Abstract
Vegetation’s increased vulnerability to extrinsic disturbances is an important but less studied effect of natural habitat fragmentation. Fire is part of the evolutionary history of grassland ecosystems, but fragmentation by forest plantations can alter the fire regime and influence their resilience. This study compares the successional trajectories after fire in continuous and fragmented grassland in terms of composition and abundance of plant species. Grassland fragments of varying sizes (0.1 to 2.5 ha) surrounded by a forest matrix and grassland controls of an equivalent area in adjacent, non-fragmented sites were selected. Fire was associated with an increase in the abundance of exotic plants in the fragmented grassland whereas the continuous grasslands were much more resistant to invasion. These differences in the species composition between fragments and continuous areas, which were limited to the smaller areas before the fire, were observed one year after the fire throughout the range of sizes analyzed. These results show the impact of fragmentation on grassland resilience and how the effects of this process become evident even months after a disturbance, highlighting the synergistic effect of habitat fragmentation and biological invasions, two factors identified as the main forces of biodiversity erosion.
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Introduction
The fragmentation of natural habitats is one of the main processes responsible for the global crisis of biodiversity loss and the degradation of ecosystems around the world1,2, and consists of the division of a continuous area of natural habitat into two or more fragments surrounded by a modified landscape matrix3. The isolation of the fragments generated and the influence of the matrix from the resulting edges, increase the vulnerability of vegetation to extrinsic disturbances such as fire4. The importance of this greater vulnerability has been less recognized than other aspects of habitat degradation; however, it has significant implications for the long-term viability of fragmented habitats5. Wilson et al.2 argue that habitat fragmentation can alter successional trajectories and suggest that the intensity of these changes will depend on the intensity of the disturbance and the size of the area that is being disturbed. However, synergies like the interaction between fragmentation and an extrinsic disturbance, such as fire, need to be further studied1.
Grassland is recognized as the terrestrial biomes with biodiversity and ecosystem services that are most at risk worldwide due to the great disparity between the rate of habitat loss and the degree of effective protection6,7. Most studies on fragmentation have focused on the replacement of areas occupied by natural forests by fragments surrounded by pastures and crops4,8,9, whereas much less is known about the opposite change, i.e. the establishment of forest plantations in grassland areas10,11. In particular, the grasslands of southeastern South America have undergone a process of transformation and fragmentation due to the advance of various anthropogenic interventions12, and grasslands in good conservation status are restricted to habitats where the agricultural edge has not been able to advance, such as in rocky outcrops, wetlands, and coastal dunes13,14. Beyond the limits imposed by agriculture on the nutrient-poor soils of coastal dune habitats, the plant communities of these habitats face the challenge of urbanization and afforestation with conifers and other exotic tree species12.
Fire has been one of the main selective forces in grassland ecosystems; native species have evolved with this natural disturbance and therefore acquired adaptations that allow them to survive15,16. Fire is an important factor in the ecological successional of plant communities, but its effects on the species composition of vegetation and ecosystem functions vary with its intensity, frequency, and duration17,18. Natural fire regimes are different in different biomes and between different habitats, since the structure of the preexisting vegetation conditions fire intensity19,20. Afforestation in prairie habitats generates particularly significant changes in the characteristics of fires. This is because the temperature and the severity of the fire increase with the amount of easily combusted material accumulated, whereas the burnt grassland areas experience relatively low temperatures that do not completely eliminate the vegetation cover and do not affect the organic carbon reservoirs in the soil. Fragmentation by forest plantations can alter the traditional fire regime in grassland, increasing its negative effects on the vegetation and soil. Many disturbances of human origin modify some properties of the system that deeply condition their successional response, altering species composition by decreasing the abundance of native plants and creating opportunities for exotic plants to invade15,16,21,22. Fragmentation by forest plantations is likely to alter fire regimes and also to influence the resilience of fragmented grassland by changing species composition and its response after the disturbance20.
