Introduction
Land-use change can lead to habitat loss and fragmentation, and these are two of the greatest threats to forest ecosystems (Noss, Reference Noss2001; Baillie et al., Reference Baillie, Hilton-Taylor and Stuart2004). Land-use change modifies connectivity, and patch density and area of forest (Lindenmayer & Fischer, Reference Lindenmayer and Fischer2006). These changes can influence ecological attributes at the species and community levels, such as species richness and individual density (Laurance et al., Reference Laurance, Vasconcelos and Lovejoy2000; Bustamante et al., Reference Bustamante, Serey, Pickett, Bradshaw and Marquet2003; Simonetti et al., Reference Simonetti, Grez, Bustamante, Grez, Simonetti and Bustamante2006). Habitat loss and fragmentation can affect species’ survival by reducing the quality and quantity of habitat available (Tomimatsu & Ohara, Reference Tomimatsu and Ohara2003), both of which can alter the dynamics of a species’ population. Such alteration could lead to local and global extinction of the most vulnerable species (Bennett, Reference Bennett2003).
The impact of land-use change on threatened species warrants investigation (Turner, Reference Turner1989; Lindenmayer & Fischer, Reference Lindenmayer and Fischer2006) to facilitate understanding of the way in which it can alter the composition and spatial configuration of the unique habitats on which threatened species depend, the influence of such alterations on species composition, the influence of the matrix, and the minimum buffer zone needed for management of the remaining interior habitats (Oliveira et al., Reference Oliveira, Grillo and Tabarelli2004). Multi-scale studies (landscape, habitat and species) could provide valuable information for the conservation of threatened species (Vergara & Simonetti, Reference Vergara and Simonetti2004).
Chilean temperate forest, which has been designated a hotspot for biodiversity conservation because of its high level of endemism (Myers et al., Reference Myers, Mittermeier, Mittermeier, da Fonseca and Kent2000), has experienced significant degradation, fragmentation and loss since 1985 as a result of land-use change (Echeverría et al., Reference Echeverría, Newton, Nahuelhual, Coomes and Rey Benayas2012). Consequently there have been significant changes in richness of plant (Echeverría et al., Reference Echeverría, Newton, Lara, Rey Benayas and Coomes2007) and bird species (Vergara & Simonetti, Reference Vergara and Simonetti2004) and the spatial distribution of threatened species (Altamirano et al., Reference Altamirano, Echeverría and Lara2007).
The Patagonian cypress Fitzroya cupressoides, an endemic and monotypic conifer of the temperate forests of southern Chile and Argentina, is categorized as Endangered on the IUCN Red List (Premoli et al., Reference Premoli, Quiroga, Souto and Gardner2013). Individuals can live for >3,600 years, making it the second longest-lived species and thus of high scientific value (Lara & Villalba, Reference Lara and Villalba1993). Since the arrival of Europeans in the south of Chile in 1850 F. cupressoides has been overexploited for its beautiful and decay-resistant wood. In Chile the species is found in the Coastal Range, the Andean Range and the Central Depression (Fraver et al., Reference Fraver, González, Silla, Lara and Gardner1999). The species is known from 13 sites in the Central Depression, five containing small remnant populations and eight supporting scattered trees and saplings in a landscape transformed by human activities such as logging for firewood and expansion of pastureland for cattle grazing (Fraver et al., Reference Fraver, González, Silla, Lara and Gardner1999). Genetic studies indicate that the F. cupressoides populations in the Central Depression are the most genetically distinct of the remaining populations in Chile and Argentina (Premoli et al., Reference Premoli, Vergara, Souto, Lara and Newton2003), and represent ancient populations from the glacial era, from which the other populations are derived (Premoli et al., Reference Premoli, Vergara, Souto, Lara and Newton2003).
Studies have focused on the reproductive biology, ecology and distribution of F. cupressoides (Armesto et al., Reference Armesto, Smith-Ramirez, León and Arroyo1992; Donoso et al., Reference Donoso, Sandoval, Grez and Rodríguez1993; Fraver et al., Reference Fraver, González, Silla, Lara and Gardner1999) but none have quantified the impact of land-use change on the spatial patterns of the species’ habitat and examined the effect of habitat fragmentation and loss on population composition. This type of information is necessary to assess the current status of F. cupressoides populations, which may have been significantly altered in Chile.
We assessed the impact of land-use change on the spatial pattern of the forest landscape and the habitat of F. cupressoides in the Central Depression in southern Chile, and related changes in spatial pattern to the composition of four remaining populations. We hypothesize that human-induced land-use change has substantially fragmented the remaining F. cupressoides habitat, resulting in reduced population density and variation in community composition.
