ABSTRACT

We compared the reproductive phenology and floral visitors of Eschweilera tetrapetala growing along the edge and in the interior of a submontane forest in the Chapada Diamantina mountains, Bahia State, Brazil. We sought to determine if there were inter-annual differences in intensity and seasonality associated with environmental conditions, and if there were differences in floral visitors between the two environmental contexts. Phenological observations were performed for three years, and included the occurrence of an El Niño event. We applied circular statistics to detect seasonal trends, performed cross correlations between phenophases and climate, Kruskal-Wallis and Wilcoxon signed-rank tests for inter-annual variation, and the Wilcoxon-Mann-Whitney test for edge-interior differences in the species richness of floral visitors. We observed inter-annual variations in the intensity and seasonality of flower production that accompanied variations in rainfall, possibly associated with El Niño events. Floral visitor richness differed between the forest edge and interior, with seven species recorded for the interior and only one for the edge. Reduced fruit set was also observed at the forest edge. This study contributes to our understanding of the influence of El Niño and edge effects on the reproductive phenologies of tropical plants.

Keywords
El Niño; Eschweilera tetrapetala; floral visitors; linear edge effects; phenology; precipitation; seasonality

Introduction

Climate change, fragmentation, and loss of natural areas are among the principal global threats to biodiversity (Klapwijk & Lewis 2008Klapwijk MJ, Lewis OT. 2008. Effects of climate change and habitat fragmentation on trophic interactions. In: Claro KD, Oliveira PS, Rico-Gray V. (eds.) Tropical biology and conservation management. Encyclopedia of Life Support Systems (EOLSS) . Oxford, UNESCO.). There is indisputable evidence that edge effects resulting from forest fragmentation can modify the richness and abundance of tropical arboreal species (e.g., Oliveira et al. 2004Oliveira AM, Grillo AS, Tabarelli M. 2004. Forest edge in the Brazilian Atlantic forest: drastic changes in tree species assemblages. Oryx 38: 389-394.; Pires et al. 2014Pires JPA, Silva AG, Freitas L. 2014. Plant size, flowering synchrony and edge effects: What, how and where they affect the reproductive success of a Neotropical tree species. Austral Ecology 39: 328-336.; Couto-Santos et al. 2015Couto-Santos APL, Conceição AA, Funch LS. 2015. The role of temporal scale in linear edge effects on a submontane Atlantic forest arboreal community. Acta Botanica Brasilica 29: 190-197.). The phenology and reproductive success of plant species occurring near forest edges can be strongly affected by their different environmental conditions (Aguilar & Galleto 2004Aguilar R, Galetto L. 2004. Effects of forest fragmentation on male and female reproductive success in Cestrum parqui (Solanaceae). Oecologia 138: 513-520.; Athayde & Morellato 2014Athayde EA, Morellato LPC. 2014. Anthropogenic edges, isolation and the flowering time and fruit set of Anadenanthera peregrina, a cerrado savanna tree. International Journal of Biometeorology 58: 443-454.). Reductions in the availability of abiotic resources such as water and soil nutrients in edge environments, for example, can limit the fruiting rates of the plants there as compared to those growing in the forest interior (Dunley et al. 2009Dunley B, Freitas L, Galetto L. 2009. Reproduction of Byrsonima sericea (Malpighiaceae) in resting fragmented habitats in Southeastern Brazil. Biotropica 41: 692-699.; Athayde & Morellato 2014Athayde EA, Morellato LPC. 2014. Anthropogenic edges, isolation and the flowering time and fruit set of Anadenanthera peregrina, a cerrado savanna tree. International Journal of Biometeorology 58: 443-454.).

