SPECIES RICHNESS AND ABUNDANCE OF LOW-TRUNK HERB EPIPHYTES IN RELATION TO HOST TREE SIZE AND BARK TYPE, EASTERN AMAZONIA

Magalhães, José Leonardo Lima; Lopes, Maria Aparecida

doi:10.1590/0100-67622015000300006

ABSTRACT

The composition and structure of the low-trunk epiphytic herb assembly as well as its vertical distribution were studied. DBH of host tree and bark type influence species richness and abundance in a nonlooded lowland tropical rainforest in Eastern Amazonia (1º57’36"S 51º36’55"W). A total of 37 epiphytic herb species were identified, among which 60% were Araceae. Species richness and abundance of epiphytic herbs showed tendency of positive correlation with host tree size and no relationships with bark type. Low positive correlation may be a by-product of the predominance of trees with smaller diameter in our sample rather than a reflection of neutral relationship. The absence of relationships with bark type may be partially explained by the large number of secondary, generalist, hemi-epiphytes and also may reflect the absence of suitable substrate in trees with smaller diameter.

Keywords:
Secondary hemi-epiphyte; Lowland tropical rainforest; Composition

RESUMO

A composição e estrutura da comunidade epifítica herbácea de fuste baixo, assim como sua distribuição vertical, foram estudadas. O DAP de hospedeiros arbóreos e o tipo de casca influenciam a riqueza e abundância dessas espécies em um trecho de floresta de terra firme na Amazônia Oriental (1º57’36"S 51º36’55"W). Foram identificadas, no total, 37 espécies herbáceas epifíticas, sendo 60% delas Araceae. A riqueza de espécies e a abundância de herbáceas epifíticas mostraram tendência de correlação positiva com o tamanho de hospedeiros arbóreos e nenhuma relação com o tipo de casca. Correlação positiva baixa pode ser um subproduto da predominância de árvores de menor diâmetro na amostragem em vez de refletir relação neutra. A ausência de relações com o tipo de casca deve ser parcialmente explicada pelo grande número de hemiepífitas secundárias, generalistas, e também refletir a ausência de substratos adequados em árvores de menor diâmetro.

Palavras-chave:
Hemiepífita secundária; Floresta de terra firme; Composição

1. INTRODUCTION

Epiphytic plants are recurrent in all humid tropical environments comprising about one third of all plants and 10% of the species in tropical forests (KRESS, 1986KRESS, J.W. The systematic distribution of vascular epiphytes: an update. Selbyana, v.9, p.2-22, 1986.; BENZING, 1990BENZING, D.H. Vascular epiphytes. Cambridge: Cambridge University Press, 1990.). In more humid areas and midelevation altitudes, like the submontane forests of the Andes and the Atlantic Forest in southern Brazil, epiphytes may constitute up to 50% of the total number of species (GENTRY; DODSON, 1987aGENTRY, A.H.; DODSON, C.H. Contribution of non-trees to species richness of tropical rain forest. Biotropica, v.19, n.2, p.149-156, 1987a; CARDELÚS et al., 2006CARDELÚS, C.L.; COLWELL, R.K.; WATKINS, J.E. Vascular epiphyte distribution patterns: explaining the mid-elevation richness peak. Journal of Ecology, v.94, p.144-156, 2006.; KERSTEN; SILVA, 2006KERSTEN, R.A., SILVA, S.M. The floristic compositions of vascular epiphytes of a seasonally inundated Forest on the coastal plain of Ilha do Mel Island, Brazil. Revísta de Biología Tropical, v.54, n.3, p.935-942, 2006.). The abundance and vertical distribution of these species reflect environmental gradients in both local and regional scales (GENTRY; DODSON, 1987aGENTRY, A.H.; DODSON, C.H. Contribution of non-trees to species richness of tropical rain forest. Biotropica, v.19, n.2, p.149-156, 1987a; TER STEEGE; CORNELISSEN, 1989TER STEEGE, H.; CORNELISSEN, J.H.C. Distribution and ecology of vascular epiphytes in lowland rain forest of Guyana. Biotropica, v.21, n.4, p.331-339, 1989.; NIEDER et al., 2000NIEDER, J.; ENGWALD, S.; KLAWUN, M.; BARTHLOTT, W. Spatial distribution of vascular epiphytes (including hemiepiphytes) in a lowland Amazonian rain forest (Surumoni Crane Plot) of Southern Venezuela. Biotropica, v.32, n.3, p.385-396, 2000.).

Almost 80% of the epiphytic species in tropics occur in the upper canopy, and fewer and different ones occur in the lower parts of their phorophytes (BENZING, 1990BENZING, D.H. Vascular epiphytes. Cambridge: Cambridge University Press, 1990.; WOLF; FLAMENCO-S, 2003WOLF, J.H.D.; FLAMENCO-S, A. Patterns in species richness and distribution of vascular epiphytes in Chiapas, Mexico. Journal of Biogeography, v.30, p.1689-1707, 2003.). Along the vertical gradient there is lower light incidence and less substrate availability, although higher humidity in the lower strata (TER STEEGE; CORNELISSEN, 1989TER STEEGE, H.; CORNELISSEN, J.H.C. Distribution and ecology of vascular epiphytes in lowland rain forest of Guyana. Biotropica, v.21, n.4, p.331-339, 1989.). Due to the differential microclimate of the understory, species that are more sensitive to desiccation as well as hemi-epiphytic individuals seeking appropriate photic levels are more abundant in this stratum (NIEDER et al., 2000NIEDER, J.; ENGWALD, S.; KLAWUN, M.; BARTHLOTT, W. Spatial distribution of vascular epiphytes (including hemiepiphytes) in a lowland Amazonian rain forest (Surumoni Crane Plot) of Southern Venezuela. Biotropica, v.32, n.3, p.385-396, 2000.).