In Argentina, the coastal dunes of the Pampas are better conserved comparatively than the rest of the grasslands, but they also present threats derived from anthropogenic activities that result in habitat loss and fragmentation, mainly through the establishment and expansion of urban nuclei and afforestation with exotic species12,23,24. Afforestation fragments the coastal ecosystem, changing the species composition of the vegetation and increasing the number of exotic plants, mainly in remnants of smaller size11. This study focuses on the interaction between fragmentation (a result of human activities) and fire (a natural disturbance) in grasslands growing on sand dunes on the coast of Buenos Aires province (Argentina), surrounded by a plantation of Pinus pinaster (maritime pine), a species with invasive behaviour25,26,27. In this paper, we analyze the effects of this synergy by evaluating the recovery processes after the fire in continuous and fragmented grassland28 in terms of composition and abundance of plant species. We propose that fragmentation will affect the successional trajectory of the burnt habitats, with increases in the abundance of exotic species in the fragments immersed in the forest matrix with respect to the continuous grassland, and that this difference will be more significant in the smaller fragments.
Materials and Methods
Study area
The coastal dunes of the extreme south of the Pampas29 occupy the southwest of Buenos Aires province, Argentina, on a strip along the Atlantic coast that extends between approximately 38°55′46″S – 60°30′32″W and 39°00′12″S – 61°33′12″W. This coastal strip varies between two and seven kilometers in width, including the beaches, bare dunes, dunes covered with vegetation, and depressions between the dunes with small lagoons associated to humid grassland. The climate is temperate, being influenced by the proximity to the sea30. Communities of the species Hyalis argentea, Panicum urvilleanum, Thelesperma megapotamicum and Oenothera sp. dominate the dunes31. Pampas grass (Cortaderia selloana), rushes (Juncus acutus), sedges (Schoenoplectus americanus) and bulrushes (Typha latifolia) are found in the depressions between the dunes32,33.
The natural landscape is well-preserved34, free of crops and subject to extensive livestock production. The area includes tourist localities associated with plantations of eucalyptus (Eucalyptus spp.) and pines (mainly Pinus pinaster and P. radiata). The latter has the ability to expand spontaneously over dune habitats35. This study was carried out in a set of natural grassland remnants of different sizes surrounded by a plantation of maritime pine (P. pinaster; 38°55′S – 60°33′O) covering 30 ha, and in adjacent continuous grassland. Both the plantation and the continuous grassland were completely burnt by a wildfire on January 6th, 2014.
Study design and field sampling
Remnants of natural vegetation surrounded by the pine plantation were identified from a satellite image of the site taken from Google Earth and dated December 14th, 2006. Their surface area was measured using Google Earth Pro. The fragments were identified in the field, confirming that there had been no changes in their surface area and shape since the capture of the satellite images. Six grassland fragments of up to 0.1 ha were selected, three from 0.1 to 0.5 ha, and six from 0.5 to 2.5 ha, totalling 15 sample units. Fifteen continuous grassland controls without afforestation of equivalent surface areas were selected in neighbouring areas.
The data used for this study were taken before the fire occurred, and then three and fifteen months afterwards. In each case, we estimated the percentage cover of all plant species present and the cover of bare ground following the method of relevés of Braun Blanquet36. Plants were identified to the species and/or genus level37 and were classified as native or exotic. The Catalog of Vascular Plants of the Southern Cone38 was used for nomenclature.
Data analysis
Ternary diagrams were used to observe the progression of changes in the cover of native and exotic plants and of bare ground in fragments of different sizes and in the continuous grassland controls before the fire, and three and fifteen months after the fire.
The Kruskal-Wallis test with multiple comparisons as post hoc tests39 were applied to analyse the effects of the successional stage (before the fire, and three and fifteen months afterwards), the context (fragmented grassland or continuous grassland), and the size of the areas (small, intermediate, or large), on the cover of native and exotic plants and of bare ground. The normality of the data was evaluated for the study of residuals and of normal probability plots. The Levene test was used to verify homogeneity of variances.
