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The risks of introduction of the Amazonian palm Euterpe oleracea in the Atlantic rainforest/Os riscos da introducao da palmeira amazonica Euterpe oleracea na Floresta Atlantica.

1. Introduction

Palms play an important role in natural communities as many palm species are important resources for animals (Tomlinson, 2006; Henderson et al., 1995). Fruits, palm heart, leaves and stems are also commonly exploited by human populations (Henderson et al., 1995). Because of their economic importance palms are one of the groups most dispersed by humans (Tomlinson, 2006). In fact, the introduction of many palm species is stimulated by their beauty and effortless cultivation - mostly in tropical regions. This may create chalenges to manage these the exotic species and to conservate native communities (Van Wilgen and Richardson, 2014). Still, few studies have assessed the ecological aspects of exotic palms and their effects on the local plant populations (Meyer et al., 2008; Christianini, 2006; Dislich et al., 2002).

Although palm species are rarely considered invasive, the general impact of exotic species on biodiversity and ecosystems has long been recognized (Richardson and Rejmanek, 2011; Simberloff, 2005; Elton, 2000). Exotic plants species may cause many impacts on the ecological patterns of the local community and when congeneric with local species, they may promote competition for pollinators or lead to interspecific interference with pollen in native flowers (Albrecht et al., 2012; Lopezaraiza-Mikel et al., 2007; Traveset and Richardson, 2006). This interference may result in hybridization, which has been considered a serious threat for conservation (Wolf et al., 2001).

Hybridization may lead to species extinction in two ways: when the hybrids exhibit lower fitness than parental taxa, the less abundant parental species may decline; alternatively, if the hybrids are fertile and have low fitness reduction, they may displace conspecifics of one or both parental taxa (Wolf et al., 2001). Also, exotic species may disrupt the relationship between seed dispersers and native plants (Spotswood et al., 2012). This could decrease the effective seed dispersal, leading to a reduction on the quality and quantity of native seeds, negatively affecting their germination or seedling establishment (Aslan and Rejmanek, 2010). Thus, a disturbance in reproductive mutualisms may affects the growth rate (Aslan and Rejmanek, 2010) and therefore modify the structure and spatial distribution of plant populations. Nevertheless, many exotic species may create conficts of interest when they are both useful to humans and able to cause harm (Dickie et al., 2013; Simberloff et al., 2013).

In the Atlantic rainforest, an endangered palm species is confronting a new threat. After decades of indiscriminate exploitation for palm heart production, Euterpe edulis Mart. (Arecaceae)--a native species from the Atlantic Forest--has been legally protected (Silva Matos and Bovi, 2002; Galetti and Fernandez, 1998). However, the over-exploitation of E. edulis, has contributed significantly to changes in its populations structure leading this species to extinction in several forest fragments (Melito et al., 2014; Silva Matos and Bovi, 2002). To guarantee the continuous production of palm heart, several species have been introduced in this ecosystem. Nowadays, nearly 50% of palm heart production is given by exotic introduced palms in the Atlantic Forest area (Sao Paulo, 2008a). One of the commonest introduced species is Euterpe oleracea Mart. (Arecaceae), which is native from Amazon rainforest where it grows in similar conditions as E. edulis (Bovi et al., 1987). This species was once considered the solution for the vulnerability of E. edulis to harvesting. These congeneric palms are able to produce E. edulis x E. oleracea hybrids under experimental management (Tiberio et al., 2012; Campos et al., 1991; Bovi et al., 1987) and these hybrids are also used in palm heart crops. However, neither the ecology of E. oleracea in this new area nor E. edulis responses in sites where the exotic palm was introduced are known. Yet, E. oleracea introduction in Atlantic rainforest has increased in the last few years not only because of the exploitation of palm hearts, but also for the production of "assai" pulp from its fruits.