The number of low-trunk epiphytic species and individuals may be correlated with the trunk diameter of their host trees (CALLAWAY et al., 2002CALLAWAY, R.M.; REINHART, K.O.; MOORE, G.W.; MOORE, D.J.; PENNINGS, S.C. Epiphyte host preferences and host traits: mechanisms for species-specific interactions. Oecologia, v.132, p.221-230, 2002.; MORAN et al., 2003MORAN, R.C.; KLIMAS, S.; CARLSEN, M. Low-trunk epiphytic ferns on tree ferns versus angiosperms in Costa Rica. Biotropica, v.35, n.1, p.48-56, 2003.; ZOTZ; VOLLRATH, 2003ZOTZ, G.; VOLLRATH, B. The epiphyte vegetation of the palm Socratea exorrhiza - correlations with tree size, tree age and bryophyte cover. Journal of Tropical Ecology, v.19, p.81-90, 2003.; MEHLTRETER et al., 2005MEHLTRETER, K.;; FLORES-PALACIOS, A. GARCÍA-FRANCO, J.G. Host preferences of low-trunk vascular epiphytes in a cloud forest of Veracruz, Mexico. Journal of Tropical Ecology, v.21, p.651-660, 2005.). Larger trees are available as hosts for a longer period of time and usually have more surfacearea than smaller trees (FLORES-PALACIOS; GARCÍA-FRANCO, 2006FLORES-PALACIOS, A.; GARCÍA-FRANCO, J. Habitat isolation changes the beta diversity of the vascular epiphyte community in lower montane forest, Veracruz, Mexico. Biodiversity and Conservation, v. 17 , p.191-207, 2006.; LAUBE; ZOTZ, 2006LAUBE, S.; ZOTZ, G. Neither host-specific nor random: vascular epiphytes on three tree species in a Panamanian lowland forest. Annals of Botany, v.97, p.1103-1114, 2006.). On the other side, too old decaying trees with loosing bark offer a less favorable site to epiphytes (FLORES-PALACIOS; GARCÍA-FRANCO, 2006FLORES-PALACIOS, A.; GARCÍA-FRANCO, J. Habitat isolation changes the beta diversity of the vascular epiphyte community in lower montane forest, Veracruz, Mexico. Biodiversity and Conservation, v. 17 , p.191-207, 2006.). Bark type also influences epiphytic richness and abundance (CALLAWAY, et al. 2002CALLAWAY, R.M.; REINHART, K.O.; MOORE, G.W.; MOORE, D.J.; PENNINGS, S.C. Epiphyte host preferences and host traits: mechanisms for species-specific interactions. Oecologia, v.132, p.221-230, 2002.). Rough barks offer more microhabitats for seed germination and root attachment facilitating epiphyte establishment (BENZING, 1990BENZING, D.H. Vascular epiphytes. Cambridge: Cambridge University Press, 1990.; LAUBE; ZOTZ, 2006LAUBE, S.; ZOTZ, G. Neither host-specific nor random: vascular epiphytes on three tree species in a Panamanian lowland forest. Annals of Botany, v.97, p.1103-1114, 2006.; TEWARI et al., 2009TEWARI, L.M.; TEWARI, G.; NAILWAL, T.; PANGTEY, Y.P.S. Bark factors affecting the distribution of epiphytic ferns communities. Nature and Science, v.7, n.5, p.76-81, 2009.; CHOMBA et al., 2011CHOMBA, C.; SENZOTA, R.; CHABWELA, H.; NYIRENDA, V. The influence of host tree morphology and stem size on epiphyte biomass distribution in Lusenga Plains National Park, Zambia. Journal of Ecology and Natural Environment, v.3, n.12, p.370-380, 2011.).

The ecological knowledge about vascular epiphytes in Brazilian Amazon in currently still incipient, with a modest number of studies carried out in the biome (POS; SLEEGERS, 2010POS, E.T.; SLEEGERS, A.D.M. Vertical distribution and ecology of vascular epiphytes in a lownland tropical rainforest of Brazil. Boletim do Museu Paraense Emílio Goeldi, Série Ciências Naturais, v.5, n.3, p.335-344, 2010.; MEDEIROS; JARDIM, 2011MEDEIROS, T.D.S.; JARDIM, M.A.G. Distribuição vertical de orquídeas epífitas na Área de Proteção Ambiental (APA) Ilha do Combu, Belém, Pará, Brasil. Revista Brasileira de Biociências , v. 9 , n . 1, p.33-38, 2011.; IRUME et al., 2013IRUME, M.V.; MORAIS, M.L.C.S.; ZARTMAN, C.E.; AMARAL, I.L. Floristic composition and community structure of epiphytic angiosperms in a terra firme forest in central Amazonia. Acta Botanica Brasilica, v. 27, n . 2 , p.278-393, 2013.; KOCH et al., 2013KOCH, A.K.; SANTOS, J.U.M.; ILKIU-BORGES, A.L. Bromeliaceae epífitas de uma Área de Conservação da Amazônia brasileira. Rodriguésia, v.64, n.2, p.419-425, 2013.; QUARESMA; JARDIM, 2012QUARESMA, A.C.; JARDIM, M.A.G. Diversidade de bromeliáceas epífitas na Área de Proteção Ambiental Ilha do Combu, Belém, Pará, Brasil. Acta Botanica Brasilica, v.26, n.2, p.290-294, 2012., 2013QUARESMA, A.C.; JARDIM, M.A.G. Fitossociologia e Distribuição Espacial de Bromélias epifíticas em uma Floresta de Várzea Estuarina Amazônica. Revista Brasileira de Biociências, v.11, n.1, p.1-6, 2013., 2014QUARESMA, A.C.; JARDIM M.A.G. Floristic composition and spatial distribution of vascular epiphytes in the restingas of Maracanã, Brazil. Acta Botanica Brasilica, v.28, n.1, p.68-75, 2014.; OBERMULLER et al., 2014OBERMULLER, F.A.; FREITAS, L.; DALY, D.C.; SILVEIRA, M. Patterns of diversity and gaps in vascular (hemi-) epiphyte flora of Southwestern Amazonia. Phytotaxa, v.166, n.4, p.259-272. 2014.). Epiphytic plants are important components of the tropical forest ecosystem and understanding their relationship with environment, including tree hosts, may help to predict their occurrence and to plan their conservation.