Disturbances of plant-pollinator interactions can also result from habitat fragmentation, and edge effects can further alter pollinator frequencies and abundances - and therefore pollination services - which can lead to drastic effects on both pollinator and plant populations (Aizen & Feinsinger 1994Aizen MA, Feinsinger P. 1994. Habitat fragmentation, native insect pollinators, and feral honey bee in Argentine ‘Chaco Serrano’. Ecological Applications 4: 378-392.; Franceschinelli et al. 2015Franceschinelli EV, Carmo RM, Silva Neto CM, Gonçalves BB, Bergamin LL. 2015. Reproductive success ofCabralea canjerana(Meliaceae) in Atlantic forest fragments, Brazil. Revista de Biologia Tropical 63: 515-524. ). While analyzing edge effects on the pollination and reproduction of Meliaceae species in the Atlantic Forest of southeastern Brazil, Franceschinelli et al. (2015)Franceschinelli EV, Carmo RM, Silva Neto CM, Gonçalves BB, Bergamin LL. 2015. Reproductive success ofCabralea canjerana(Meliaceae) in Atlantic forest fragments, Brazil. Revista de Biologia Tropical 63: 515-524. observed that the numbers of pollinators of the arboreal species examined were greater in the forest interior than at the forest edge.

Another factor that can affect the reproductive phenology of plants is climate change, which can alter flowering seasons, with consequent effects on plant-pollinator interactions (Hughes 2000Hughes L. 2000. Biological consequences of global warming: Is the signal already apparent? Trends in Ecology & Evolution 15: 56-61.; Hegland et al. 2009Hegland SJ, Nielsen A, Lázaro A, Bjerkness A, Totland Ø. 2009. How does climate warming affect plant-pollinator interactions? Ecology Letters 12: 184-195.; Scaven & Rafferty 2013Scaven VL, Rafferty NE. 2013. Physiological effects of climate warming on flowering plants and insect pollinators and potential consequences for their interactions. Current Zoology 59: 418-426.). These effects on the phenological behaviors of plants and the possible loss of synchrony between mutualistic partners indicate the necessity of better understanding pollination mechanisms and how they are affected by the characteristics of plant and pollinator populations (Hegland et al. 2009Hegland SJ, Nielsen A, Lázaro A, Bjerkness A, Totland Ø. 2009. How does climate warming affect plant-pollinator interactions? Ecology Letters 12: 184-195.). A large proportion of our knowledge about phenological responses to climatic alterations has come from studies undertaken in temperate regions in the northern hemisphere, where the effects of global warming have been demonstrated in numerous studies (IPCC 2007IPCC. 2007. Climate change 2007: the physical science basis. Summary for policymakers. Cambridge, Intergovernmental Panel on Climate Change. ).

Studies associating climate changes with alterations of phenological patterns at low latitudes in the southern hemisphere are still rare (Chuine 2010Chuine I. 2010. Why does phenology drive species distribution? Philosophical Transactions of the Royal Society Biological Sciences 365: 3149-3160.). As temperature variations are generally smaller in tropical and sub-tropical areas, rainfall has been identified as the principal phenological driver, especially in seasonal environments (Chambers et al. 2013Chambers LE, Altwegg R, Barbraud C, et al. 2013. Phenological Changes in the Southern Hemisphere. Plos One 8(10). doi:10.1371/journal.pone.0075514.
https://doi.org/10.1371/journal.pone.007... ). El Niño is a major source of climatic variation in tropical South America, mainly affecting rainfall regimes, with potential effects on phenological rhythms (Malhi & Wright 2004Malhi Y, Wright J. 2004. Spatial patterns and recent trends in the climate of tropical rainforest regions. Philosophical Transactions of the Royal Society B 359: 311-329.; Wright & Calderon 2006Wright SJ, Calderon O. 2006. Seasonal, El Niño and longer term changes in flower and seed production in a moist tropical forest. Ecology Letters 9: 35-44.). Multiple year studies of reproductive phenology can help identifying the effects of El Niño and their roles as phenological drivers (Wright & Calderon 2006Wright SJ, Calderon O. 2006. Seasonal, El Niño and longer term changes in flower and seed production in a moist tropical forest. Ecology Letters 9: 35-44.; Chambers et al. 2013Chambers LE, Altwegg R, Barbraud C, et al. 2013. Phenological Changes in the Southern Hemisphere. Plos One 8(10). doi:10.1371/journal.pone.0075514.
https://doi.org/10.1371/journal.pone.007... ).