Due to their great biological similarity, we expect that these Euterpe species have also the same ecological requirements and, therefore, E. oleracea might successfully establish in Atlantic rainforest. These similarities also lead us to expect the interaction with local fauna. The main objective of this study was to understand the ecological aspects of E. oleracea introduction in Atlantic rainforest and the possible consequences for the native E. edulis. To clarify these aspects, we separetely accessed the following questions: 1. To investigate whether the introduced palm E. oleracea is able to establish populations and spread in the Atlantic rainforest, we evaluated the introduced population structure by analysing the frequencies of ontogenetic stages and its spatial distribution; 2. To verify if E. oleracea is able to interact with local bird community, we observed the visits of frugivorous birds to both E. oleracea and E. edulis; 3. To understand the possible effects of E. oleracea introduction on E. edulis population structure we compared the frequencies of ontogenetic stages and the spatial distribution of this palm populations in sites with and without E. oleracea; 4. To investigate if E. oleracea and E. edulis may generate spontaneous hybrids (i.e. generated in the wild and not produced by men), we separetely identified and quantified these individuals.

2. Methods

2.1. Species description

Euterpe edulis occurs in the Atlantic rainforest from Southern Brazilian coast up to Paraguay and Argentina (Henderson et al., 1995). It has a single stem reaching 20 m height and produces globular purple-black fruits 1-1.4 cm diameter (Henderson et al., 1995) which are food resource for many animal species, typically birds (Galetti et al., 2013; Pizo and Vieira, 2004; Galetti and Aleixo, 1998). This species produces the most economically valuable palm heart but, as it produces a single stem and does not resprout, individuals are killed for the palm heart extraction. In the southeast region, the presence ofE. edulis is comonly restricted to the remaining areas of Atlantic rainforest and particularly in some protected areas of Rio de Janeiro, Sao Paulo and Parana states, in southeast of Brazil (Silva Matos and Bovi, 2002).

Euterpe oleracea ("assai palm") is commonly found along the Amazon River basin in Northern Brazil. E. oleracea has multiple stems, reaching 12-20 meters high (Henderson et al., 1995). It bears purple-black globular fruits 1-2 cm diameter which are dispersed by several bird species (Moegenburg and Levey, 2003; Henderson et al., 1995). The palm heart from E. oleracea does not have the same economical value as the ones from E. edulis but, as a multiple stemmed plant, palm heart production may be higher and the plants are not necessarily killed during exploitation. Also, its fruits are used for "assai" cream production.

Although these palm species show naturally distinct distributions (Henderson et al., 1995), both Atlantic and Amazon rainforests present similar characteristics mostly defined by their wet and high temperature climates (above 25[degrees]C), with even rainfall distribution along the year.

2.2. Study sites

In order to compare areas differentiated only by the presence ofE. oleracea, we selected two areas 75 Km apart, but having the same vegetation type and environmental conditions. Thus, we conducted the research at two protected areas of Atlantic rainforest: Carlos Botelho State Park (24[degrees] 06' 55" W, 24[degrees] 14' 41" S and 47[degrees] 47' 18", 48[degrees] 07' 17" W) and Ilha do Cardoso State Park (48[degrees] 05' 42" W, 25[degrees] 03' 05" S and 48[degrees] 53' 48" W, 25[degrees] 18' 18" S). These parks belong to a continuous area of Atlantic rainforest in Southeast Brazil. E. oleracea was introduced at Carlos Botelho State Park in the 1970s. This population was once cut as an attempt to remove the species from the park, but most of individuals resprouted. Hereafter, we refer to Carlos Botelho State Park as site of introduction and to Ilha do Cardoso State Park as control site.

This region has tropical rainforest climate with annual rainfall ranging between 1700 and 2400 mm and average temperature between 19[degrees]C and 27[degrees]C (Sao Paulo, 2008b; Melo and Mantovani, 1994). Both study sites are located in floodplain areas and exhibit alluvial rainforest vegetation with the same plant species composition (Sao Paulo 2008b; Melo and Mantovani, 1994).

2.3. Data sampling and analysis

From July 2009 to March 2010 we sampled all individuals (except seedlings) ofE. edulis and E. oleracea within 35 contiguous plots (10 x10m) in a grid, in both introduction and control sites. The contiguous plot design was selected to keep focus on the area where E. oleracea population were first introduced, also including the immediate surrounding area. We sampled seedlings in randomly located sub-plots (2 x2m) within each 100 m2 plot. We identified the hybrids based on leaves shape and leaflets spacing (Tiberio et al., 2012). No individuals of E. oleracea were to be found at control site.