This study describes the composition and structure of the low-trunk epiphytic herb assembly in Caxiuanã National Forest, eastern Amazonia. We also investigate the following hypothesis based on previous cited literature and theory: (1) species richness and (2) number of individuals increase with DBH of host trees; and rough-barked trees have more (3) species and (4) individuals than fissured- and smooth- barked trees.

2. MATERIAL AND METHODS

2.1. Study site

This study was carried out in a 25km² trail grid established at the center of the Caxiuanã National Forest – CNF – (1º57' - 2º0’S and 51º36' - 51º39’W), Eastern Amazonia (Figure 1). This trail grid belongs to a longterm Brazilian research program in biodiversity (PPBio/ Eastern Amazônia). This research program aims to execute standardized protocols along Eastern Amazon rainforest prospecting biodiversity and maintaining biological collections in order to integrate and disseminate information in biodiversity (ppbio.museu-goeldi.br).

Figure 1
Study area with location of PPBIO/Eastern Amazonia site, the trail grid at the center of the Caxiuanã National Forest. Figura 1 – Área de estudo com a localização do sítio do PPBIO/Amazônia Oriental, a grade de trilhas no centro da FLONA de Caxiuanã.

The climate at Caxiuanã is Am_i, humid tropical, according to Köppen’s classification, with more intense rainfall from December to June, an annual average rainfall of 1900mm and an average annual temperature around 26 ºC (COSTA; MORAES, 2002COSTA, J.P.R.; MORAES, J.C. Médias mensais de variáveis metereológicas (1996-1999). In: LISBOA, P.L.B. (Ed.) Caxiuanã., Belém: MPEG 2002. p.225-232.; OLIVEIRA et al., 2008OLIVEIRA, L.L.; COSTA, R.F.; SOUSA, F.A.S.; COSTA, A.C.L.; BRAGA, A.P. Precipitação efetiva e interceptação em, Caxiuanã na Amazônia Oriental. Acta Amazonica, v.48, n.4, p.723-732, 2008.). The canopy at CNF is dense and closed; trees can be thirty to forty meters tall, some with large basal areas (LISBOA et al., 1997LISBOA, P.L., ALMEIDA, S.S., SILVA, A.S.L. Florística e estrutura dos ambientes. In: LISBOA, P.L. B. (Ed.) Caxiuanã., Belém: MPEG 1997. p.163-193.). The understory is sparse, with few lianas of genus such as Bauhinia, Tetracera, Doliocarpus, Desmoncus (AMARAL et al., 2009AMARAL, D.D.; ALMEIDA, S.S.; COSTA, D.C.T. Contribuições ao manejo florestal de espécies de valor madeireiro e não madeireiro na Floresta Nacional de Caxiuanã. In: LISBOA, P.L.B. (Ed.) Caxiuanã, desafios para a conservação de uma Floresta Nacional na Amazônia. Belém: MPEG, 2009. p.199-228.), terrestrial herbs such as Ischnosiphon, Calathea and Pariana (AUTHOR, unpublished results) and many tree species that reach 150-180 species per hectare and include many individuals with large DBH (AMARAL et al., 2009AMARAL, D.D.; ALMEIDA, S.S.; COSTA, D.C.T. Contribuições ao manejo florestal de espécies de valor madeireiro e não madeireiro na Floresta Nacional de Caxiuanã. In: LISBOA, P.L.B. (Ed.) Caxiuanã, desafios para a conservação de uma Floresta Nacional na Amazônia. Belém: MPEG, 2009. p.199-228.).

2.2. Data collection and analysis

Between March and September 2009, thirty transects of 2m x 100m (6000m²) separated systematically by one kilometer were used to inventory the low-trunk epiphytic herb assembly (Figure 1). Within these transects all trees and treelets with DBH >1cm with at least one epiphytic individual were surveyed, as well as trunks of standing and fallen dead trees. In all cases only the bottom of the stem up to 8m high were examined. For trees, this part was called low-trunk (TER STEEGE; CORNELISSEN, 1989TER STEEGE, H.; CORNELISSEN, J.H.C. Distribution and ecology of vascular epiphytes in lowland rain forest of Guyana. Biotropica, v.21, n.4, p.331-339, 1989.). All epiphytes were counted, and morphotyped, and the height at which each one occurred was recorded. When the morphotype was not easily recognized in situ, the specimen was collected. Clonal plants were counted as single individuals when we were sure about it was a single genet, based on visual separation. Botanical samples from all morphospecies, with fertile material when possible, were collected and dried for subsequent identification.

