Abstract

Many species of Bromeliaceae store water among their leaves creating microhabitats for several biological groups. Using bromeliads in enrichment of reforestation offers an opportunity to understand the occupation of tank habitat, and the impacts of these plants in increasing biodiversity. We translocated 20 rescued individuals of tank-bromeliad Hohenbergia ramageana to enrich a reforested area in Atlantic Forest. Then, we recorded the visiting dynamics of animals in the tank habitat of H. ramageana. Ten orders of vertebrates and invertebrates visited nine terrestrial and eight epiphyte tank-habitats just one month after the translocation. Richness and composition were similar between epiphyte and terrestrial translocations. We found that precipitation explained a significant proportion of variation of the number of visited plants and richness of animal orders. Our results confirm the importance of using tank-bromeliads in reforested ecosystems and bring novelty that reintroduced bromeliads in alternative habitats also play the same role for animal groups as in their original habitat. This knowledge will orientate future plans of conservation of bromeliads and of ecosystem restoration.

Key words:
bromeliads; conservation; enrichment; translocation

Resumo

Muitas espécies de Bromeliaceae armazenam água entre suas folhas criando microhabitats para diversos grupos biológicos. O uso de bromélias no enriquecimento de reflorestamentos oferece uma oportunidade para entender a ocupação do habitat tanque e os impactos dessas plantas no aumento da biodiversidade. Foram translocados 20 indivíduos resgatados da bromélia-tanque Hohenbergia ramageana para enriquecimento de uma área reflorestada de Mata Atlântica. Em seguida, foi gravada a dinâmica de visitação de animais no habitat tanque de H. ramageana. Dez ordens de vertebrados e invertebrados visitaram nove habitats tanques terrícolas e oito epífitos apenas um mês após a translocação. A riqueza e a composição foram semelhantes entre as translocações epífitas e terrícolas. Descobrimos que a precipitação explicou uma proporção significativa de variação do número de plantas visitadas e da riqueza de ordens de animais. Nossos resultados confirmam a importância do uso de bromélias-tanque em ecossistemas reflorestados e trazem novas evidências de que as bromélias reintroduzidas em habitats alternativos também desempenham o mesmo papel para grupos de animais que em seu habitat original. Esse conhecimento orientará planos futuros de conservação de bromélias e de restauração de ecossistemas.

Palavras-chave:
bromélias; conservação; enriquecimento; translocação

Habitat loss is one of the main threats to biodiversity (Pimm et al. 1995Pimm SL, Russell GJ, Gittleman JL & Brooks TM (1995) The future of biodiversity. Science 269: 347-350. DOI: 10.1126/science.269.5222.347
https://doi.org/10.1126/science.269.5222... ). Five centuries of deforestation have reduced the Atlantic Forest to archipelagos of small remnants that represent 11.4 to 16% of its original cover (Ribeiro et al. 2009Ribeiro MC, Metzger JP, Martensen AC, Ponzoni FJ & Hirota MM (2009) The Brazilian Atlantic Forest: how much is left, and how is the remaining forest distributed? Implications for conservation. Biological Conservation 142: 1141-1153. DOI: 10.1016/j.biocon.2009.02.021
https://doi.org/10.1016/j.biocon.2009.02... ; Rezende et al. 2018Rezende CL, Scarano FR, Assad ED, Joly CA, Metzger JP, Strassburg BBN & Mittermeier RA (2018) From hotspot to hopespot: an opportunity for the Brazilian Atlantic Forest. Perspectives in Ecology and Conservation 16: 208-214. DOI: 10.1016/j.pecon.2018.10.002
https://doi.org/10.1016/j.pecon.2018.10.... ). This process has caused loss of habitat quality and availability for a large number of endemic species (Myers et al. 2000Myers N, Mittermeier AR, Mittermeier CG, Fonseca GAB & Kent J (2000) Biodiversity hotspots for conservation priorities. Nature 403: 853-858. DOI: 10.1038/35002501
https://doi.org/10.1038/35002501... ; Lindenmayer & Fischer 2006Lindenmayer DB & Fischer J (2006) Habitat fragmentation and landscape change: an ecological and conservation synthesis. Island Press, Washington. 352p.). For example, the reduction of richness and diversity of large trees affects species that depend on the habitat provided by them, such as epiphytes of the Bromeliaceae family (Oliveira et al. 2008Oliveira MA, Santos AMM & Tabarelli M (2008) Profound impoverishment of the large-tree stand in hyper fragmented landscape of the forest. Forest Ecology and Management 256: 1910-1917. DOI: 10.1016/j.foreco.2008.07.014
https://doi.org/10.1016/j.foreco.2008.07... ; Siqueira-Filho & Tabarelli 2006Siqueira-Filho JA & Tabarelli M (2006) Bromeliad species of the Atlantic forest of north-east Brazil: losses of critical populations of endemic species. Oryx 40: 218-224. DOI: 10.1017/S0030605306000627
https://doi.org/10.1017/S003060530600062... ).