The reproductive phenology and pollination of plants in the Chapada Diamantina Mountains (the northern extension of the Espinhaço Range in central-eastern Brazil) have been the subject of several studies (Funch et al. 2002Funch LS, Funch RR, Barroso GM. 2002. Phenology of gallery and montane forest in the Chapada Diamantina, Bahia, Brazil. Biotropica 34: 40-50.; Ramos et al. 2005Ramos COC, Borba EL, Funch LS. 2005. Pollination in Brazilian Syngonanthus (Eriocaulaceae) species: evidence for entomophily instead of anemophily. Annals of Botany 96: 387-397.; Souza et al. 2012Souza IM, Coutinho K, Funch LS. 2012. Estratégias fenológicas de Senna cana (Nees & Mart.) H.S. Irwin & Barneby (Leguminosae: Caesalpinioideae) como mecanismo eficiente para atração de polinizadores. Acta Botanica Brasilica 26: 435-443.; Souza & Funch 2016Souza IM, Funch LS. 2016. Synchronization of leafing and reproductive phenological events in Hymenaea L. species (Leguminosae, Caesalpinioideae): the role of photoperiod as the trigger. Brazilian Journal of Botany 40: 125-136.). The mountains at the eastern edge of the Chapada Diamantina are covered by seasonal submontane forests (Atlantic Forest sensu lato) growing on deep latosols. These forests have experienced profound physical impacts in the last 30 years (Oliveira-Filho & Fontes 2000Oliveira-Filho AT, Fontes MAL. 2000. Patterns of floristic differentiation among Atlantic forests in Southeastern Brazil and the influence of climate. Biotropica 32: 793-810.; Funch et al. 2008Funch LS, Rodal MJN, Funch RR. 2008. Floristic aspects of the forests of the Chapada Diamantina, Bahia, Brazil. In: Thomas W, Briton EG. (eds.) The Atlantic Coastal Forest of Northeastern Brazil. New York, Springer & NYBG Press. p. 193-220.; Couto et al. 2011Couto APL, Funch LS, Conceição AA. 2011. Composição florística e fisionomia de floresta estacional semidecídua submontana na Chapada Diamantina, Bahia, Brasil. Rodriguésia 61: 391-405.; Couto-Santos et al. 2015Couto-Santos APL, Conceição AA, Funch LS. 2015. The role of temporal scale in linear edge effects on a submontane Atlantic forest arboreal community. Acta Botanica Brasilica 29: 190-197.), including the installation of electrical transmission lines. Clearing during these installations has created extensive linear edges and caused strong impacts on the local floristic composition and on the abundances of arboreal species, including Eschweilera tetrapetala(Lecythidaceae), which has been found to be more abundant in the forest interior than along artificial edges (Couto-Santos et al. 2015Couto-Santos APL, Conceição AA, Funch LS. 2015. The role of temporal scale in linear edge effects on a submontane Atlantic forest arboreal community. Acta Botanica Brasilica 29: 190-197.).

