Hostname: page-component-cd9895bd7-jkksz Total loading time: 0 Render date: 2024-12-27T08:09:28.290Z Has data issue: false hasContentIssue false

Tree phenology in montane forests of southern Ecuador can be explained by precipitation, radiation and photoperiodic control

Published online by Cambridge University Press:  01 May 2008

Sven Günter*
Affiliation:
Institute of Silviculture, Centre of Life and Food Sciences Weihenstephan, Technische Universität München, Germany
Bernd Stimm
Affiliation:
Institute of Silviculture, Centre of Life and Food Sciences Weihenstephan, Technische Universität München, Germany
Manuel Cabrera
Affiliation:
Area Agropecuaria y Recursos Naturales Renovables, Universidad Nacional de Loja, Ecuador
Maria Luisa Diaz
Affiliation:
Area Agropecuaria y Recursos Naturales Renovables, Universidad Nacional de Loja, Ecuador
Manuel Lojan
Affiliation:
Area Agropecuaria y Recursos Naturales Renovables, Universidad Nacional de Loja, Ecuador
Eduardo Ordoñez
Affiliation:
Area Agropecuaria y Recursos Naturales Renovables, Universidad Nacional de Loja, Ecuador
Michael Richter
Affiliation:
Institute of Geography, Friedrich-Alexander-Universität Erlangen-Nürnberg, Germany
Michael Weber
Affiliation:
Institute of Silviculture, Centre of Life and Food Sciences Weihenstephan, Technische Universität München, Germany
*
1Corresponding author. Current address: Lehrstuhl für Waldbau, Am Hochanger 13, 85354 Freising, Germany. Email: sven_gunter@yahoo.de

Abstract:

We investigated the effect of seasonality on tree phenology in the tropical montane rain forest of southern Ecuador and analysed possible triggering factors. Two hypotheses were tested: (1) Interspecific synchronization of flowering and fruiting phenology is higher at study sites with pronounced rainfall seasonality compared with sites within perhumid forests. (2) Proximate causes for flowering in closely situated seasonal and perhumid sites are either photoperiodicity or climatic factors. Two nearby study sites with contrasting precipitation patterns were selected at the same altitude east and west of the western Cordillera. Eighty trees from 13 species were observed over a 2.5-y period. Three species were common to both study sites. Phenological and climate data were collected and cross-correlated by conducting a time-series analysis. At the perhumid site, very clear annual patterns of phenological behaviour could be observed for most of the selected rain-forest tree species, but with a poor interspecific synchronization. On the nearby seasonal site in contrast, most species showed high synchrony in their phenological behaviour coinciding with the dry season. There is strong evidence that flowering is induced not by one factor alone: we identified photoperiodic control, radiation and precipitation as possible proximate causes for both sites. Our results confirm studies which state that these factors are closely linked to each other in the tropics.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2008