Species composition of the sampling sites was compared by means of a Principal Component Analysis (PCA) based on the covariance matrix of the species cover data with the objective of identifying sets of species associated with the size and context of the samples, and with the different successional stages related to fire. The data were transformed using the arc sine of the square root to correct the distortion of the Euclidean distance in its spatial representation40. To maintain an appropriate balance between the number of samples and variables (coverage by species) the plants present in less than 33% of the samples (75 species) was excluded from the analysis. All analyses and graphs were performed using the Infostat and XLSTAT statistical packages.
Results
The after-fire successional trajectories of the grassland fragments surrounded by pine plantations and of the continuous grassland controls were qualitatively similar with respect to the cover of the native and exotic plants and of bare ground, regardless of the size of the plots. There was a decrease in the cover of native species three months after the fire and an increase after fifteen months. The percentage of bare ground showed the opposite behaviour, whereas the cover of exotic species was constant throughout the entire sampling period, except in the case of the fragments surrounded by the forest matrix, where it increased fifteen months after the fire. The changes described were much more noticeable in the fragments than in the continuous grassland controls. The greatest differences between the fragments and controls were observed in the smaller areas (Fig. 1).
An effect of the context, the area and the successional stage in relation to the fire was observed for both the bare ground and the vegetation cover (H = 40.97, P = 0.0009 for bare soil; H = 43.37, P = 0.0004 for native; H = 39.14, P = 0.0012 for exotic). Before the fire, the cover of bare ground was greater in the small and intermediate fragments with respect to the controls, but showed no differences in the larger areas. In the continuous grassland the bare ground cover did not vary with area, whereas in the fragmented grassland it decreased in the larger areas. No significant differences were observed between fragments and controls for any of the sizes analyzed three and fifteen months after the fire. In both contexts (fragmented grassland and continuous grassland) the proportion of bare soil was greater three months after the fire compared to the pre-fire stage (Fig. 2). In the pre-fire stage, the cover of native plants was significantly higher in the continuous grassland controls compared to the fragments surrounded by afforestation for the small and intermediate areas. The cover native plants remained unchanged with the increase in area in the controls, but increased in the larger fragments. In the stages after the fire, no significant differences were observed in the cover of native plants between fragments and controls for any of the sizes analyzed, nor between the different areas within each context (Fig. 3). The cover of exotic plants was significantly higher in the fragments compared to the controls in the small areas before the fire, remaining unchanged with the increase in area in both contexts (fragmented grassland and continuous grassland). Three months after the fire, no significant differences were observed, while fifteen months later the coverage of exotic plants was significantly higher in the fragments compared to the controls in the small and intermediate areas. The intermediate fragments showed a greater coverage with respect to the pre-fire stage (Fig. 4). Fifteen months after the fire, 24% of the coverage of exotic species in the large fragments corresponded to the pines that advanced from the matrix, representing a six-fold increase over the pine cover before the fire (4%). Pine coverage in the same time interval increased from 0% to 22% in the case of intermediate fragments and from 0% to 23% in small fragments.