These collected materials were identified in the laboratory with help of specialized literature (STEYERMARK et al., 1995STEYERMARK, J.S.; BERRY, P.E.; HOLST, B.K. Flora of the Venezuelan Guayana. Portland: Timber Press, 1995.; MAYO et al., 1997MAYO, S.J.; BOGNER, J.; BOYCE, P.C. The genera of Araceae. Kew: Royal Botanic Gardens, 1997.; RIBEIRO et al., 1999RIBEIRO, J.E.L.S.; HOPKINS, M.J.G.; VICENTINI, A.; SOTHERS, C.A.; COSTA, M.A.S.; BRITO, J.M.; SOUZA, M.A.D.; MARTINS, L.H.P.; LOHMANN, L.G.; ASSUNÇÃO, P.A.C.L.; PEREIRA, E.C.; SILVA, C.F.; MESQUITA, M.R.; PROCÓPIO, L.C. Flora da Reserva Ducke: guia de identificação das plantas vasculares de uma floresta de terra firme na Amazônia Central. Manaus: INPA/DFID, 1999.; SILVA; ROSÁRIO, 2008SILVA, M.R.P.; ROSÁRIO, S.M. Licófitas e monilófitas (Pteridophyta) da Floresta Nacional de, Caxiuanã estado do Pará, Brasil: chave para as famílias e as espécies de Aspleniaceae e Blechnaceae. Boletim do Museu Paraense Emílio Goeldi, Série Ciências Naturais, v.3, n.2, p.151-163, 2008.; ZUQUIM et al., 2008ZUQUIM, G.; COSTA, F.R.C.; PRADO, J.; TUOMISTO, H. Guia de samambaias e licófitas da REBIO Uatumã. Manaus: Amazônia Central/INPA, 2008.) and by comparison with herbarium specimens. The fertile material was deposited in the Herbarium João Murça Pires MG. Identification of Monilophyta followed Smith et al. (2006)SMITH, A.R.; PRYER, K.M.; SCHUETTPELZ, E.; KORALL, P.; SCHNEIDER, H.; WOLF, P.G. A classification for extant ferns. Taxon, v.55, n.3, p.705-731, 2006. and of Magnoliophyta followed APG II (2003). Species and authors names were checked on the site Tropicos (2013) available at www.tropicos.org (last access 10/01/2013) and synonyms were verified in the World Checklist of Selected Plant Families (2013) available at http://apps.kew.org/ wcsp (last access 10/02/2013). All identified morphospecies were considered different species in the analysis.

Epiphytes were classified based on their relationship to the host trees (following BENZING, 1990BENZING, D.H. Vascular epiphytes. Cambridge: Cambridge University Press, 1990.) as holoepiphytes, hemi-epiphytes (primary and secondary), facultative epiphytes and accidental epiphytes. When the species identification was not possible, it was based on classification found in the literature about the genus.

All species encountered were included to compose the list of epiphytic herbs and to describe the assembly structure (frequency, relative abundance and vertical distribution), regardless of the type of phorophyte (n=739). Only host trees whose DBH measures were available in previous study data set (n=246) were used to test hypotheses 1) and 2); and only host trees identified to the species level (n=79) were included to test hypotheses 3) and 4). Bark was classified as rough (n=28), fissured (n=25) and smooth (n=26) based on descriptions available in the literature (RIBEIRO et al., 1999RIBEIRO, J.E.L.S.; HOPKINS, M.J.G.; VICENTINI, A.; SOTHERS, C.A.; COSTA, M.A.S.; BRITO, J.M.; SOUZA, M.A.D.; MARTINS, L.H.P.; LOHMANN, L.G.; ASSUNÇÃO, P.A.C.L.; PEREIRA, E.C.; SILVA, C.F.; MESQUITA, M.R.; PROCÓPIO, L.C. Flora da Reserva Ducke: guia de identificação das plantas vasculares de uma floresta de terra firme na Amazônia Central. Manaus: INPA/DFID, 1999.).

For each species, the frequency of occurrence (F = [n_i/n_t]x100, where n_i=number of phorophytes supporting the species i, n_t=total number of hosts) and relative abundance (RA = [ne_i/ne_t]x100 , where ne_i=number of individuals of epiphytic species i, ne_t=total number of epiphytic individuals) were calculated. The vertical distribution was evaluated for all epiphytic families and genera that had at least five individuals along the vertical gradient. The species cumulative curve and nonparametric bootstrap were used to assess representativeness of the sampling effort with 95% confidence with100 randomizations (MAGURRAN, 2004MAGURRAN, A. Measuring biological diversity. London: Blackwell Science, 2004.).

Variables tested were not normal or homocedastic, so non-parametrical statistics were used in all cases. Hypotheses 1) and 2) were tested applying Spearman’s correlation rank, and hypotheses 3) and 4) were tested applying Kruskal-Wallis, all considering p < 0.05. Analyses were performed with R 2.15 (R DEVELOPMENT CORE TEAM, 2005R DEVELOPMENT CORE TEAM. R: A Language and Environment for Statistical Computing. Version 2.10. Vienna, Austria: 2005.), EstimateS 8.0 (COLWELL, 2006COLWELL, R.K. Estimate S:Estatistical estimation of species richness and shared species from samples, Versão 8. 2006.) and PAST (HAMMER et al., 2001HAMMER, O.; HARPER, D.A.T.; RYAN, P.D. PAST: Paleontological statistics software package for education and data analysis. Paleontologia Electronica, v. 4 , n. 1 , p. 1-9, 2001.).