Study area
The study area (1,430 km2) was defined by the distribution of four remaining populations of F. cupressoides in the Central Depression, Chile (Fraver et al., Reference Fraver, González, Silla, Lara and Gardner1999), and by Landsat satellite images used to determine land-use change (Fig. 1). The area, characterized by a cold oceanic climate, has a maximum elevation of 200 m, mean temperature of 11.5°C and annual rainfall of 1,912 mm. The landscape in this area is dominated by patches of broad-leaved evergreen native forest of the Valdivian Rainforest.
Methods
Land-use change analyses were performed based on maps of land use, with 30 x 30 m pixels, derived from Landsat satellite images for 1999 and 2011 (Echeverría et al., Reference Echeverría, Newton, Nahuelhual, Coomes and Rey Benayas2012). Land use was categorized as native forest, shrubland, wetland, grassland, forest plantations of exotic species or other uses (bare soil, urban areas and water bodies). Changes in spatial patterns of the forest landscape were assessed by determining the total area and number of patches of native forest, using FRAGSTATS v. 3.3 (McGarigal et al., Reference McGarigal, Cushman, Neel and Ene2002) and the Spatial Analyst extension for ArcGIS v. 9.3.1 (ESRI, Redlands, USA).
Four of the five known F. cupressoides populations in the Central Depression were included in the study; the fifth population was not assessed because access to information about it was limited. Spatially explicit information on the locations of populations was provided by Corporación Nacional Forestal.
The habitat of F. cupressoides in the Central Depression is characterized by poorly drained acidic soils (pH of 5.0) known as ñadis (Fig. 1; FAO-UNESCO, 1971), which means seasonal swamp in the indigenous Mapudungun language. These soils have a depth of 40–100 cm, abundant humus, moss beds and coarse woody debris. The habitat of F. cupressoides is also characterized by a cold oceanic temperate climate, with annual mean temperature and rainfall of 11.5°C and 1,912 mm, respectively, and by the presence of the following species of plants: Amomyrtus luma, Drimys winteri, Laureliopsis philippiana, Saxegothaea conspicua and Weinmannia trichosperma (IUCN, 2013).
A previous study in the same area revealed a relationship between F. cupressoides habitat and the interior of small patches of native forest (Fraver et al., Reference Fraver, González, Silla, Lara and Gardner1999), which had a core area of <3 ha and a buffer zone of ≥137 m. Fraver et al. (Reference Fraver, González, Silla, Lara and Gardner1999) reported that in the patches of native forest where edge effects (altered species composition, community structure and microclimate) occurred within 137 m of the patch edge, F. cupressoides populations were not present and only a few scattered F. cupressoides were recorded. Following the approach of Fraver et al. (Reference Fraver, González, Silla, Lara and Gardner1999) we defined the potential habitat of F. cupressoides as an area of native forest <3 ha with a buffer zone of ≥120 m.
Areas of potential habitat for F. cupressoides were identified by analysing the core area and buffer zone of native forest patches, using the Land Change Modeler for Ecological Sustainability extension of IDRISI Andes (Clark Labs, Worcester, USA), which generated maps of potential habitat for the years 1999 and 2011. Changes in spatial patterns of potential habitat were evaluated by analysing the total area (ha) and number of potential habitat patches over time, using FRAGSTATS. Subsequently we identified the habitat patches that include the four remaining populations of F. cupressoides.
In 2011 we recorded the tree density (based on individuals with diameter at breast height (DBH) ≥5 cm and height ≥2 m) and level of regeneration (based on seedlings with DBH <5 cm and/or height <2 m) in the four F. cupressoides populations (Fig. 1). We established two 20 x 25 m sampling plots randomly within each forest patch, taking into account the small size of the patches and the likelihood of edge effects. To facilitate data collection each plot was divided into 10 5 x 10 m subplots, following the methods of Peet et al. (Reference Peet, Wentworth, Duncan and White1996). We estimated the number of plant species present in native forest patches where F. cupressoides was present (Jiménez-Valverde & Hortal, Reference Jiménez-Valverde and Hortal2003). This information was analysed together with the area of the native forest patches where F. cupressoides was present, and the area of F. cupressoides habitat and the matrix that surrounded each F. cupressoides population.