The Principal Components Analysis resulted in a grouping of the samples according to the context (fragmented grassland and continuous grassland), the size of the areas, and successional stages with respect to fire. The first component (20.04% total variance) separated the smaller fragments surrounded by the forest plantation with respect to the smaller continuous grassland controls (Fig. 5a). The samples corresponding to the fragments formed a group on the left end of the component characterized by a greater abundance of exotic species: Senecio madagascariensis, Hypochaeris radicata, Acacia longifolia and Pinus pinaster, with negative correlations with the first component. At the other end of PC1, the plots corresponding to the controls formed a second group, associated with high coverage values of grasses and other native species typical of the Pampas grassland: Aristida spegazzinii, Panicum urvilleanum, Schizachyrium plumigerum, Margyricarpus pinnatus and Discaria americana (Table 1, Fig. 5a). The second component (16.56% total variance) separated smaller fragments belonging to the whole range of successional stages considered (grouped on the left) from the larger fragments before the fire and the controls over the entire period of time (concentrated on the right). The same component also separated fragments fifteen months after fire (on the left) from controls at the same sampling time (on the right), throughout the range of sizes analyzed (Fig. 5b). Samples on the left end of PC2 were associated with high coverage values of the exotic species Hypochaeris radicata and Pinus pinaster, while on the other extreme of the same axis two native species, Imperata brasiliensis and Cortaderia selloana, were responsible of the maximum loads (Table 1, Fig. 5b). The third component (9.43% total variance) separated the samples mainly as a function of their location in the successional trajectory in relation to fire (Fig. 5b). The plots surveyed before and three months after the fire formed a group on the positive side of the axis and were characterized by a greater abundance of two native species associated with disturbances: Ambrosia tenuifolia and Tessaria absinthioides, both showing positive correlations with the third component. At the other end of PC3, the plots sampled fifteen months after the fire formed a group associated with high coverage values of two native plants: Schizachyrium plumigerum and Schoenoplectus americanus (Table 1, Fig. 5b).
Discussion
Since the beginning of the 20th century, it has been suggested that habitat fragmentation may alter the capacity of biodiversity to recover from additional disturbances41. Different authors have argued that ecosystem fragmentation can modify successional trajectories, resulting in small fragments being affected to a greater extent than large fragments2,42. Our study represents a contribution to the study of the effects of fragmentation on the successional response of natural grasslands affected by fire. Evidence is provided on how the recovery of grasslands growing on sand dunes after a fire varies according to whether they are part of a continuous area or fragmented and immersed in a forest matrix, and, according to the size of the fragments, on the increase in the susceptibility of the fragmented areas to the invasion by exotic species, and on the reduction of their resilience after fires.
Our results show that the total vegetation cover and bare ground cover followed similar trajectories in grassland fragments and in continuous grassland controls after the fire, and with respect to their pre-fire characteristics. As expected, the vegetation gave way to bare ground following the fire, reversing this trend fifteen months later. However, while these changes were barely significant in the continuous grassland, they were much more noticeable in the fragments surrounded by the forest plantations, particularly in the smaller areas, which at least shows a delay in the recovery of the vegetation cover in response to fragmentation. The interaction between fire, fragmentation, and abundance of exotic plants is of particular interest. For several decades the relationship between invasion by exotic plants and disturbances has been highlighted43,44, in particular, with respect to the effects of changes in the nature, intensity, and frequency of the disturbances on the success of the invaders45,46. Similarly, it is recognized that the fragmentation of grasslands generates changes in the floristic composition of the community, favouring the entry of exotic species, which typically behave opportunistically11,47,48,49. The fire is a central natural component in the structuring of grassland vegetation communities17,18. However, changes in the composition of plant communities will respond to the fragmentation process and the alteration of the disturbance characteristics according to the matrix that surrounds the fragments. It is expected that this response affects the succession of vegetation in fragmented grasslands and eventually favouring the invasion by exotic species. Our results show that the cover of exotic plants is greater in fragmented grasslands surrounded by the forest matrix with respect to continuous grasslands, and the differences observed only in small areas before the fire, also extend to intermediate sizes fifteen months after the disturbance. In particular, our results document the encroachment of the pines into the remnant grassland fragments from the forest matrix in response to the fire. The pines typically release large quantities of seeds after a fire and the environmental conditions post fire favor their germination and establishment50,51. The fires in these types of grassland surrounded by pine plantations probably resulted in subsequent habitat losses and the intensification of the fragmentation process. This increase in the cover of exotic plants in fragmented habitats fifteen months after the disturbance contrasts with the constancy in their relative importance throughout the successional process for the plots surrounded by continuous grassland. The intact grasslands thus appear to be more resistant to invasion, as had been reported for similar habitats affected by fire in South Africa22, whereas the fragmentation of grasslands growing on sand dunes in the study area seems to increase their vulnerability to invasions. This increase in invasiveness could be due both to a reduction in fragment resistance associated with previous alterations in its species composition, and to a higher pressure of propagules related to its proximity to the forest matrix.
