air temperatures above 26 degrees C inhibit flower initiation of Phalaenopsis regardless of the nighttime air temperature. This opens possibilities for energy saving by lowering the nighttime air temperature during the vegetative growth phase. As chilling injury can occur after a few hours exposure to cool temperature conditions, growers prefer to cultivate Phalaenopsis at daily temperatures between 25 and 30 degrees C. A better understanding of the low night temperature effects on the photosynthetic physiology of Phalaenopsis would improve production of these orchids in terms of greenhouse temperature control and energy use. Therefore, the Phalaenopsis hybrid 'Hercules' was subjected to nighttime air temperatures of 27.0, 24.0, 21.1, 18.0, 15.4 and 12.8 degrees C, while during the day temperatures of about 27.5 degrees C were maintained. Photoperiod was set to 9 h with non-saturating white fluorescent light (217.3 +/- 2.8 mu mol PAR m(-2) s(-1)). The chlorophyll fluorescence temperature response curves revealed a significant reduction of the photochemical quenching (qP) and quantum efficiency of PSII electron transport (Phi(PSII)) when plants were exposed to night temperatures below 21.1 degrees C, but maximum quantum yield of PSII photochemistry (F-v/F-m) suggested no PSII damage for these night temperatures. Early morning determined leaf acidity, which can be used as a measure of nocturnal malic acid production, and leaf water potential were lowest at night temperatures of 21.1 and 24.0 degrees C. However, maximum net CO2 uptake in the late night (2 h before daytime) was observed between 15.4 and 21.1 degrees C. Furthermore, PSII photochemistry required only 5 h for full recovery of all night temperatures imposed. Our results suggest that Phalaenopsis can tolerate relatively cool night temperatures during the vegetative growth stage.
Please use this url to cite or link to this publication:
author
organization
year
type
conference
publication status
published
subject
keyword
LEAVES, LEAF, critical temperature, chlorophyll fluorescence, leaf acidity, orchid, leaf water photosynthesis, potential, CRASSULACEAN ACID METABOLISM, PHOSPHOENOLPYRUVATE CARBOXYLASE, PHOTOSYNTHESIS, CO2 FIXATION, RESPONSES, CAM, CARBOHYDRATE, FLUORESCENCE
in
Acta Horticulturae
Acta Hortic.
editor
Martine Dorais
volume
893
issue title
International symposium on high technology for greenhouse systems : GreenSYS 2009
pages
865 - 871
publisher
International Society for Horticultural Science (ISHS)
place of publication
Leuven, Belgium
conference name
2009 International symposium on High Technology for Greenhouse Systems (GreenSYS 2009) : Global trends in greenhouse
conference location
Québec, QC, Canada
conference start
2009-06-14
conference end
2009-06-19
Web of Science type
Proceedings Paper
Web of Science id
000305385800095
ISSN
0567-7572
ISBN
9789066050471
language
English
UGent publication?