The overall distribution of E. tetrapetala is quite restricted, being endemic to the forests on the eastern slopes of the Chapada Diamantina mountain range (Funch et al. 2008Funch LS, Rodal MJN, Funch RR. 2008. Floristic aspects of the forests of the Chapada Diamantina, Bahia, Brazil. In: Thomas W, Briton EG. (eds.) The Atlantic Coastal Forest of Northeastern Brazil. New York, Springer & NYBG Press. p. 193-220.; Couto et al. 2011Couto APL, Funch LS, Conceição AA. 2011. Composição florística e fisionomia de floresta estacional semidecídua submontana na Chapada Diamantina, Bahia, Brasil. Rodriguésia 61: 391-405.). Its conservation status is vulnerable (IUCN 2014IUCN. 2014. The IUCN Red list of threatened species. Version 2014.3. http://www.iucnredlist.org. 21 Feb. 2016.
http://www.iucnredlist.org... ) and negatively impacted mainly by deforestation (CNCFLORA 2012CNFLORA - Centro Nacional de Conservação da Flora. 2012. Eschweilera tetrapetala -Avaliação do risco de extinção. http://cncflora.jbrj.gov.br/portal/pt-br/profile/Eschweilera%20tetrapetala. 21 Jan. 2016.
http://cncflora.jbrj.gov.br/portal/pt-br... ). Menezes (2017Menezes IS. 2017. Fenologia, biologia floral e distribuição espacial de Eschweilera tetrapetala Mori (Lecythidaceae) em Florestas Estacionais Submontanas, Chapada Diamantina-BA. MSc Thesis, Universidade Estadual de Feira de Santana, Feira de Santana.) observed that variables related to rainfall are the predictors that most contribute to the construction of models regarding the potential distribution of E. tetrapetala, with projected reductions of 75 % of areas climatically adequate for its growth by 2100. This projected reduction will be caused by temperature increases and rainfall reductions in northeastern Brazil, with consequent retractions of forested areas, including Atlantic Forest remnants (Torres & Marengo 2012Torres RR, Marengo JA. 2013. Uncertainty assessments of climate change projections over South America. Theoretical and Applied Climatology 112: 253-272.; Colombo & Joly 2010Colombo AF, Joly CA. 2010. Brazilian Atlantic Forest lato sensu: the most ancient Brazilian forest, and a biodiversity hotspot, is highly threatened by climate change. Brazilian Journal of Biology 70: 697-708. ).

Numerous species of the Lecythidaceae occur in seasonal environments with well-defined dry and rainy seasons, with flowering occurring in the driest season and fruiting at the beginning of the period with the highest rainfall (Mori 1988Mori SA. 1988. Biologia da polinização em Lecythidaceae. Acta Botanica Brasilica 1: 121-124.). This phenological reproductive pattern has been observed in E. ovata (Krause 2008Krause L. 2008. Floral biology, flowering phenology and floral visitors of five insect-pollinated tree species in a tropical lowland rainforest remnant of Pernambuco, Brazil. PhD Thesis, Ulm Universitat, Ulm.), but not in Eschweilera tenuifolia (Maia & Piedade 2000Maia LA, Piedade MTF. 2000. Phenology of Eschweilera tenuifolia (Lecythidaceae) in flooded forest of the Central Amazonia - Brazil. In: German-Brazilian Workshop on Neotropical Ecosystems, Achievements and Prospects of Cooperative Research. Session 4: Living Resources Management: Approaches, Techniques, Variability. Hamburg, GKSS-Geesthacht. ). The genus Eschweilera is considered hyperdominant and requires specific habitat characteristics (Steege et al. 2013Steege H, Pitman N, Sabatier D, et al. 2013. Hyper-dominance in the Amazonian tree flora. Science 342: 325-335.). Its pollination is associated with large bees, following the general pattern of the family (Prance 1976Prance GT. 1976. The Pollination and Androphore Structure of Some Amazonian Lecythidaceae. Biotropica 8: 235-241.; Potascheff et al. 2013Potascheff CM, Mori SA, Lombardi JA. 2013. Pollination ecology of the Cerrado species Eschweilera nana (Lecythidaceae subfam. Lecythidoideae). Brittonia 66: 191-206.).