Changes in species composition along the successional trajectory also provide evidence on the effects of fragmentation. The samples of intact grassland showed a marked coincidence in the dominant species before the fire and fifteen months later, evidence of resilience that was much less obvious in the fragments surrounded by the forest plantation. Whereas before the fire event only the smallest fragments showed a species composition different from that of the continuous grassland controls of equivalent areas, these differences between habitats became widespread throughout the whole size range (small, intermediate, and large areas) one year after the fire.
The results obtained have at least two fundamental implications: they reinforce the evidence of the effect of fragmentation on grassland resilience, and they show how the effects of the fragmentation process, which can go unnoticed in certain successional stages, become evident after a disturbance. It is also important to note that the forest matrix could have affected the recovery capacity of grassland fragments not only in terms of the fragmentation process itself, but also due to the characteristics of a fire that affects a pine plantation. It is expected that the temperatures reached within the fragmented have exceeded those typical of grassland fires52, particularly affecting small fragments and thus confounding the particular effect of fragmentation.
Our study demonstrates the synergistic effects of the two main causes of biodiversity erosion in grassland remnants of high conservation value: habitat loss and fragmentation, and biological invasions53. It is also important to highlight the possible feedback between disturbance and habitat loss, as some of the invasive species recorded in this study, such as pines and acacias, have evolved in fire-adapted ecosystems. Changes in the dynamics of fires may favour their expansion, further tilting the balance in their advantage in this scenario of fragmentation and habitat loss15,54,55.
References
Haddad, N. M. et al. Habitat fragmentation and its lasting impact on Earth’s ecosystems. Science Advances, https://doi.org/10.1126/sciadv.1500052 (2015).
Wilson, M. C. et al. Habitat fragmentation and biodiversity conservation: key findings and future challenges. Landscape Ecology 31, 219–227 (2016).
Saunders, D. A., Hobbs, R. J. & Margules, C. R. Biological consequences of ecosystem fragmentation: A Review. Conservation Biology 5, 18–32 (1991).
Benitez, J. Impact of forest fragmentation on seedling abundance in a Tropical Rain Forest. Conservation Biology 12(2), 380–389 (1998).
Lord, J. M. & Norton, D. A. Scale and the Spatial Concept of Fragmentation. Conservation Biology 4(2), 197–202 (1990).
Hoekstra, J. M., Boucher, T. M., Ricketts, T. H. & Roberts, C. Confronting a biome crisis: global disparities of habitat loss and protection. Ecology Letters 8, 23–29 (2005).
Suttie, J. M., Reynolds, S. G. & Batello, C. Grasslands of the world. Food and Agriculture Organization of the United Nations (FAO), Rome, Italy, 514 pp (2005).
Thiollay, J. M. Forest Fragmentation and the Conservation of Raptors: A Survey on the Island of Java. Biological Conservation 44, 229–250 (1988).
Barnes, A. D., Emberson, R. M., Chapman, H. M., Krell, F. & Didham, R. K. Matrix habitat restoration alters dung beetle species responses across tropical forest edges. Biological Conservation 170, 28–37 (2014).
Jobbágy, E. G. et al. Forestación en pastizales: hacia una visión integral de sus oportunidades y costos ecológicos. Agrociencias 10(2), 109–124 (2006).
Yezzi, A., Nebbia, A. J. & Zalba, S. M. Fragmentación de pastizales psamófilos por plantaciones de pinos: efectos sobre la riqueza y la composición vegetal. Ecología Austral 28(1), 133–144 (2018).