Individuals from each population were then divided into five ontogenetic life stages according to their morphology: seedling, juvenile I, juvenile II, immature, reproductive adult (Tiberio et al., 2012). Besides height and diameter, we also observed leaf and leaflet shape and signs of reproduction such as presence of inflorescences, infrutescences or its scars on the stems (previous reproduction). We evaluated differences between population structures comparing the distribution of relative stage frequencies, using chi-squared test in the program Past version 2.01 (Hammer et al., 2001). Although the multiple stems of E. oleracea are biologically recognized as only one individual, we considered each stem as a distinctive unit, in order to also account for resprouting.

Frugivory was recorded at the site of introduction, from March to September 2007-2009, when fruits of both species were ripe. We detected the abundance of birds visiting E. edulis and E. oleracea, by viewing or by vocalizations, walking along transects within areas where these species were present. The work was done from 30 min before sunrise until 30 min after dusk, at least two days per month. Amongst all birds, we observed and identified those feeding on fruits of both Euterpe species using 8x40 binoculars. The resulting sampling effort was of 214 hours. In order to assess each palm species effects on birds attraction, we evaluated the correlation of total number of visits with the number of observed consumers for each species using the Spearman coefficient (rs).

3. Results

At the control site, we recorded 2374 individuals of E. edulis (6782.8 ind. [ha.sup.-1]), while at the site of introduction we found 400 individuals ofE. edulis (1142.8 ind. [ha.sup.-1]), 68 of E. oleracea (194.3 ind. ha-1) and 72 hybrids (205.7 ind. [ha.sup.-1]). Likewise overall density, E. edulis ontogenetic structure was significantly different between control site and site of introduction ([chi square] = 248.55; p=0.00001, Figure 1). Total density and frequency of seedlings of E. edulis were higher in the control site. The ontogenetic structure of E. edulis and E. oleracea at the site of introduction also differed significantly ([chi square] = 36.62; p=7.11x 10-7). We did not find seedlings within E. oleracea population, however juveniles were the most frequent stage (Figure 1) and were mostly originated as sprouts (82%). We did not find any hybrids seedlings and reproductive adults, but intermediary stages were still present (Figure 1). Some individuals of E. oleracea and hybrids were located outside the original planting area.

We observed an overlap between fructification periods of native and introduced species: E. edulis produced ripe fruits from March to September and E. oleracea from June to September. In this period, we observed 19 bird species consuming fruits: 16 species consumed E. edulis and 12 consumed E. oleracea (Table 1). The native and exotic Euterpe species shared nine of the frugivorous bird species located at the site of introduction, while seven species were detected exclusively on E. edulis and three visited only E. oleracea (Table 1). The observations of fruit consumption for E. edulis was not correlated with the total bird species recorded (rs=0.36, p=0.12), while for E. oleracea we obtained a significant positive correlation between fruit consumption and bird visits (rs=0.62, p=0.004).

4. Discussion

Our results provided evidences that the Amazonian palm tree E. oleracea, introduced in the Atlantic Forest, is able to establish through sexual reproduction and vegetative growth, to produce non-mediated hybrids with the native palm species and to interact with local bird community, including dispersers of E. edulis.

We observed that even though the original plantation of E. oleracea have already been cut down, most of the clumps have resprouted. In our case, E. oleracea resprouting ability may increase its resilience to disturbances when compared to the native palm species, since E. edulis is unable to resprout after being cut. We can conclude that E. oleracea is also able to establish populations and to resprout in the novel area even after its clumps have been completely cut. Nevertheless, variation between sexual reproduction or vegetative growth, may indicate that the absence of seedlings of this species do not automatically represent population instability in the new environment (Halle et al., 1978).

In contrast, what we observed for E. edulis may suggest instability of the population that co-ocuurs with the exotic palm. The density of E. edulis population at the site of introduction was significantly lower than expected for this species along the Atlantic Forest (Fantini and Guries, 2007; Conte et al., 2003; Reis et al., 2000). This difference was mostly caused by the lower seedling density in the site where E. oleracea was introduced. At the same region of our site of introduction, E. edulis populations usually have higher densities and negative exponential distribution of stages (Silva Matos and Bovi, 2002). E. edulis also shows high fruit production patterns (von Allmen et al., 2004; Silva Matos and Watkinson, 1998) and germination rates (Leite et al., 2012; Tiberio et al., 2012), and also keeps seedling banks instead of seed banks. So it is always expected to find high abundance of seedlings, specially after fruit production period. The same pattern of high frequency of seedlings has been also detected in other regions of the Atlantic Forest (Silva et al., 2009; Fantini and Guries, 2007; Conte et al., 2003; Silva Matos and Bovi 2002; Reis et al., 2000; Silva Matos and Watkinson, 1998). Therefore, the significant reduction of seedlings observed at the site of introduction, when compared to the control site and to many examples in the literature, can be considered a concern for the population stability.