3. RESULTS

In total 1,091 epiphytic herb individuals were found on 739 phorophytes, distributed in 10 families and 37 morphospecies comprising at least 30 species (Table 1). Only one form of the genera Microgramaand Catasetum was recorded, suggesting that only one species of each genus occurs in the area. About 70% of the sampled individuals were in juvenile stages and, of these, 40% could only be identified as morphospecies.

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Table 1
Species list of low-trunk epiphytic herb species and their relationship with host tree, classified according to relative abundance. Lista de espécies de herbáceas epifíticas de fuste baixo e suas relações com hospedeiros arbóreos, classificadas segundo sua abundância relativa

Twelve species were categorized as holo-epiphytes, 25 as secondary hemi-epiphytes and there were no reports of facultative, accidental or primary hemiepiphytes (Table 1). In Araceae, only one species was not a hemi-epiphyte, Anthurium gracile, which is a holoepiphyte. This species was associated with ants as were two other species, Aechmea bromeliifolia (Bromeliaceae) and Codonanthe calcarata(Gesneriaceae).

The botanical family with the greatest richness was Araceae with 23 species (62% of the total), followed by Pteridaceae with three species (8%). The three most abundant families were Araceae, Pteridaceae and Lomariopsidaceae which together accounted for 99% of the individuals sampled. The remaining families contributed with one or two species and no more than 12 individuals.

The great majority of epiphytes occurred on the lower three meters of the trunk, particularly ferns and allies probably due to their great demand of humidity (Figure 2A). Cyclanthaceae and Polypodiaceae were the most evenly distributed families (Figure 2B), occurring frequently up to 5m high.

Figure 2
Vertical distribution of low-trunk epiphytic herb genera (A) and family (B) in tree host at the Caxiuanã National Forest, Eastern Amazonia. Figura 2 – Distribuição vertical dos gêneros (A) e famílias (B) de epífitas herbáceas de fuste baixo em hospedeiros arbóreos na FLONA de Caxiuanã, Amazônia Oriental.

The species rarefaction curve (Figure 3) showed no apparent asymptote, but it did tend toward stabilization. With the non-parametric bootstrap statistical test we estimated a richness equivalent to 41±8 species, indicating that this study reached about 90% of the expected richness.

Figure 3
Species accumulation curve (line) of epiphytic herb species sampled on 739 phorophytes with 95% confidence (light gray) with 100 randomizations, in the Caxiuanã National Forest, Eastern Amazonia. Figura 3 – Curva cumulativa de espécies (linha) de epífitas herbáceas amostradas em 739 forófitos com 95% de confiança (cinza claro) e 100 aleatorizações, na FLONA de Caxiuanã, Amazônia Oriental.

Both species richness (Spearman=0.15, p=0.01) and abundance (Spearman=0.23, p=0.0002) showed a tendency of positive correlation with DBH (Figure 4). Rough-barked trees did not have more species richness (Kruskal-Wallis=0.27, p=0.83) and abundance (KruskalWallis=0.1, p=0.93) than fissured- and smooth-barked trees.

Figure 4
Correlation between species richness (Spearman=0.15, p=0.01 - triangle) and abundance (Spearman=0.23, p=0.0002 - dots) of epiphytic herb species versus DBH of host trees in the Caxiuanã National Forest, Eastern Amazonia. Figura 4 – Correlação entre riqueza de espécies (Spearman = 0,15, p = 0,01 - triângulo) e abundância (Spearman = 0,23, p = 0,0002 - pontos) de epífitas herbáceas e DAP de hospedeiros arbóreos na FLONA de Caxiuanã, Amazônia Oriental.

