Seed Germination Ecophysiology of Meadow Salsify (Tragopogon pratensis) and Western Salsify (T. dubius)

To understand persistence strategies of meadow and western salsify, ecophysiological characteristics of their seed germination were studied. Anaerobiosis (immersion in deoxygenated water) induced secondary dormancy in seeds of both species. Dormancy could be induced in 86% of meadow salsify seeds an...

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Bibliographic Details
Published in:Weed science 1993-07, Vol.41 (3), p.362-368
Main Authors: Qi, Meiqin, Upadhyaya, Mahesh K.
Format: Article
Language:English
Subjects:
After ripening
Agronomy. Soil science and plant productions
ALMACENAMIENTO
ANAEROBIOSE
ANAEROBIOSIS
BIOLOGIA
Biological and medical sciences
BIOLOGIE
DIFERENCIAS BIOLOGICAS
DIFFERENCE BIOLOGIQUE
DORMANCE
Dormancy
DORMICION
EMERGENCIA
ESTRATIFICACION
FISIOLOGIA VEGETAL
FRIO
FROID
Fundamental and applied biological sciences. Psychology
Generalities, botany, ecology, damages, economic importance
GERMINACION
GERMINATION
GRAINE
LEVEE
LEVEE DE DORMANCE
LUMIERE
LUZ
MALEZAS
MAUVAISE HERBE
Meadows
Parasitic plants. Weeds
PHYSIOLOGIE VEGETALE
Phytopathology. Animal pests. Plant and forest protection
SALIDA DE LA LATENCIA
Seed dormancy
Seed germination
Seeding
Seeds
SEMILLA
STOCKAGE
STRATIFICATION
TEMPERATURA AMBIENTE
TEMPERATURE AMBIANTE
TRAGOPOGON
Tragopogon dubius
Tragopogon pratensis
Viability
Weed Biology and Ecology
Weeds
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Summary:To understand persistence strategies of meadow and western salsify, ecophysiological characteristics of their seed germination were studied. Anaerobiosis (immersion in deoxygenated water) induced secondary dormancy in seeds of both species. Dormancy could be induced in 86% of meadow salsify seeds and in 65% of western salsify seeds by a 1-d anaerobiosis treatment. The induced dormancy was gradually released during storage of air-dried secondary dormant meadow salsify seeds, and the rate of this release was influenced by storage temperature; 30 C was more effective than 10 or 20 C in releasing secondary dormancy. These results suggest that the two species may rely on induced dormancy as an option in their persistence strategy. The optimum temperature for germination of nondormant seeds of both species was 15 C. Maximum germination percentages for both species were established within 4 to 6 d of incubation at 15 C and within 14 to 28 d of incubation at 25 C. Nondormant seeds did not germinate below 10 or above 30 C. Stratification (at 5 C for 2 to 10 wk) stimulated germination of secondary dormant seeds of meadow salsify. This stratification requirement can be important in preventing germination of dormant salsify seeds in the fall, thereby avoiding high seedling mortality in the winter. Light (red and far-red) had no effect on germination of seeds in secondary dormancy. In a separate study, seeds of both species were planted in pots at depths of 2 to 14 cm and seedling emergence was observed. Maximum emergence occurred when seeds were buried 2 cm deep. Seeds planted 8 cm or deeper germinated but did not emerge.
ISSN:0043-1745
1550-2759
DOI:10.1017/S0043174500052061