yes
classification
P1
copyright statement
I have transferred the copyright for this publication to the publisher
id
2915234
handle
http://hdl.handle.net/1854/LU-2915234
alternative location
http://www.actahort.org/books/893/893_95.htm
date created
2012-06-21 17:04:18
date last changed
2013-02-06 14:08:29
@inproceedings{2915234,
  abstract     = {Daytime air temperatures above 26 degrees C inhibit flower initiation of Phalaenopsis regardless of the nighttime air temperature. This opens possibilities for energy saving by lowering the nighttime air temperature during the vegetative growth phase. As chilling injury can occur after a few hours exposure to cool temperature conditions, growers prefer to cultivate Phalaenopsis at daily temperatures between 25 and 30 degrees C. A better understanding of the low night temperature effects on the photosynthetic physiology of Phalaenopsis would improve production of these orchids in terms of greenhouse temperature control and energy use. Therefore, the Phalaenopsis hybrid 'Hercules' was subjected to nighttime air temperatures of 27.0, 24.0, 21.1, 18.0, 15.4 and 12.8 degrees C, while during the day temperatures of about 27.5 degrees C were maintained. Photoperiod was set to 9 h with non-saturating white fluorescent light (217.3 +/- 2.8 mu mol PAR m(-2) s(-1)). The chlorophyll fluorescence temperature response curves revealed a significant reduction of the photochemical quenching (qP) and quantum efficiency of PSII electron transport (Phi(PSII)) when plants were exposed to night temperatures below 21.1 degrees C, but maximum quantum yield of PSII photochemistry (F-v/F-m) suggested no PSII damage for these night temperatures. Early morning determined leaf acidity, which can be used as a measure of nocturnal malic acid production, and leaf water potential were lowest at night temperatures of 21.1 and 24.0 degrees C. However, maximum net CO2 uptake in the late night (2 h before daytime) was observed between 15.4 and 21.1 degrees C. Furthermore, PSII photochemistry required only 5 h for full recovery of all night temperatures imposed. Our results suggest that Phalaenopsis can tolerate relatively cool night temperatures during the vegetative growth stage.},
  author       = {Pollet, Bruno and Storme, Els and Lemeur, Raoul and Dambre, Pieter and Van Labeke, Marie-Christine and Steppe, Kathy},
  booktitle    = {Acta Horticulturae},
  editor       = {Dorais, Martine},
  isbn         = {9789066050471},
  issn         = {0567-7572},
  keyword      = {LEAVES,LEAF,critical temperature,chlorophyll fluorescence,leaf acidity,orchid,leaf water photosynthesis,potential,CRASSULACEAN ACID METABOLISM,PHOSPHOENOLPYRUVATE CARBOXYLASE,PHOTOSYNTHESIS,CO2 FIXATION,RESPONSES,CAM,CARBOHYDRATE,FLUORESCENCE},
  language     = {eng},
  location     = {Qu{\'e}bec, QC, Canada},
  pages        = {865--871},
  publisher    = {International Society for Horticultural Science (ISHS)},
  title        = {Determining the optimal nighttime air temperature for Phalaenopsis during the vegetative stage},
  url          = {http://www.actahort.org/books/893/893\_95.htm},
  volume       = {893},
  year         = {2011},
}

Chicago
Pollet, Bruno, Els Storme, Raoul Lemeur, Pieter Dambre, Marie-Christine Van Labeke, and Kathy Steppe. 2011. “Determining the Optimal Nighttime Air Temperature for Phalaenopsis During the Vegetative Stage.” In Acta Horticulturae, ed. Martine Dorais, 893:865–871. Leuven, Belgium: International Society for Horticultural Science (ISHS).
APA
Pollet, B., Storme, E., Lemeur, R., Dambre, P., Van Labeke, M.-C., & Steppe, K. (2011). Determining the optimal nighttime air temperature for Phalaenopsis during the vegetative stage. In M. Dorais (Ed.), Acta Horticulturae (Vol. 893, pp. 865–871). Presented at the 2009 International symposium on High Technology for Greenhouse Systems (GreenSYS 2009) : Global trends in greenhouse, Leuven, Belgium: International Society for Horticultural Science (ISHS).
Vancouver
1.
Pollet B, Storme E, Lemeur R, Dambre P, Van Labeke M-C, Steppe K. Determining the optimal nighttime air temperature for Phalaenopsis during the vegetative stage. In: Dorais M, editor. Acta Horticulturae. Leuven, Belgium: International Society for Horticultural Science (ISHS); 2011. p. 865–71.
MLA
Pollet, Bruno, Els Storme, Raoul Lemeur, et al. “Determining the Optimal Nighttime Air Temperature for Phalaenopsis During the Vegetative Stage.” Acta Horticulturae. Ed. Martine Dorais. Vol. 893. Leuven, Belgium: International Society for Horticultural Science (ISHS), 2011. 865–871. Print.