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Journal of the International Association of Wildland Fire
RESEARCH ARTICLE

Effect of heat shock on germination of 23 plant species in pine–oak and montane cloud forests in western Mexico

Susana Zuloaga-Aguilar A , Oscar Briones A and Alma Orozco-Segovia B C
+ Author Affiliations
- Author Affiliations

A Instituto de Ecología A. C., Red de Biología Evolutiva. Km 2.5 Antigua carreteraa Coatepec No. 351 Congregación El Haya, Xalapa Ver, México, C.P 91070.

B Instituto de Ecología, Departamento de Ecología Funcional, Universidad Nacional Autónomade México. Apdo. Postal 70-275. Circuito Exterior S/N, Ciudad Universitaria,04360 México, D. F., México.

C Corresponding author. Email: aorozco@miranda.ecologia.unam.mx

International Journal of Wildland Fire 19(6) 759-773 https://doi.org/10.1071/WF08092
Submitted: 3 June 2008  Accepted: 4 January 2010   Published: 17 September 2010

Abstract

We determined the effect of heat shock on seed germination of 23 species growing in fire-prone areas covered by pine–oak and montane cloud forests. Seeds of each species were exposed to 60, 80, 100 or 120°C for 5 or 60 min in dry and moist sand. Seeds of nine species were incubated for 15 h in moist sand and exposed to the temperature that best promoted germination. Eighteen species required heat shock for germination, and five tolerated it. Dry heat shock for 5 min promoted germination of these species; heat shock in moist sand at 100°C induced germination of 10 species. Exposure for 60 min to heat shock in dry and moist sand improved germination of 14 and 5 species respectively. Logistic models indicate that germination probabilities of most species are increased by temperatures of 70–120°C. Depending on substrate and seed hydration, heat shock increased or left unchanged the germination of most pine–oak and montane cloud forest species. Thus, montane cloud forest seeds can survive low-intensity surface fires. Most species with seeds hydrated before heat shock showed little or no germination. Prescribed burns at the end of the rainy season may therefore be harmful to pine–oak and montane cloud forest species.

Additional keywords: fire management, heat shock in dry sand, heat shock in moist sand, pine–oak forest.


Acknowledgements

The authors thank Enrique Jardel Peláez and Ruben Ramírez for the facilities and technical support given by the Universidad de Guadalajara and ‘Las Joyas’ Scientific Station, to María Luisa Martínez, Luis Ignacio Iñiguez Dávalos, Ignacio Méndez Ramírez and anonymous referees for their critical review of the manuscript, María Esther Sánchez Coronado, Daniel Valle Vidal and Alejandro Gonz´lez Ponce for their technical support, and Erminio Quiñones and the staff of the ‘Las Joyas’ Scientific Station for field assistance. This research was supported by the CONACyT grants 47409-Q and 47859-Q.


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