4. DISCUSSION

The epiphytic herb assembly at CNF showed a relatively low number of species (30-37) compared to studies carried out in Amazonia (NIEDER et al., 200NIEDER, J.; ENGWALD, S.; KLAWUN, M.; BARTHLOTT, W. Spatial distribution of vascular epiphytes (including hemiepiphytes) in a lowland Amazonian rain forest (Surumoni Crane Plot) of Southern Venezuela. Biotropica, v.32, n.3, p.385-396, 2000.0; BUSSMANN, 2001BUSSMANN, R.W. Epiphyte diversity in a tropical Andean Forest - Reserva Biológica San Francisco, Zamora-Chinchipe, Ecuador. Ecotropica, v.7, p.43-59, 2001.; LEIMBECK; BALSLEV, 2001LEIMBECK, R.M.; BALSLEV, H. Species richness and abundance of epiphytic Araceae on adjacent floodplain and upland forest in Amazonian Ecuador. Biodiversity and Conservation, v.10, p.1579-1593, 2001.; KREFT et al., 2004KREFT, H.; KÖSTER, N.; KÜPER, W.;; NIEDER, J. BARTHLOTT, W. Diversity and biogeography of vascular epiphytes in Western Amazonia, Yasuní, Ecuador. Journal of Biogeography, v.31, p.1463-1476, 2004.; KÜPER et al., 2004KÜPER, W.;; KREFT, H.; NIEDER, J. KÖRTER, N.; BARTHLOTT, W. Large-scale diversity patterns of vascular epiphytes in Neotropical montane rain forests. Journal of Biogeography, v.31, p.1477-1487, 2004.; BENAVIDES et al., 2005BENAVIDES, A.M.D.; DUQUE, A.J.; DUIVENVOORDEN, J.F.; VASCO, G.A.; CALLEJAS, R. A first quantitative census of vascular epiphytes in rain forests of Colombian Amazonia. Biodiversity and Conservation, v.14, p.739-758, 2005.; ARÉVALO; BETANCUR, 2006ARÉVALO, R.; BETANCUR, J. Vertical distribution of vascular epiphytes in four Forest types of the Serranía de Chiribiquete, Colombian Guyana. Selbyana, v.27, n.2, p.175-185, 2006.; POS; SLEEGERS, 2010POS, E.T.; SLEEGERS, A.D.M. Vertical distribution and ecology of vascular epiphytes in a lownland tropical rainforest of Brazil. Boletim do Museu Paraense Emílio Goeldi, Série Ciências Naturais, v.5, n.3, p.335-344, 2010.; IRUME et al., 2013IRUME, M.V.; MORAIS, M.L.C.S.; ZARTMAN, C.E.; AMARAL, I.L. Floristic composition and community structure of epiphytic angiosperms in a terra firme forest in central Amazonia. Acta Botanica Brasilica, v. 27, n . 2 , p.278-393, 2013.) and the Guyanas (TER STEEGE; CORNELISSEN, 1989TER STEEGE, H.; CORNELISSEN, J.H.C. Distribution and ecology of vascular epiphytes in lowland rain forest of Guyana. Biotropica, v.21, n.4, p.331-339, 1989.; FREIBERG, 1996FREIBERG, M. Spatial distribution of vascular epiphytes on three emergent canopy trees in French Guiana. Biotropica, v.28, n.3, p.345-355, 1996.). However, one should take into account the fact that only the understory was inventoried, and only herb species were considered. Species richness of epiphytes is often lower on trunks than on the higher parts of the same phorophyte because of the reduced amount of surface available for attachment (TER STEEGE; CORNELISSEN, 1989TER STEEGE, H.; CORNELISSEN, J.H.C. Distribution and ecology of vascular epiphytes in lowland rain forest of Guyana. Biotropica, v.21, n.4, p.331-339, 1989.). Mehltreter et al. (2005)MEHLTRETER, K.;; FLORES-PALACIOS, A. GARCÍA-FRANCO, J.G. Host preferences of low-trunk vascular epiphytes in a cloud forest of Veracruz, Mexico. Journal of Tropical Ecology, v.21, p.651-660, 2005. studied the low-trunk epiphyte assembly at a high altitude forest in Veracruz, Mexico and found around 20% more species (55 in total) than we found at CNF. According to Gentry and Dodson (1987b)GENTRY, A.H., DODSON, C.H. Diversity and biogeography of neotropical vascular epiphytes. Annals of the Missouri Botanical Garden, v.74, p.205-233, 1987b. the contribution of epiphytic species to the whole diversity of an area varies according to the different forest type and is usually smaller in lowland forests such as in the CNF. On the other hand, Araceae usually presents high species richness and abundance in lowland forest (IBISCH et al., 1996IBISCH, P.L.; BOEGNER, A.; NIEDER, J.; BARTHLOTT, W. How diverse are neotropical epiphytes? An analysis on the "Catalogue of the flowering plants and gymnosperms of Peru". Ecotropica, v.2, n.2, p.13-28, 1996.).

As was observed by Ter Steege and Cornelissen (1989)TER STEEGE, H.; CORNELISSEN, J.H.C. Distribution and ecology of vascular epiphytes in lowland rain forest of Guyana. Biotropica, v.21, n.4, p.331-339, 1989. in Guyana, Nieder et al. (2000)NIEDER, J.; ENGWALD, S.; KLAWUN, M.; BARTHLOTT, W. Spatial distribution of vascular epiphytes (including hemiepiphytes) in a lowland Amazonian rain forest (Surumoni Crane Plot) of Southern Venezuela. Biotropica, v.32, n.3, p.385-396, 2000. in Venezuela and Irume et al. (2013)IRUME, M.V.; MORAIS, M.L.C.S.; ZARTMAN, C.E.; AMARAL, I.L. Floristic composition and community structure of epiphytic angiosperms in a terra firme forest in central Amazonia. Acta Botanica Brasilica, v. 27, n . 2 , p.278-393, 2013. in central Amazonia, the most representative group in the assembly of epiphytes on the trunks at CNF were Araceae. The concentration of species in a few families reflects their specialization for the existing understory microhabitats (GENTRY; DODSON, 1987aGENTRY, A.H., DODSON, C.H. Diversity and biogeography of neotropical vascular epiphytes. Annals of the Missouri Botanical Garden, v.74, p.205-233, 1987b.; NIEDER et al., 2001NIEDER, J.; PROSPERÍ, J.; MICHALOUD, G. Epiphytes and their contribution to canopy diversity. Plant Ecology, v.153, n.2, p.51-63, 2001.). The low number or absence of typically reported orchids and bromeliads might be associated with the fact that epiphytic species in these families occupy preferentially the upper strata of the forest. These plants are highly adapted to support the wider range of humidity and temperature in these strata (TER STEEGE; CORNELISSEN, 1989TER STEEGE, H.; CORNELISSEN, J.H.C. Distribution and ecology of vascular epiphytes in lowland rain forest of Guyana. Biotropica, v.21, n.4, p.331-339, 1989.; BENZING, 1990BENZING, D.H. Vascular epiphytes. Cambridge: Cambridge University Press, 1990.; CALLAWAY et al., 2002CALLAWAY, R.M.; REINHART, K.O.; MOORE, G.W.; MOORE, D.J.; PENNINGS, S.C. Epiphyte host preferences and host traits: mechanisms for species-specific interactions. Oecologia, v.132, p.221-230, 2002.). During a survey of the epiphytes on 10 large trees in the same area of this study (CNF), POS and SLEEGERS (2010)POS, E.T.; SLEEGERS, A.D.M. Vertical distribution and ecology of vascular epiphytes in a lownland tropical rainforest of Brazil. Boletim do Museu Paraense Emílio Goeldi, Série Ciências Naturais, v.5, n.3, p.335-344, 2010. found orchids and bromeliads only in the tree canopies, while aroids were found predominantly on the lower part of the trunks.