The presence of spontaneous hybrids at the site of introduction indicates that the exchange of pollen between E. oleracea and E. edulis may occur when flowering periods of these palms overlap. Considering that these species can spontaneously produce viable hybrid seeds (Tiberio et al., 2012) and that hybrids may reach the reproductive stage (Bovi et al., 1987), the introduction ofE. oleracea increases the vulnerability of the native species. The cross pollination between congener species may decrease the number of viable seeds of the native species consequently dropping the number of seedlings (Traveset and Richardson, 2006) and, finally, the total population density. As indicated by our results, this scenario can be observed for E. edulis population at the site of introduction. Moreover, these hybrids are expected to backcross to parental populations (Campos et al., 1991) resulting in a high gene pool mixtures between both palm species. This process may threaten mostly small populations, as it is the current status of E. edulis in many forest fragments, which could result in a "silent invasion" as already observed for other organisms (Miglietta and Lessios, 2009).

Individuals of E. oleracea were also found outside the original planting area, which demonstrates its capability of being efficiently dispersed. Both E. oleracea and E. edulis are zoochoric species and produce fruits very similar in size, weight and colour (Tiberio et al., 2012; Henderson et al., 1995). Thus, as expected, we observed that most frugivorous birds feed on the fruits of both species. Only two species, Pyrrhura frontalis and Brotogeris tirica, may not act as seed dispersers as they can also consume the endocarp of seeds (Galetti et al., 2013; Pizo et al., 2006). Still, five of the species observed in our study have wide distribution that include the region of natural occurrence of E. oleracea in the Amazon rainforest (Sick, 1997). Patagioenas plumbea, Trogon viridis, Ramphastos vitellinus, Myiozetetes similis and Turdus albicollis occur in the Atlantic rainforest as well as in the Amazon rainforest. Therefore, these bird species are also able to disperse seeds of E. oleracea in the Atlantic Forest. At family level, the community assemblage of visitors of each Euterpe palm in their native habitats is also similar. For example, in the Indigenous Land Waiapi do Amapari, at Amapa state in north of Brazil, fruits of E. oleracea are eaten by: Cracidae (Penelope marail), Psittacidae (Ara macao and Deroptyus accipitrinus), Ramphastidae (Ramphastos tucanus) and Cotingidae (Querula purpurata) (A. Antunes, personal observation).

Seed dispersal of fleshy-fruited exotic species is known to play an important role in the invasion process (Gosper et al., 2005). The impoverishment or even the displacement of dispersers of E. edulis could directly influence the density and distribution of the this palm tree (Fadini et al., 2009). We observed that, as its native congener E. edulis,E. oleracea also attracts a broad range of frugivorous birds and also that few species that used to feed on the native were found exclusively feeding on the exotic palm. The large number of interactions with local bird species including species with great moving capacity as Ramphastos spp. and Turdus spp. may certainly contribute to the spread of this exotic palm in the Atlantic rainforest.

In this study we observed that the Amazonian palm E. oleracea is able to establish populations and spread in the Atlantic rainforest and also to spontaneously hybridize with the native E. edulis. As E. oleracea showed a significant interaction with local frugivorous birds, it is necessary to evaluate how its presence may interfere in the dispersion of the native E. edulis. The small number of seedlings of E. edulis found at the site of introduction may also have resulted from a negative impact caused by the interaction between E. oleracea and local fauna. As a long-term effect, we could expect the same impacts in other areas as E. oleracea fruits are being dispersed by several frugivorous birds.