Many of the 3,500 species of Bromeliaceae store water in their rosettes creating habitat conditions for several biological groups (Benzing 2000Benzing DH (2000) Bromeliaceae: profile of an adaptative radiation. Cambridge University Press, Cambridge. 690p.; Fernandez-Barrancos et al. 2016; Zizka et al. 2019Zizka A, Azevedo J, Leme E, Neves B, Costa AF, Caceres D & Zizka G (2019) Biogeography and conservation status of the pineapple family (Bromeliaceae). Diversity and Distributions 26: 183-195. DOI: 10.1111/ddi.13004
https://doi.org/10.1111/ddi.13004... ). Studies confirm that bromeliads are indispensable for restoring ecosystems, because tank-habitats of bromeliads increase richness and density of many animal groups when introduced in restored areas (Benzing 2000; Duarte & Gandolfi 2013Duarte MM & Gandolfi S (2013) Enriquecimento de florestas em processo de restauração: aspectos de epífitas e forófitos que podem ser considerados. Hoehnea 40: 507-514. DOI: 10.1590/S2236-89062013000300010
https://doi.org/10.1590/S2236-8906201300... ; Fernandez-Barrancos et al. 2016; Melo et al. 2016Melo TDS, Benati KR, Peres MC, Tinôco MS, Andrade AR & Alves MD (2016) Bromeliad translocation in Atlantic Forest fragments, Brazil. Conservation Evidence 13: 88-92. ; Rocha et al. 2004Rocha CFD, Cogliatti-Carvalho L, Nunes-Freitas AF, Rocha-Pessôa TC, Dias AS, Ariani CV & Morgado LN (2004) Conservando uma larga porção da diversidade biológica através da conservação de Bromeliaceae. Vidália 2: 52-72.). Thus, tank-bromeliad species play an indispensable role in ecosystems where they occur (Cogliatti-Carvalho et al. 2010Cogliatti-Carvalho L, Rocha-Pessôa TC, Nunes-Freitas AF & Rocha CFD (2010) Volume de água armazenado no tanque de bromélias, em restingas da costa brasileira. Acta Botanica Brasilica 24: 84-95. DOI: 10.1590/S0102-33062010000100009
https://doi.org/10.1590/S0102-3306201000... ).

Translocation of bromeliad plants offers an opportunity to test the importance of tank-habitat for fauna in restored ecosystems. Because the terrestrial habitat is the most available in recently restored ecosystems, reintroducing bromeliad in these places also offers opportunities to understand whether bromeliad play the same ecological role in alternative habitats. Therefore, we aimed to evaluate the impact of using bromeliad in reforested ecosystems and to test whether there is difference in visiting dynamics of fauna associated with tank-habitats in typical epiphytes and alternative terrestrial habitats of a bromeliad species.

We selected a reforested area placed between two old Atlantic Forest remnants and surrounded by a densely urbanized matrix in Recife, Pernambuco, Brazil (08°04’40.9”S, 34°57’53.0”W; Fig. 1). The reforested area was a pasture field of elephant grass and brachiaria until 2010, when the Recife Environmental Office (Prefeitura da Cidade do Recife) started several programs of reforestation (Nascimento et al. 2017Nascimento LM, Oliveira AM & Nascimento UB (2017) Aspectos históricos e ambientais do Jardim Botânico do Recife, Pernambuco. Arrudea 3: 51-75. ). The climate of the region is tropical rainy (AS’); the dry season is from October to December and the rainiest season is between May and July; the average annual rainfall is 1,651 mm/year and the average temperature is 25 °C (77 °F); and the soil of the region is classified as dystrophic red argisols (Nascimento et al. 2017).