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

LITERATURE CITED

ANDERSON, D. P., NORDHEIM, E. V., MOERMOND, T. C., GONE BI, Z. B. & BOESCH, C. 2005. Factors influencing tree phenology in Tai National Park, Côte d'Ivoire. Biotropica 37:631640.CrossRefGoogle Scholar
BACH, C. S. 2002. Phenological patterns in monsoon rainforests in the Northern Territory, Australia. Austral Ecology 27:477489.CrossRefGoogle Scholar
BALSLEV, H. & ØLLGAARD, B. 2002. Mapa de vegetación del sur del Ecuador. Pp. 5164 in Aguirre, M. Z., Madsen, J. E., Cotton, E. & Balslev, H. (eds.). Botánica Austroecuatoriana. Ediciones Abya-Yala, Quito, Ecuador.Google Scholar
BAWA, K. S., KANG, H. & GRAYUM, M. H. 2003. Relationship among time, frequency, and duration of flowering in tropical rain forest trees. American Journal of Botany 90:877887.CrossRefGoogle ScholarPubMed
BENDIX, J. 2004. Extremereignisse und Klimavariabilitat in den Anden von Ecuador und Peru. Geographische Rundschau 56:1016.Google Scholar
BENDIX, J., HOMEIER, J., CUEVA ORTIZ, E., EMCK, P., BRECKLE, S.-W., RICHTER, M. & BECK, E. 2006a. Seasonality of weather and tree phenology in a tropical evergreen mountain rain forest. International Journal of Biometeorology 50:370384.CrossRefGoogle Scholar
BENDIX, J., ROLLENBECK, R., GÖTTLICHER, D. & CERMAK, J. 2006b. Cloud occurrence and cloud properties in Ecuador. Climate Research 30:133147.CrossRefGoogle Scholar
BORCHERT, R. 1983. Phenology and control of flowering in tropical trees. Biotropica 15: 8189.CrossRefGoogle Scholar
BORCHERT, R. 1994. Soil and stem water storage determine phenology and distribution of tropical dry forest trees. Ecology 75:14371449.CrossRefGoogle Scholar
BORCHERT, R., RENNER, S. S., CALLE, Z., NAVARRETE, D., TYE, A., GAUTIER, L., SPICHIGER, R. & VONHILDEBRAND, P. 2005. Photoperiodic induction of synchronous flowering near the Equator. Nature 433:627629.CrossRefGoogle ScholarPubMed
BUSSMANN, R. W. 2001. The montane forests of Reserva Biológica San Francisco (Zamora-Chinchipe, Ecuador). Die Erde 132:925.Google Scholar
CASTRO-DIEZ, P., MONTSERRAT-MARTI, G. & CORNELISSEN, J. H. C. 2003. Trade-offs between phenology, relative growth rate, life form and seed mass among 22 mediterranean woody species. Plant Ecology 166:117129.CrossRefGoogle Scholar
CHAZDON, R. L., CAREAGA, S., WEBB, C. & VARGAS, O. 2003. Community and phylogenetic structure of reproductive traits of woody species in wet tropical forests. Ecological Monographs 73:331347CrossRefGoogle Scholar
CUEVA ORTIZ, E., HOMEIER, J., BRECKLE, S.-W., BENDIX, J., EMCK, P., RICHTER, M. & BECK, E. 2006. Seasonality in an evergreen tropical mountain rainforest in Southern Ecuador. Ecotropica 12:6985.Google Scholar
FOURNIER, L. A. & CHARPENTIER, C. 1975. El tamaño de las muestra y frecuencia de observaciones en el estudio de las características de los árboles tropicales. Turrialba 25:4548.Google Scholar
GROMBONE GUARATINI, M. T. & RODRIGUEZ, R. R. 2002. Seed bank and seed rain in a seasonal semi-deciduous forest in south-eastern Brazil. Journal of Tropical Ecology 18:759774.CrossRefGoogle Scholar
HAMANN, A. 2004. Flowering and fruiting phenology of a Philippine submontane rain forest: climatic factors as proximate and ultimate causes. Journal of Ecology 92:2431.CrossRefGoogle Scholar
HAUGAASEN, T. & PERES, C. A. 2005. Tree phenology in adjacent amazonian flooded and unflooded forests. Biotropica 37:620630.CrossRefGoogle Scholar
HOMEIER, J., DALITZ, H. & BRECKLE, S.-W. 2002. Waldstruktur und Baumartendiversität im montanen Regenwald der Estación Cientifica San Francisco in Südecuador. Berichte der Reinhold-Tüxen-Gesellschaft 14:109118.Google Scholar
HOMEIER, J. 2004. Baumdiversität, Waldstruktur und Wachstumsdynamik zweier tropischer Bergregenwälder in Ecuador und Costa Rica. Dissertationes Botanicae 391:1207.Google Scholar
JØRGENSEN, P. M. & LEÓN-YÁNEZ, S. 1999. Catalogue of the vascular plants of Ecuador. Monographs in Systematic Botany from the Missouri Botanical Garden 75:11182.Google Scholar
JUSTINIANO, M. J. & FREDERICKSEN, T. S. 2000. Phenology of tree species in Bolivian dry forests. Biotropica 32:276281.Google Scholar
KNOWLES, O. H. & PARROTTA, J. A. 1995. Amazonian forest restoration: an innovative system for native species selection based on phenological data and field performance indices. Commonwealth Forestry Review 74:230252.Google Scholar
KRISHNAN, R. M. 2002. Reproductive phenology of a wet forest understorey in the Western Ghats, South India. Global Ecology and Biogeography 11:179182.CrossRefGoogle Scholar
LEGENDRE, P. & FORTIN, M.-J. 1989. Spatial patterns and ecological analysis. Vegetatio 80:107138.CrossRefGoogle Scholar
LOBO, J. A., QUESADA, M., STONER, K. E., FUCHS, E. J., HERRERÍAS-DIEGO, Y., ROJAS, J. & SABORÍO, G. 2003. Factors affecting phenological patterns of bombacaceous trees in seasonal forests in Costa Rica and Mexico. American Journal of Botany 90:10541063.CrossRefGoogle ScholarPubMed