Many palm heart and fruit producers along the Atlantic forest have been adopting E. oleracea and even E. oleracea x E. edulis hybrids sold in the seedlings market. As exemplified by our study, E. oleracea might be able to interact with birds, spread and succesfully establish in wild areas. Nevertheless, the final consequences of its introduction still needs to be addressed by reasearchers and environmental policy. As E. oleracea, several palm species can easily establish into new areas allowing it to spread and becoming invasive. Our study reveals that besides the dangers of habitat destruction and illegal exploitation (Silva Matos and Bovi, 2002), the indiscriminate introduction of exotic palms represents another risk to the maintenance of the native palm E. edulis in Atlantic rainforest.

http://dx.doi.org/10.1590/1519-6984.12114

Acknowledgements

We thank the funding agencies "Fundacao de Amparo a Pesquisa do Estado de Sao Paulo" (FAPESP) and "Coordenacao de Aperfeicoamento de Pessoal de Nivel Superior" (CAPES) for the scholarships provided for the first and second authors, respectively. We also thank two anonymous reviewers for comments on the manuscript.

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F. C. S. Tiberio (a) *, T A. Sampaio-e-Silva (a), D. M. S. Matos (a) and A. Z. Antunes (b)

(a) Departamento de Hidrobiologia, Universidade Federal de Sao Carlos-UFSCar, Rodovia Washington Luis, Km 235, SP 310, CEP 13565-905, Sao Carlos, SP, Brazil

(b) Divisao de Dasonomia, Instituto Florestal do Estado de Sao Paulo, Rua do Horto, 931, Horto Florestal, CEP 02377-000, Sao Paulo, SP, Brazil

* e-mail: nandatiberio@gmail.com

Received: July 7, 2014-Accepted: November 27, 2014-Distributed: February 29, 2015 (With 1 figure)
Table 1. Birds recorded feeding on fruits of E. edulis and E.
oleracea and total number of visits obtained at the site of
introduction--Carlos Botelho State Park, SP, Brazil.

Species                                 Total       E.        E.
                                       visits     edulis   oleracea
                                     ([section])

Cracidae
  Penelope obscura (Temminck 1815)       13         3         1
  Aburria jacutinga (Spix 1825)           9         3

Columbidae
  Patagioenas plumbea (Vieillot          14         2
    1818)

Psittacidae
  Pyrrhura frontalis (Vieillot           389        68        26
    1817)
  Brotogeris tirica (Gmelin 1788)        313        10        4

Trogonidae
  Trogon viridis (Linnaeus 1766)         94         3         1

Momotidae
  Baryphthengus ruficapillus             62         1
    (Vieillot 1818)

Ramphastidae
  Ramphastos vitellinus                  61         12        3
    (Lichtenstein 1823)
  Ramphastos dicolorus (Linnaeus         42         23        7
    1766)
  Selenidera maculirostris               28         4
    (Lichtenstein 1823)
  Pteroglossus bailloni (Vieillot         6         2
    1819)

Tyrannidae
  Myiozetetes similis (Spix 1825)        21                   1

Cotingidae
  Procnias nudicollis (Vieillot          40         1
    1817)
  Pyroderus scutatus (Shaw 1792)          5         2

Turdidae
  Turdusflavipes (Vieillot 1818)         56         19        13
  Turdus rufiventris (Vieillo,           10                   2
    1818)
  Turdus amaurochalinus (Cabani,          3         1         1
    1850)
  Turdus albicollis (Vieillot            183        7         4
    1818)
  Thraupidae
  Tangara seledon (Statius               638                  12
    Muller 1776)

([section]) Total of visits are related to all individuals observed
along transects. These individuals were not necessarily
consuming fruits of E. edulis or E. oleracea every time they
were registered.

Figure 1. Ontogenetic structure of E. oleracea and hybrids at the site
of introduction and of E. edulis at the introduction and control sites.
Grey: populations at site of introduction; black: populations at
control site. Ontogenetic stages: 1-seedling, 2-juvenile I, 3-juvenile
II, 4-immature, 5-reproductive adult.

E. oleracea

1   0
2   35
3   25
4   7
5   1

Hybrids

1   0
2   35
3   32
4   5
5   0

E. edulis

1   100
2   239
3   49
4   34
5   2

E. edulis

1   1425
2   763
3   120
4   58
5   8

Note: Table made from bar graph.
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Title Annotation:Original Article
Author:Tiberio, F.C.S.; Sampaio-e-Silva, T.A.; Matos, D.M.S.; Antunes, A.Z.
Publication:Brazilian Journal of Biology
Date:Feb 1, 2016
Words:5363
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