The predominance of hemi-epiphytic species was also reported for other studies in Amazonia (TER STEEGE; CORNELISSEN, 1989TER STEEGE, H.; CORNELISSEN, J.H.C. Distribution and ecology of vascular epiphytes in lowland rain forest of Guyana. Biotropica, v.21, n.4, p.331-339, 1989.; NIEDER et al.,2000NIEDER, J.; ENGWALD, S.; KLAWUN, M.; BARTHLOTT, W. Spatial distribution of vascular epiphytes (including hemiepiphytes) in a lowland Amazonian rain forest (Surumoni Crane Plot) of Southern Venezuela. Biotropica, v.32, n.3, p.385-396, 2000.; BUSSMAN, 2001BUSSMANN, R.W. Epiphyte diversity in a tropical Andean Forest - Reserva Biológica San Francisco, Zamora-Chinchipe, Ecuador. Ecotropica, v.7, p.43-59, 2001.; LEIMBECK; BALSLEV, 2001LEIMBECK, R.M.; BALSLEV, H. Species richness and abundance of epiphytic Araceae on adjacent floodplain and upland forest in Amazonian Ecuador. Biodiversity and Conservation, v.10, p.1579-1593, 2001.; ARÉVALO; BETANCUR, 2006ARÉVALO, R.; BETANCUR, J. Vertical distribution of vascular epiphytes in four Forest types of the Serranía de Chiribiquete, Colombian Guyana. Selbyana, v.27, n.2, p.175-185, 2006.; IRUME et al., 2013IRUME, M.V.; MORAIS, M.L.C.S.; ZARTMAN, C.E.; AMARAL, I.L. Floristic composition and community structure of epiphytic angiosperms in a terra firme forest in central Amazonia. Acta Botanica Brasilica, v. 27, n . 2 , p.278-393, 2013.). Moreover, most low-trunk epiphytic species and individuals found at CNF were concentrated on the lowest three meters of the trunks, what was evidenced with high number of secondary hemi-epiphytes. These species need to connect with the ground at some point in their life cycle (BENZING, 1990BENZING, D.H. Vascular epiphytes. Cambridge: Cambridge University Press, 1990.) which is why, when escalating a support close to where they germinate their juvenile stages were sampled in large numbers.

Epiphytic species richness and abundance showed positive correlation with DBH, what was expected and confirmed by similar studies (CALLAWAY et al., 2002CALLAWAY, R.M.; REINHART, K.O.; MOORE, G.W.; MOORE, D.J.; PENNINGS, S.C. Epiphyte host preferences and host traits: mechanisms for species-specific interactions. Oecologia, v.132, p.221-230, 2002.; MORAN et al., 2003MORAN, R.C.; KLIMAS, S.; CARLSEN, M. Low-trunk epiphytic ferns on tree ferns versus angiosperms in Costa Rica. Biotropica, v.35, n.1, p.48-56, 2003.; ZOTZ; VOLLRATH, 2003ZOTZ, G.; VOLLRATH, B. The epiphyte vegetation of the palm Socratea exorrhiza - correlations with tree size, tree age and bryophyte cover. Journal of Tropical Ecology, v.19, p.81-90, 2003.; MEHLTRETHER et al., 2005MEHLTRETER, K.;; FLORES-PALACIOS, A. GARCÍA-FRANCO, J.G. Host preferences of low-trunk vascular epiphytes in a cloud forest of Veracruz, Mexico. Journal of Tropical Ecology, v.21, p.651-660, 2005.; FLORES-PALACIOS; GARCÍA-FRANCO, 2006FLORES-PALACIOS, A.; GARCÍA-FRANCO, J. Habitat isolation changes the beta diversity of the vascular epiphyte community in lower montane forest, Veracruz, Mexico. Biodiversity and Conservation, v. 17 , p.191-207, 2006.). The low correlation found may have been at least partially affected by the predominance of smaller trees in our sample, weakening the detection of an expected stronger correlation.

On the other hand, no relationship with bark type was found, contrary to what is generally found in other studies in lowland tropical rainforests (BENZING, 1990BENZING, D.H. Vascular epiphytes. Cambridge: Cambridge University Press, 1990.; LAUBE; ZOTZ, 2006LAUBE, S.; ZOTZ, G. Neither host-specific nor random: vascular epiphytes on three tree species in a Panamanian lowland forest. Annals of Botany, v.97, p.1103-1114, 2006.; TEWARI et al., 2009TEWARI, L.M.; TEWARI, G.; NAILWAL, T.; PANGTEY, Y.P.S. Bark factors affecting the distribution of epiphytic ferns communities. Nature and Science, v.7, n.5, p.76-81, 2009.; CHOMBA et al., 2011CHOMBA, C.; SENZOTA, R.; CHABWELA, H.; NYIRENDA, V. The influence of host tree morphology and stem size on epiphyte biomass distribution in Lusenga Plains National Park, Zambia. Journal of Ecology and Natural Environment, v.3, n.12, p.370-380, 2011.). Wyse and Burns (2011)WYSE, S.V.; BURNS, B.R. Do host bark traits influence trunk epiphyte communities? New Zealand Journal of Ecology, v.35, n.3, p.296-301, 2011. found similar pattern in a temperate New Zealand rainforest but they covered all vertical gradients in four specific host trees species; instead of our assembly sample. This absence of correlation may be partially explained by the large number of secondary hemi-epiphytes which are substrate generalists (TER STEEGE; CORNELISSEN, 1989TER STEEGE, H.; CORNELISSEN, J.H.C. Distribution and ecology of vascular epiphytes in lowland rain forest of Guyana. Biotropica, v.21, n.4, p.331-339, 1989.), but also probably may reflect the absence of suitable substrate in smaller trees.