Results
There was a loss of 18% of native forest in the study landscape from 1999 to 2011 (i.e. a mean annual loss of 1.6%; Supplementary Fig. S1). In 1999 there were 9,478 patches of native forest, with a total area of 46,129 ha. The number of patches in 2011 (22,446) was more than double that in 1999, with a reduction in total area to 37,948 ha, and shrubland had become the dominant land cover type
There was a 46% loss in potential habitat for F. cupressoides from 1999 to 2011 (i.e. a mean annual loss of 5.1%). In 1999 potential habitat for the species occurred in 112 patches of native forest (a total of 26,122 ha). In 2011 the number of patches had decreased to 36 and the total area to 14,076 ha. In 1999 the four F. cupressoides populations occurred in patches of 5–36 ha. In 2011 these patches were 0.4–27 ha (Table 1). Losses of 38, 100, 54 and 79% of potential habitat were recorded over the entire study period for populations 1, 2, 3 and 4, respectively (Table 1).
There appeared to be a correlation between lower density of F. cupressoides seedlings and trees and greater loss of potential habitat (Table 1). In 2011 for the population with a loss of 38% of potential habitat we recorded a density of 2,270 trees per ha and regeneration of 4,340 trees per ha. For the population with a loss of 100% of potential habitat the density was 40 trees per ha and there was no regeneration (Table 1).
The populations of F. cupressoides for which greater loss of habitat was recorded were those surrounded by an anthropogenic matrix and were associated with plant communities with the greatest number of native and exotic species (Table 1). In 2011 the population for which a 38% loss of potential habitat was recorded was located in the largest patch of native forest (27 ha), embedded in a matrix dominated by native forest, and associated with a community with the lowest richness of exotic plant species (Table 1). The population for which a 100% loss of potential habitat was recorded was located in the smallest patch of native forest (0.4 ha), embedded in a matrix dominated by grassland, and associated with a community with the greatest richness of exotic plant species (Plantago truncata, Poa annua and Prunella vulgaris; Table 1).
Discussion
Changes in the forest landscape and Fitzroya cupressoides habitat
Our results indicate there was a substantial loss of native forest in the study landscape from 1999 to 2011, although the annual rate of loss (1.6%) was lower than that recorded for other hotspot landscapes that have been significantly transformed, such as the Maulino temperate forest in central Chile (4.5% annual loss; Echeverría et al., Reference Echeverría, Coomes, Salas, Rey Benayas, Lara and Newton2006) and the tropical montane forest of Chiapas, Mexico (3.05% annual loss; Cayuela et al., Reference Cayuela, Rey Benayas and Echeverría2006). The loss of native forest area was associated with an increase in the number of patches, from 9,478 in 1999 to 22,400 in 2011, which is one of the main symptoms of fragmentation (Lindenmayer & Fischer, Reference Lindenmayer and Fischer2006). The trend in fragmentation is similar to that reported for other temperate landscapes in Chile where threatened tree species occur (Bustamante & Castor, Reference Bustamante and Castor1998), as well as in tropical montane landscapes of conservation importance in Mexico (Cayuela et al., Reference Cayuela, Rey Benayas and Echeverría2006). This trend of loss and fragmentation of native forest in the study landscape was associated with a significant loss (46%) of potential habitat for F. cupressoides since the early 2000s, with a decrease in the number of patches of potential habitat from 112 to 36. If the current trajectory of loss and fragmentation of native forest continues, further losses of potential habitat for F. cupressoides can be expected.
Changes at the population and community level in 2011
We observed differences in habitat loss in each of the four F. cupressoides populations, associated with the densities of the populations. The smallest habitat patches had the lowest densities of F. cupressoides. Similar trends have been reported for other threatened plant species in Chile, such as Nothofagus alessandrii (Bustamante & Castor, Reference Bustamante and Castor1998) and Legrandia concinna (Altamirano et al., Reference Altamirano, Echeverría and Lara2007), for various species of birds (Vergara & Simonetti, Reference Vergara and Simonetti2004; Simonetti et al., Reference Simonetti, Grez, Bustamante, Grez, Simonetti and Bustamante2006), and for some populations of insectivorous birds, primates and mammals in the Amazon rainforest (Laurance et al., Reference Laurance, Vasconcelos and Lovejoy2000). A reduction in habitat size may decrease the density of F. cupressoides populations and thus increase the risk of extinction for this species.
Our results show that differences in the spatial patterns of habitat for the four F. cupressoides populations were associated with differences in the plant species richness of the associated communities. As the size of F. cupressoides habitat patches decreased, the number of native and exotic plant species increased. In the Chilean temperate forest a similar trend in community composition was reported for plants (Bustamante & Grez, Reference Bustamante and Grez1995), birds (Vergara & Simonetti, Reference Vergara and Simonetti2004) and small mammals (Kelt, Reference Kelt2000). In boreal (Chávez & Macdonald, Reference Chávez and Macdonald2010) and tropical areas (Trauernicht & Ticktin, Reference Trauernicht and Ticktin2005) this change is less dramatic, perhaps because forest landscapes have not been transformed to the same extent. Other factors may also influence changes in the plant species richness of communities associated with patches of native forest where F. cupressoides occurs. The matrix may induce several types of abiotic changes at the edge of forest patches, resulting in the potential establishment and recruitment of generalist plant species (Bustamante et al., Reference Bustamante, Serey, Pickett, Bradshaw and Marquet2003). The combination of different patch sizes and matrix composition may have influenced the establishment of generalist native and exotic species in each community where F. cupressoides was present.