Bilenca, D. & Miñarro, F. Identificación de Áreas Valiosas de Pastizal (AVPs) en las Pampas y Campos de Argentina, Uruguay y sur de Brasil. Fundación Vida Silvestre Argentina, Buenos Aires, 323 pp (2004).
Zalba, S. M. & Villamil, C. B. Woody plant invasion in relictual grasslands. Biological Invasions 4, 55–72 (2002).
Baldi, G., Guerschman, J. P. & Paruelo, J. M. Characterizing fragmentation in temperate South America grasslands. Agriculture, Ecosystems and Environment 116, 197–208 (2006).
Grace, J. B., Smith, M. D., Grace, S. L. & Stohlgren, T. J. Interactions between fire and invasive plants in temperate grasslands of North America. In: Proceedings of the Invasive Species Workshop: the Role of Fire in the control and Spread of Invasive Species [Galley, K. E. M. & Wilson, T. P. (eds)]. Tall Timbers Research Station, Tallahassee, 40–65 (2001).
Vega, E. & Peters, E. Conceptos generales sobre el disturbio y sus efectos en los ecosistemas. In: Conservación de ecosistemas templados de montaña en México [Sánchez, O., Vega, E., Peters, E. & Monroy-Vilchis, O. (eds.)]. Secretaria de Medio Ambiente y Recursos Naturales, Instituto Nacional de Ecología, Secretaria de Medio Ambiente, Recursos Naturales y Pesca, Comisión Nacional para el conocimiento y Uso de la Biodiversidad México, 137–150 (2003).
Wu, G. L., Zhao, L. P., Wang, D. & Shi, Z. H. Effects of time-since-fire on vegetation composition and structures in semi-arid perennial grassland on the Loess Plateau, China. Clean-Soil Air Water 42(1), 98–103 (2014).
Van Langevelde, F., de Groot, C., Groen, T. A., Heitkönig, I. M. A. & Gaigher, I. Effect of patches of woody vegetation on the roleof fire in tropical grasslands and savannas. International Journal of Wildland Fire 23, 410–416 (2014).
Cochrane, M. A. & Laurance, W. F. Synergisms among fire, land use, and climate change in the Amazon. AMBIO: A. Journal of the Human Environment 37(7), 522–527 (2008).
Giorgis, M. A., Cingolani, A. M. & Cabido, M. El efecto del fuego y las características topográficas sobre la vegetación y las propiedades del suelo en la zona de transición entre bosques y pastizales de las sierras de Córdoba, Argentina. Boletín de la Sociedad Argentina de Botánica 48(3–4), 493–513 (2013).
Deák, B. et al. Grassland fires in Hungary Experiences of nature conservationists on the effects of fire on biodiversity. Applied ecology and environmental research 12(1), 267–283 (2014).
Bachinger, L. M., Brown, L. R. & van Rooyen, M. W. The effects of fire-breaks on plant diversity and species composition in the grasslands of the Loskop Dam Nature Reserve, South Africa. African Journal of Range & Forage Science 2016, 1–12 (2016).
Guadagnin, D. L. et al. Árvores e arbustos exóticos invasores no Bioma Pampa - questões ecológicas, culturais e socioeconômicas de um desafio crescente. In: Campos Sulinos: conservação e uso sustentable da biodiversidade [De Patta Pillar, V., Müller, S. C., de Souza, Z. M. & Ávila Jacques, A. V. (eds)]. Ministerio do Meio Ambiente, Brasilia, 300–316 (2009).
Marcomini, S., López, R., Picca, P., Madanes, N. & Bertolín, L. Cambios en la vegetación en costas de dunas y su influencia en el balance sedimentario. In: Problemática de los ambientes costeros: Sur de Brasil, Uruguay y Argentina [López, R. A. & Marcomini, S. C. (eds)]. Primera edición, Editorial Croquis S.R.L., Buenos Aires, 193–205 (2011).
