Zoraida Calle scite author profile

In tropical rainforests, 30-65% of tree species grow at densities of less than one individual per hectare. At these low population densities, successful cross-pollination relies on synchronous flowering. In rainforests with low climatic seasonality, photoperiodic control is the only reliable mechanism for inducing synchronous flowering. This poses a problem because there is no variation in day length at the Equator. Here we propose a new mechanism of photoperiodic timekeeping based on the perception of variation in sunrise or sunset time, which explains and predicts the annually repeated, staggered, synchronous and bimodal flowering of many tree species in Amazonian rainforests near the Equator.

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Leaf-cutting ants revisited: Towards rational management and control

Lerma¹,

Giraldo-Echeverri²,

Armbrecht³

et al. 2012

International Journal of Pest Management

132

127

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Insolation and photoperiodic control of tree development near the equator

et al. 2014

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Seasonal variation in daily insolation induces synchronous bud break and flowering in the tropics

Calle

Schlumpberger

Piedrahita

et al. 2010

Trees

104

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In many temperate plants seasonal variation in day length induces flowering at species-specific times each year. Here we report synchronous bud break and flowering of tropical perennials that cannot be explained by seasonal changes in day length. We recorded flushing and flowering of more than 100 tropical trees, succulents and understory herbs over several years. We observed the following phenological patterns throughout the northern Neotropics: wide-ranging trees flush or flower twice a year at the Equator, but annually further north; many trees leaf out in February; in autumn, wide-ranging perennials flower 4 months earlier in Mexico than at the Equator. This latitudinal variation of phenology parallels that of the annual cycle of daily insolation, a function of day length and solar irradiation. Insolation has two annual maxima at the Equator, it rapidly increases in February at all latitudes, and between Mexico and the Equator its maximum shifts from the summer solstice to the autumn equinox. These unique, manifold correlations suggest that throughout the tropics insolation, rather than day length, may control the phenology of many perennials. Our observations significantly extend current knowledge of environmental signals involved in photoperiodic control of plant development.

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Zoraida Calle

Native trees and shrubs for the productive rehabilitation of tropical cattle ranching lands

Photoperiodic induction of synchronous flowering near the Equator

Leaf-cutting ants revisited: Towards rational management and control

Insolation and photoperiodic control of tree development near the equator

Seasonal variation in daily insolation induces synchronous bud break and flowering in the tropics

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