Implications for conservation
The Central Depression is located in a landscape that has been subjected to constant anthropogenic pressure (Torrejón et al., Reference Torrejón, Cisternas, Alvial and Torres2011). From the 16th to the 19th century significant changes in the spatial patterns of native forest were caused mainly by extensive wood extraction (Torrejón et al., Reference Torrejón, Cisternas, Alvial and Torres2011), whereas since the 1970s the greatest changes in the spatial patterns of native forests have been caused by commercial plantations and expansion of pastureland for cattle grazing (Echeverría et al., Reference Echeverría, Newton, Lara, Rey Benayas and Coomes2007, Reference Echeverría, Newton, Nahuelhual, Coomes and Rey Benayas2012). The landscape of the Central Depression is under increasing pressure from the cities of Puerto Montt and Puerto Varas (Fraver et al., Reference Fraver, González, Silla, Lara and Gardner1999), and anthropogenic land use may result in further changes in the spatial patterns of native forest and F. cupressoides habitat (Armesto et al., Reference Armesto, Smith-Ramirez, León and Arroyo1992; Wilson et al., Reference Wilson, Newton, Echeverría, Weston and Burgman2005).
Fitzroya cupressoides was listed in Appendix I of CITES in 1975 and declared a Natural Monument by the Chilean government in 1976. Our multi-scale study has shown a progressive and severe loss of native forest with F. cupressoides populations from 1999 to 2011. If habitat loss continues, the population density of F. cupressoides may decrease further, increasing the risk of extinction for the species. As a first step in conserving F. cupressoides we suggest a landscape approach, using the corridor–patch–matrix model (Lindenmayer & Franklin, Reference Lindenmayer and Franklin2002), as a strategy for conservation planning. This is appropriate given the current configuration of the landscape, with native forest restricted to small patches sparsely distributed across the landscape. The main objective of the corridor–patch–matrix model is to maintain the quality and quantity of patches of native forest through management of the matrix (Lindenmayer & Franklin, Reference Lindenmayer and Franklin2002). The condition of the matrix may be more important in determining the survival of the species than the isolation of patches (Lindenmayer & Franklin, Reference Lindenmayer and Franklin2002). In the study landscape the management of the matrix should focus on sensitive buffer areas that improve the connectivity between forest patches and increase the ability of the matrix to support F. cupressoides populations. We recommend that this strategy be complemented with land-use planning focused on sustainable production practices such as agroforestry. The design and implementation of such a strategy requires identification and evaluation of sensitive buffer areas and their connectivity. Moreover, this strategy must be supported by a framework of environmental policies.
We recommend that the Chilean government expands the country's protected areas to conserve F. cupressoides populations and promote conservation of the species. At present there is only one protected F. cupressoides population in the Central Depression, which is the Monumento Natural Lahuen Ñadi. We also recommend strengthening the existing restoration programmes for F. cupressoides, and developing new programmes, to improve the quality of habitats for F. cupressoides. These programmes could include patches of native forest that are potential habitat for the species, monitoring to assess the viability and success of conservation efforts, and investment of capital. Researchers from the Universidad Austral de Chile, land owners, and Corporación Nacional Forestal are already participating in restoration programmes (Premoli et al., Reference Premoli, Quiroga, Souto and Gardner2013) but the conservation of F. cupressoides also requires the commitment and active participation of the Chilean government and the general community.
Acknowledgements
We thank FONDECYT project 1085077, CONAF, Alberto Hernández, Natalia Medina, Víctor Sandoval, and Laboratorio de Ecología de Paisaje of the Universidad de Concepción. We also thank the Ministry of Education of Chile for a MECESUP scholarship.
Biographical sketches
James Rodríguez-Echeverry is a biologist interested in landscape ecology, ecological restoration and conservation. His research focuses on global change, threatened species, biodiversity and ecosystem services in the landscapes of Latin America. Cristian Echeverría is a forester interested in landscape ecology and conservation. His research focuses on threatened species, landscape change and ecological restoration of degraded forests in Latin America. Laura Nahuelhual is an agronomist interested in the economics of natural resources and rural development. Her research focuses on assessment and economic valuation of ecosystem services in Latin America.