MITANI, M. 1999. Does fruiting phenology vary with fruit syndrome? An investigation on animal-dispersed tree species in an evergreen forest in south-western Cameroon. Ecological Research 14:371383.CrossRefGoogle Scholar
MORELLATO, L. P. C., TALORA, D. C., TAKAHASI, A., BENCKE, C. C., ROMERA, E. C. & ZIPPARO, V. B. 2000. Phenology of Atlantic rain forest trees: a comparative study. Biotropica 32:811823.CrossRefGoogle Scholar
NOMURA, N. & KIKUZAWA, K. 2003. Productive phenology of tropical montane forests: fertilization experiments along a moisture gradient. Ecological Research 18:573586.CrossRefGoogle Scholar
PAULSCH, A. 2002. Development and application of a classification system for undisturbed and disturbed tropical montane forests based on vegetation structure. Dissertation, University of Bayreuth, Germany. 152 pp.Google Scholar
PERES, C. A. 2000. Identifying keystone plant resources in tropical forests: the case of gums from Parkia pods. Journal of Tropical Ecology 16:287317.CrossRefGoogle Scholar
RAMIREZ, N. 2002. Reproductive phenology, life-forms, and habitats of the Venezuelan Central Plain. American Journal of Botany 89:836842.CrossRefGoogle ScholarPubMed
REGAL, P. J. 1982. Pollination by wind and animals: ecology of geographic patterns. Annual Review of Ecology and Systematics 13:497524.CrossRefGoogle Scholar
REICH, P. B. 1995: Phenology and seasonality of woody plants: the effects of climate change. A symposium at the 15th International Botanical Congress, Yokohama, Japan, August 1993. Canadian Journal of Botany 73:164–174.Google Scholar
REICH, P. B. & BORCHERT, R. 1984. Water stress and tree phenology in a tropical dry forest in the lowlands of Costa Rica. Journal of Ecology 72:6174.CrossRefGoogle Scholar
RENNER, S. S. 2007. Synchronous flowering linked to changes in solar radiation intensity. New Phytologist 175:195197.CrossRefGoogle ScholarPubMed
RICE, W. R. 1989. Analyzing tables of statistical tests. Evolution 43:223225.CrossRefGoogle ScholarPubMed
RICHTER, M. 2003: Using epiphytes and soil temperatures for eco-climatic interpretations in Southern Ecuador. Erdkunde 57:162181.CrossRefGoogle Scholar
SAKAI, S. 2001. Phenological diversity in tropical forests. Population Ecology 43:7786.CrossRefGoogle Scholar
SMITH, N., MORI, S. A., HENDERSON, A., STEVENSON, D. W. & HEELD, S. V. (eds.) 2004. Flowering plants of the Neotropics. Princeton University Press, Princeton.Google Scholar
STIMM, B., BECK, E., GÜNTER, S., AGUIRRE, N., CUEVA, E., MOSANDL, R. & WEBER, M. 2008. Reforestation of abandoned pastures: seed ecology of native species and production of indigenous plant material. In: Beck, E., Bendix, J., Kottke, I., Makeschin, F. & Mosandl, R. (eds.) Gradients in a tropical mountain ecosystem of Ecuador. Ecological Studies 198. Springer, Berlin.Google Scholar
SUN, C., KAPLIN, B. A., KRISTENSEN, K. A., MUNYALIGOGA, V., MVUKIYUMWAMI, J., KAJONDO, K., MOERMOND, T. C. & KA-KAJONDO, K. 1996. Tree phenology in a tropical montane forest in Rwanda. Biotropica 28:668681.CrossRefGoogle Scholar
URREGO, L. E. & DEL VALLE, J. I. 2001. Relacion Phenologia-clima de algunas especies de los humedales forestales (Guandales) del Pacifico sur Colombiano. Interciencia 26:150156.Google Scholar
VAN DULMEN, A., LINSENMAIR, K. E., DAVIS, A. J., FIALA, B. & SPEIGHT, M. R. 2001. Pollination and phenology of flowers in the canopy of two contrasting rain forest types in Amazonia, Colombia. ‘Tropical forest canopies: ecology and management’. Proceedings of European Science Foundation Conference, Oxford University, 12–16 December 1998. Plant Ecology 153:73–85.CrossRefGoogle Scholar
WOLDA, H. 1988. Insect seasonality: why? Annual Review of Ecology and Systematics 19:118.CrossRefGoogle Scholar
WOLFF, D., BRAUN, M. & LIEDE, S. 2003. Nocturnal versus diurnal pollination success in Isertia laevis (Rubiaceae): a sphingophilous plant visited by hummingbirds. Plant Biology 5:7178.CrossRefGoogle Scholar
WONG, H. & LING, S. 2003. Mixed Portmanteau tests for time-series models. Journal of Time Series Analysis 26:569579.CrossRefGoogle Scholar
WRIGHT, S. J. & CALDERON, O. 1995. Phylogenetic patterns among tropical flowering phenologies. Journal of Ecology 83:937948.CrossRefGoogle Scholar
WRIGHT, S. J. & VANSCHAIK, C. P. 1994. Light and the phenology of tropical trees. The American Naturalist 143:192199.CrossRefGoogle Scholar
YEANG, H.-Y. 2007. Synchronous flowering of the rubber tree (Hevea brasiliensis) induced by high solar radiation intensity. New Phytologist 175:283289.CrossRefGoogle ScholarPubMed
ZIMMERMAN, J. K., WRIGHT, S. P., CALDERÓN, O., APONTE PAGAN, M. & PATON, S. 2007. Flowering and fruiting phenologies of seasonal and aseasonal neotropical forests: the role of annual changes in irradiance. Journal of Tropical Ecology 23:231251.CrossRefGoogle Scholar