For this study, we used plants of Hohenbergia ramageana Mez (Bromeliaceae: Bromelioideae), an epiphyte and terrestrial tank-bromeliad endemic to the Atlantic Forest of the states of Alagoas, Pernambuco, Paraíba and Rio Grande do Norte (Siqueira-Filho & Leme 2006Siqueira-Filho JA & Tabarelli M (2006) Bromeliad species of the Atlantic forest of north-east Brazil: losses of critical populations of endemic species. Oryx 40: 218-224. DOI: 10.1017/S0030605306000627
https://doi.org/10.1017/S003060530600062... ). In 2015, an outbreak of dengue disease in Recife caused panic, bringing about many people to remove bromeliads from urban trees. The team of Recife Botanic Garden rescued these plants and brought them to be cultivated in the plant nursery of the institution. All the specimens used in our study came from this rescue. Although H. ramageana occurs in the forest remnants adjacent to the study area, spontaneous individuals of this species have not been reported after the reforestation until our intervention. In addition, the reforestation programs in the area have used only trees, excluding other groups such as bromeliads (Nascimento et al. 2017Nascimento LM, Oliveira AM & Nascimento UB (2017) Aspectos históricos e ambientais do Jardim Botânico do Recife, Pernambuco. Arrudea 3: 51-75. ).

Figure 1
a-b. Study area location and aspect of phytophysiognomy - a. before reforestation; b. after reforestation. Satellite imagery taken from Google Earth shows the area in September 2009 (a) and October 2018 (b).

Prior to translocation, shoots from different individuals were separated to avoid the use of clones. Before transplanting plants to the area of study, we washed the tanks of the bromeliads to remove all organisms present in them. We planted twenty adult individuals of H. ramageana as epiphytes (n = 10) and terrestrial (n = 10) along a transect in the reforested area in February 2017. We reintroduced plants in pairs, where epiphytes were fixed in a tree 1.7 to 2 meters above to where a terrestrial was planted. Epiphyte plants were attached to the trees with naturally worn cotton twine. We collected data on colonization of rosettes from March to October 2017. The data collection consisted in: (1) passive searching of the visiting fauna lasting ten minutes for each translocated individual; (2) active search inside the rosette for five minutes (manual scan on phytothelma) and around each individual. Observations were recorded by photograph and later identified at Order level.

We performed z-tests to evaluate differences in richness of orders of animals and in the number of visited plants between epiphytic and terrestrial translocated plants. For testing differences in taxonomic composition between epiphytic and terrestrial translocation, we run an ANOSIM test with 10,000 permutations over a Jaccard matrix of similarity. We carried out multiple Chi-squared tests to check for differences in richness and number of visited plants by month. Finally, we performed correlation analysis to evaluate the response of richness of orders and number of visited plants to precipitation. We ran all the analysis in R-Environment (R Core Team 2020).

We recorded visiting animals in almost the same number of terrestrial (9) and epiphyte (8) tank-bromeliad along the eight months (z = -0.50, p = 0.61). However, we found a significant difference between the number of visited epiphytes and terrestrial plants in September (X² = 4, df = 1, p = 0.04). Animals occupied epiphyte plants for more time than terrestrial plants (Fig. 2).

Eight orders of animals were found in each habitat (Figs. 2-3). In the first month, four terrestrial and three epiphyte plants were visited by three orders of animals (Fig. 2). We found no differences in richness of animal orders between epiphyte and terrestrial plants by month, according to the Chi-Squared test. Taxonomic composition of the colonization was similar between epiphytes and terrestrials, despite it varied slightly (ANOSIM: R = 0.05, p = 0.23). Araneae, Coleoptera, and Hymenoptera visited the bromeliads first. Araneae, Phyllodocida, Hemiptera, Hymenoptera, Lepidoptera, and Orthoptera used both epiphytes and terrestrial habitats. While Anura and Squamata appeared only in epiphyte plants, Didelphimorphia and Coleoptera visited only terrestrial plants. We recorded vertebrates from the fifth month until the end of the experiment (Fig. 2).

The number of occupied plants and the richness of animal orders increased in the wettest months and started to decrease in the beginning of the dry season (Fig. 2). We found that precipitation explained a significant proportion of variation of the number of visited plants (cor = 0.41, p = 0.31) and richness of animal orders (cor = -0.53, p = 0.18), but these correlations lack statistical support. Finally, we identified a gap in animal activities in the second month of the survey. An unidentified stochastic event might have caused this anomaly in the data.