Picasso, G. & Rodríguez, E. Bañados del Este. In: Especies exóticas invasoras en las Reservas de Biosfera de América Latina y el Caribe [Schüttler, E. & Karez, C. S. (eds)]. UNESCO, Montevideo, 289–294 (2008).
Brugnoli, E., Masciadri, S. & Muniz, P. Base de datos de especies exóticas e invasoras en Uruguay, un instrumento para la gestión ambiental y costera. Ecoplata, Montevideo, Uruguay, 23 pp (2009).
Cuevas, Y. A. & Zalba, S. M. Control de pinos invasores en el parque provincial Ernesto Tornquist (Buenos Aires): áreas prioritarias y análisis de costos. BioScriba 2(2), 76–89 (2009).
Bowers, M. A. & Dooley, J. L. A controlled, hierarchical study of habitat fragmentation: responses at the individual, patch, and landscape scale. Landscape Ecology 14, 381–389 (1999).
Cabrera, A. L. Fitogeografía de la República Argentina. Boletín de la Sociedad Argentina de Botánica 14(1–2), 1–42 (1971).
Campo de Ferreras, A., Capelli de Steffens, A. & Diez, P. El clima del Suroeste Bonaerense. Departamento de Geografía y Turismo, Universidad Nacional del Sur, Bahía Blanca, 105 pp (2004).
Zalba, S. M. Y. & Nebbia, A. J. Neosparton darwinii (Verbenaceae) a restricted endemic species. Is it also endangered? Biodiversity and Conservation 8, 1585–1593 (1999).
Celsi, C. E. & Monserrat, A. L. La vegetación dunícola en el frente costero de la Pampa Austral (Partido de Coronel Dorrego, Buenos Aires). Multequina 17, 73–92 (2008).
Kittlein, M. J. et al. Dunas del sureste bonaerense. In: Identificación de Áreas Valiosas de Pastizal (AVPs) en las Pampas y Campos de Argentina, Uruguay y sur de Brasil [Bilenca, D. & Miñarro, F. (eds)]. Fundación Vida Silvestre, Argentina, 76–77 (2004).
Monserrat, A. L. & Celsi, C. E. Análisis regional de la costa pampeana austral en el marco del sistema de áreas protegidas y caracterización de un área clave como reserva, en el partido de Coronel Dorrego. Bioscriba 2(1), 1–23 (2009).
Isacch, J. P. & Maceira, N. O. Parque Atlántico Mar Chiquito. In: Especies exóticas invasoras en las Reservas de Biosfera de América Latina y el Caribe. Un informe técnico para fomentar el intercambio de experiencias entre las Reservas de Biosfera y promover el manejo efectivo de las invasiones biológicas [Schüttler, E. & Karez, C. S. (eds)]. UNESCO, Montevideo, 52–55 (2008).
Mueller-Dombois, D. & Ellenberg, E. Aims and Methods of Vegetation Ecology. John Wiley & Sons. New York, Chichester, Brisbane, Toronto, 547 pp (1974).
Cabrera, A. L. Flora de la Provincia de Buenos Aires. Colección Científica del INTA, Buenos Aires, 6 vols (1963–1970).
Zuloaga, F. O., Morrone, O. & Belgrano, M. Catálogo de las Plantas Vasculares del Cono Sur. Monographs in Systematic Botany 107, MO Botanical Garden Press, St. Louis, Missouri, USA, 3384 pp (2008).
Conover, W. J. Practical Nonparametric Statistics. John Wiley & Sons, Inc., New York. (1999).
Legendre, P. & Gallagher, E. D. Ecologically meaningful transformations for ordination of species data. Oecologia 129, 271–280 (2001).
Clements, F. E. Nature and structure of the climax. Journal of Ecology 24, 252–284 (1936).
Cook, W. M., Yao, J., Foster, B. L., Holt, R. D. & Patrick, L. B. Secondary succession in an experimentally fragmented landscape: community patterns across space and time. Ecology 86(5), 1267–1279 (2005).