5. CONCLUSION

Epiphytes are a key component of tropical forest in Amazonia but is not enough studied yet. Its relationships with host trees and bark type are important to enhance ecological knowledge about high diverse environments like Amazon forest and to increase biodiversity information. Furthermore, it is clear that, in others studies in Amazonia, hemi-epiphytes are driving for different pressures than holo-epiphytes. Future analysis should differentiate both growth habitats and also should be important determine the effect of life stage in low trunk epiphytic species on different host sizes.

6. ACKNOWLEDGEMENTS

We thank the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) for granting the scholarship to the first author. The Universidade Federal Rural da Amazônia and Museu Paraense Emílio Goeldi for technical and logistical support. The Coordenação do Programa de Pesquisa em Biodiversidade (PPBio – Eastern Amazônia) for providing access to their tree database, as well as financial and logistical support.

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Publication Dates

Publication in this collection
May-Jun 2015

History

Received
06 Sept 2013
Accepted
15 Apr 2015

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[1] THE ANGIOSPERM PHYLOGENY GROUP - APG II. An update of the Angiosperm Phylogeny Group classification for the orders and families of flowering plants: APG II. Botanical Journal of the Linnean Society, v.141, p.399-436. 2003.

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Species/ Morphospecies	Family	Relationship with host tree¹ 1 E=holo-epiphyte, SHE=secondary hemi-epiphyte.	Relative abundance (%)	Frequency (%)
Polytaenium guayanense (Hieron.) Alston	Pteridaceae	E	21.1	17.6
Heteropsis flexuosa (Kunth) G. S. Bunting	Araceae	SHE	15.4	19.0
Lomariopsis japurensis (Mart.) J. Sm.	Lomariopsidaceae	SHE	11.8	13.3
Philodendron surinamense (Miq.) Engl.	Araceae	SHE	8.1	8.0
Philodendron platypodum Gleason	Araceae	SHE	7.8	9.4
Hecistopteris pumila (Spreng.) J. Sm.	Pteridaceae	E	6.5	1.2
Heteropsis spruceana Schott	Araceae	SHE	4.2	5.1
Philodendron sp. 2	Araceae	SHE	4.1	3.9
Monstera obliqua Miq.	Araceae	SHE	3.6	3.5
Philodendron sp. 1	Araceae	SHE	3.3	4.0
Philodendron rudgeanum Schott	Araceae	SHE	2.0	1.2
Philodendron linnaei Kunth.	Araceae	SHE	1.3	1.6
Asplenium serratum L.	Aspleniaceae	E	1.3	1.6
Monstera adansonii Schott	Araceae	SHE	1.3	1.3
Campyloneurum repens (Aubl.) C. Presl	Polypodiaceae	E	1.2	1.3
Philodendron squamiferum Poepp.	Araceae	SHE	1.2	1.3
Philodendron melinonii Brongn. ex Regel	Araceae	SHE	0.7	0.6
Philodendron pedatum (Hook.) Kunth	Araceae	SHE	0.7	0.6
Evodianthus funifer (Poit.) Lindm.	Cyclanthaceae	SHE	0.6	0.6
Codonanthe calcarata (Miq.) Hanst.	Gesneriaceae	E	0.5	0.6
Philodendron fragantissimun (Hook.) G. Don	Araceae	SHE	0.5	0.6
Anthurium sp. 2	Araceae	SHE	0.4	0.2
Philodendron ecordatum Schott.	Araceae	SHE	0.4	0.5
Anthurium gracile (Rudge) Schott	Araceae	SHE	0.3	0.4
Lomariopsis prieuriana Fée	Lomariopsidaceae	SHE	0.3	0.4
Polytaenium cajenense (Desv.) Benedict	Pteridaceae	E	0.3	0.4
Asplenium juglandifolium Lam.	Aspleniaceae	SHE	0.2	0.2
Micrograma sp.	Polypodiaceae	E	0.2	0.2
Philodendron sp. 3	Araceae	SHE	0.2	0.1
Trichomanes ankersii C. Parker ex Hook. and Grev.	Hymenophyllaceae E		0.2	0.2
Aechmea bromeliifolia (Rudge) Baker	Bromeliaceae	E	0.1	0.1
Anthurium bonplandii G. S. Bunting	Araceae	SHE	0.1	0.1
Anthurium sinuatum Benth. Ex Schott	Araceae	SHE	0.1	0.1
Anthurium sp. 1	Araceae	SHE	0.1	0.1
Catasetum sp.	Orchidaceae	E	0.1	0.1
Philodendron sp. 4	Araceae	SHE	0.1	0.1
Philodendron sp. 5	Araceae	SHE	0.1	0.1

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