Figure 2
Number of used plants and dynamics of fauna occupation of epiphyte and terrestrial plants after enrichment with Hohenbergia ramageana in a reforested area of the Atlantic Forest in Pernambuco. The line represents the monthly rainfall recorded in 2017 when the reintroduction experiment was performed. Silhouettes symbolize the orders recorded in the bromeliads in the sequence of appearance: Araneae, Coleoptera, Hymenoptera, Hemiptera, Phyllodocida, Lepidoptera, Orthoptera, Didelphimorphia, Anura and Squamata.

Our results confirm the importance of using tank-bromeliads in reforested and add proves that reintroduced bromeliads in alternative habitats also play the same role for animal colonization as in their original habitat. Fernandez-Barrancos et al. (2016) found that using tank-bromeliad raised richness and abundance of arthropods in a reforested ecosystem in Costa Rica. In another study, Melo et al. (2016Melo TDS, Benati KR, Peres MC, Tinôco MS, Andrade AR & Alves MD (2016) Bromeliad translocation in Atlantic Forest fragments, Brazil. Conservation Evidence 13: 88-92. ) noted that translocation of bromeliads to enriching reforested ecosystems promoted local maintenance of biodiversity. Conclusions of these works reinforce our observations in translocation of H. ramageana. However, Fernandez-Barrancos et al. (2016) and Melo et al. (2016) deal specifically with the impact of tank-bromeliad on arthropods, while we bring a more complete view of the faunal colonization of tank-bromeliad habitats.

We add more evidence of immediate use of habitats offered by bromeliads after translocation procedure. Bromeliads provide essential resources for breeding, sheltering and feeding of several animal groups (Benzing 2000Benzing DH (2000) Bromeliaceae: profile of an adaptative radiation. Cambridge University Press, Cambridge. 690p.). This explains the fast exploration of tank habitats of H. ramageana by animals. Previous studies found a long gap between the translocation and the first observations of animal activities in tank-bromeliads (Fernandez-Barrancos et al. 2016; Melo et al. 2016Melo TDS, Benati KR, Peres MC, Tinôco MS, Andrade AR & Alves MD (2016) Bromeliad translocation in Atlantic Forest fragments, Brazil. Conservation Evidence 13: 88-92. ), probably as an effect of the experimental design.

We observed that arthropods started the initial occupation of habitats offered by H. ramageana, that richness of orders increased gradually, and that vertebrates appeared when the community of invertebrates diversified. Usually, invertebrates of class Insecta predominate among the faunal community of thank-bromeliad habitat (Rocha et al. 2004Rocha CFD, Cogliatti-Carvalho L, Nunes-Freitas AF, Rocha-Pessôa TC, Dias AS, Ariani CV & Morgado LN (2004) Conservando uma larga porção da diversidade biológica através da conservação de Bromeliaceae. Vidália 2: 52-72.). In our study, Didelphimorphia species used only terrestrial plants while Anura species used only epiphyte plants, following a pattern of habitat composition described in literature (Rocha et al. 2004).

Figure 3
a-h. Representative species of orders recorded in tank-bromeliads of Hohenbergia ramageana used to enrich a reforested area in Atlantic Forest - a. Araneae; b. Coleoptera; c. Hymenoptera; d. Hemiptera; e. Phyllodocida; f. Lepidoptera; g. Anura; h. Didelphimorphia.

Bromeliads are viable in reforested areas and essential for any program of ecological recovery in Atlantic Forest, as we can conclude from our results. Bromeliaceae play a role that can ease the continuous habitat loss in Atlantic Forest. This paper illustrates that restoring populations of bromeliad increases habitat in restored areas. Finally, this study adds new empirical evidence on ecological relationships of bromeliads bringing an example of the process of colonization of tank-bromeliad habitat.

Acknowledgements

We are grateful to Prefeitura da Cidade do Recife, for the fellowship of the first author. We also thank the manager staff of Jardim Botânico do Recife, for logistical support to this work.

Data availability statement

In accordance with Open Science communication practices, the authors inform that all data are available within the manuscript. Raw data for analyzes can be requested to the corresponding author.

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