There is a long‐standing debate on whether the occurrence of the iconic high‐Andes Polylepis woodlands as small and isolated fragments is of natural or anthropogenic origin. We make inferences regarding the fragmentation history based on both a new population genetic study on P. besseri and a synthesis of available studies on the population genetics of Polylepis woodlands. We infer the timing of the main woodland fragmentation event by analysing: (1) the remaining levels of population genetic diversity and the relation to population size; (2) among‐population genetic differentiation; and (3) the difference in genetic diversity between the offspring and adult generation. We retrieved seven publications on the population genetics of five Polylepis spp. We did not find a relationship between population size and genetic diversity, and genetic differentiation was low compared with that reported for similar plant species. These findings do not support a history of long‐term fragmentation. The offspring showed a loss of genetic diversity and increasing differentiation compared with adults, suggesting that the main habitat fragmentation event is of relatively recent origin. For P. besseri, no significant differences were found between the adult and offspring genetic variation. We discuss the conservation and restoration consequences for this important high‐Andean genus. © 2013 The Linnean Society of London, Botanical Journal of the Linnean Society, 2013, 172, 544–554.
High-altitude Polylepis besseri woodlands in Bolivia are under increasing threat from human use and disturbance. Currently, there is no information regarding P. besseri growth rates, age structures or the relationship between environmental variables and growth. Such information would be useful for effective management and conservation of the remaining woodlands. We used standard dendrochronological techniques to determine the age and radial growth rates for 23 trees from two Polylepis besseri populations in Sacha Loma (mountains Uypa and Chutu Senega), and investigated the relationship between climate and radial growth. Wood samples exhibited semicircular porosity and visible tree-ring boundaries. The sample trees were young (mean age 40 years, max age 63 years) and growing slowly (\1 mm/year). Trees at Chutu Senega were older and growing more slowly than those at Uypa. The strong linearity of cumulated radial increments suggest that P. besseri may maintain consistent growth rates beyond 60 years. Our results indicate that radial growth is limited by the accumulation of reserves the year before ring formation, and that a warm period before the growing season (humid period) can increase P. besseri's growth in the Bolivian-Tucuman biogeographic Province. It seems that local factors are more important than regional factors in these high Andean woodlands. This study improves our understanding of the biology of Polylepis and demonstrates the usefulness of dendrochronology for investigating the biotic, abiotic and anthropogenic effects on woodlands in areas lacking long term historical data.
Seed germination is a crucial event in a plant's life cycle. Because temperature and water availability are important regulators of seed germination, this process will likely be influenced by global warming. Insight into the germination process under global warming is thus crucial, and requires the study of a wide range of water availability and temperature conditions. As hydrothermal time (HTT) models evaluate seed germination for any combination of water potential and temperature, they can be suitable to predict global warming effects on seed germination. We studied the germination characteristics of the high Andean endemic tree speciesPolylepis besseri(Rosaceae), using HTT models. We were especially interested in the potential effects of global warming on seed germination. Assembly of HTT models forP. besseriwas fairly straightforward due to the lack of a seed dormancy mechanism. The models allowed prediction ofPolylepisgermination under constant and alternating temperatures. Initially, a global warming induced increase in the field minimum and mean temperature will increaseP. besserigermination, but as maximum temperatures rise above the optimum temperature for the species, seed germination will become jeopardized. Effects of global warming on seed germination are currently considerably underexplored. HTT models prove to be useful tools to study a plant species' general germination characteristics, and how they may become affected under global warming. For the endemic mountain tree speciesP. besseri, we predict an increase, followed by a decrease of seed germination under global warming.
Polylepis forests are endemic to the high-Andes, with trees characterized by multi-layered, exfoliating bark-providing protection against harsh, high-elevation conditions, both for individual trees and the wide array of organisms dependent on them. However, Polylepis habitat has suffered severe human-induced land conversion and currently mainly occurs as fragmented remnants only. Here, we studied the effects of fragment size on local ambient temperature and on biomass of bark and its bark-dwelling arthropods. We did so by comparing multiple samples at the edge and interior of both large and small fragments, while also accounting for branch size, tree width, and tree structure. Because arthropod biomass is likely to impact higher trophic levels, we also studied abundance and foraging behavior of two bird species specialized on Polylepis forest. We show that arthropod biomass was relatively higher in wider, larger trees, which were preferred for foraging by both bird species. Moreover, we show that small forest fragments are not only environmentally less buffered but are also characterized by lower amounts of bark and lower densities of bark-dwelling arthropods than larger fragments. Our study highlights the conservation value of large trees. Also, we advise it is now timely to test to what degree restoration efforts to increase fragment size could mitigate the negative effects of reduced arthropod biomass for higher trophic levels of endemic specialist insectivores.
ESTE ESTUDIO VINCULA LA PROBLEMÁTICA FORESTAL Y AMBIENTAL A NIVEL MICRO con el nivel de políticas más sectorial a través de un estudio de caso y consulta a expertos locales y nacionales. Aporta al conocimiento de las principales barreras legales e institucionales que impiden a los finqueros ganaderos fomentar y aprovechar mejor el recurso arbóreo en sus fincas. Identifica medidas de políticas y ajustes al marco legal forestal que podrían contribuir a favorecerlo. El estudio discute sobre el desconocimiento de la legislación forestal del país entre los finqueros y una falta de coordinación entre los actores institucionales, INAFOR y alcaldías, en relación con la gestión del recurso y el otorgamiento de permisos para aprovechamiento, lo que favorece la ilegalidad y la no sostenibilidad de los recursos forestales. Se concluye que en zonas ganaderas del interior existe un potencial de aprovechamiento forestal que puede ser explotado de manera sostenible si se dirige la atención a mejorar los conocimientos del marco regulatorio, la capacidad de manejo técnico del recurso arbóreo en fincas, el entrenamiento en el manejo de la legislación y los procedimientos para el aprovechamiento forestal, y la articulación entre el INAFOR y las municipalidades en un marco de descentralización.
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