Fox, B. J. & Fox, M. D. The susceptibility of natural communities to invasion. In: Ecology of biological invasions: an Australian Perspective [Groves, R. H. & Burdon, J. J. (eds.)]. Australian Academy of Science, Canberra, 57–66 (1986).
Lozon, J. D. & MacIsaac, H. J. Biological invasions: are they dependent on disturbance? Environmental Reviews 5, 131–144 (1997).
Didham, R. K., Tylianakis, J. M., Hutchison, M. A., Ewers, R. M. & Gemmell, N. J. Are invasive species the drivers of ecological change? Trends in Ecology and Evolution 20(9), 471–474 (2005).
Keeley, J. E. Fire and invasive species in Mediterranean-climate ecosystems of California. In: Proceedings of the Invasive Species Workshop: the Role of Fire in the Control and Spread of Invasive Species [Galley, K. E. M. & Wilson, T. P. (eds)]. Tall Timbers Research Station, Tallahassee, 81–94 (2001).
Gross, K. L., Mittelbach, G. G. & Reynolds, H. L. Grassland invasibility and diversity: responses to nutrients, seed input, and disturbance. Ecology 86(2), 476–486 (2005).
MacDougall, A. S. & Turkington, R. Are invasive species the drivers or passengers of change in degraded ecosystems? Ecology 86(1), 42–55 (2005).
Dechoum, M., Rejmánek, M., Castellani, T. T. & Zalba, S. M. Limited seed dispersal may explain differences in forest colonization by the Japanese raisin tree (Hovenia dulcis Thunb.), an invasive alien tree in Southern Brazil. Tropical Conservation. Science 8(3), 610–622 (2015).
Rejmánek, M. & Richardson, D. M. What attributes make some plant species more invasive? Ecology 77, 1655–1661 (1996).
Tapias, R., Gil, L., Fuentes-Utrilla, P. & Pardos, J. A. Canopy seed banks in Mediterranean pines of south-eastern Spain: a comparison between Pinus halepensis Mill., P. pinaster Ait., P. nigra Arn. and P. pinea L. Journal of Ecology 89, 629–638 (2001).
De las Heras, J., Martínez, J. J. & Herranz, J. M. Impacto ecológico de los incendios forestales. Revista de Estudios Albacetenses 29, 105–117 (1991).
Yates, E. D., Levia, D. F. & Williams, C. L. Recruitment of three non-native invasive plants into a fragmented forest in southern Illinois. Forest Ecology and Management 190, 119–130 (2004).
Pieterse, P. J. & Cairns, A. L. The population dynamics of the weed Acacia longifolia (Fabaceae) in the absence and presence of fire. South African Forestry Journal 145, 25–27 (1988).
Zalba, S. M., Cuevas, Y. A. & Boó, R. Aleppo pine invasión after a wildfire in an Argentinean grassland nature reserve. Journal of environmental Managemente 88, 539–546 (2008).
Acknowledgements
We thank the farm owners who allowed access to their property for this study, to Mariano Kittler for his help during field work, Dr. Pamela Geddes for the detailed review of English language, and to CONICET (Consejo Nacional de Investigaciones Científicas y Técnicas) and the Department of Biology, Biochemistry and Pharmacy of the Universidad Nacional del Sur.
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A.L.Y. carried out the sampling; A.L.Y. and S.M.Z. carried out statistical analyses; A.L.Y. and A.J.N. carried out the taxonomic identification of the plants; all authors analyzed the results and contributed to the paper writing, editing and revision.
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Yezzi, A.L., Nebbia, A.J. & Zalba, S.M. Interaction between fire and fragmentation in the successional stages of coastal dune grasslands of the southern Pampas, Argentina. Sci Rep 9, 15109 (2019). https://doi.org/10.1038/s41598-019-51595-x
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DOI: https://doi.org/10.1038/s41598-019-51595-x
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