In light of the restricted distribution of E. tetrapetala in seasonal submontane forests along the eastern edge of the Chapada Diamantina, where different population densities are known to occur along forest edges and in the forest interior (Couto-Santos et al. 2015Couto-Santos APL, Conceição AA, Funch LS. 2015. The role of temporal scale in linear edge effects on a submontane Atlantic forest arboreal community. Acta Botanica Brasilica 29: 190-197.), and where variables related to precipitation are the main predictors contributing to models of its potential distribution (Menezes, 2017Menezes IS. 2017. Fenologia, biologia floral e distribuição espacial de Eschweilera tetrapetala Mori (Lecythidaceae) em Florestas Estacionais Submontanas, Chapada Diamantina-BA. MSc Thesis, Universidade Estadual de Feira de Santana, Feira de Santana.), we investigated the reproductive phenology E. tetrapetala and its floral visitors to address the following questions: i) Are the flowering and fruiting phenophases of E. tetrapetala associated with environmental factors? ii) Are there differences in the reproductive phenologies of individuals growing in the forest interior and along the forest edge? iii) If such differences exist, do they affect fruit set in interior and edge sites? iv) Are there variations in the species richness of floral visitors to E. tetrapetala plants between interior and edge environments? v) Are there reproductive phenological variations associated with El Niño, as rainfall variations associated with that phenomenon are known to have important roles in regulating phenological rhythms (Wright & Calderon 2006Wright SJ, Calderon O. 2006. Seasonal, El Niño and longer term changes in flower and seed production in a moist tropical forest. Ecology Letters 9: 35-44.)? Our main hypothesis was that the reproductive phenology of E. tetrapetala would be affected by inter-annual variations in rainfall related to the El Niño phenomenon and by forest edge-interior environmental contexts. Additionally, we hypothesize that the edge context would negatively affect the richness of floral visitors of E. tetrapetala.

Materials and methods

Study area and the target species

The present study was undertaken in an area of seasonal submontane forest in the municipality of Lençóis (12º28’31”S 41º23’14’’W), in the Chapada Diamantina National Park, Bahia State, Brazil. The region has a tropical climate (type Aw by the Köppen system), with a rainy season concentrated in the Austral summer (between December and April), and a dry winter season (between July and August). The mean monthly precipitation generally varies between 35 mm (July and August) and 184 mm (December), with the mean annual precipitation varying between 700 and 1300 mm. Mean monthly temperatures vary between 18 ºC (April to September) and 22 ºC (October to February) (Azevedo & Silva 2000Azevedo PV, Silva GB. 2000. Potencial agroclimático da região da Chapada Diamantina, no estado da Bahia. Revista Brasileira de Meteorologia 15: 77- 88. ; Alvares et al. 2014Alvares CL, Stape JL, Stelhas PC, Gonsalves JLM, Sparovek G . 2014. Köpen’s climate classification map for Brazil. Meteorologische Zeitschrift 22: 711-728.). Climatic data of total monthly precipitation, mean monthly temperatures, mean monthly relative humidity of the air, mean monthly solar radiation, and mean monthly photoperiod (Fig. 1A-D) were obtained from the INMET (2017)INMET - Instituto Nacional de Meteorologia. 2017. http://www.inmet.gov.br/. 2 Jan. 2017.
http://www.inmet.gov.br/... database of the Lençóis-BA weather station (12°27'36"S 41°22'48"W).

Figure 1
Environmental data from the region near Lençóis, Chapada Diamantina, Brazil. A. Precipitation and Temperature (1962-2016); B. Solar radiation and Photoperiod (1962-2016); C. Precipitation and Humidity (2011-2012); D. Precipitation and Humidity (2015-2016). Sources: Instituto Nacional de Meteorologia, and the Astronomical Applications Department of the U.S. Naval Observatory.

Northeastern Brazil experiences high inter-annual variations in total rainfall, partially due to the El Niño and La Niña meteorological phenomena. El Niño cycles alter the global climate, modifying the rainfall regimes in tropical and semitropical regions, with northeastern Brazil experiencing diminished cloud cover and reduced rainfall (Marengo et al. 2011Marengo JA, Alves LM, Beserra EA, Lacerda FF. 2011. Variabilidade e mudanças climáticas no semiárido brasileiro. In. Recursos hídricos em regiões áridas e semiáridas. Campina Grande, Instituto Nacional do Semiárido. ). During the years 2015 and 2016, the region was affected by a strong El Niño event that initiated in May/2015 and reached its maximum between October/2015 and January/2016, producing scenarios of extreme drought throughout central Bahia State - which was only surpassed in intensity by the El Niño event of 1997/1998 (INMET 2017INMET - Instituto Nacional de Meteorologia. 2017. http://www.inmet.gov.br/. 2 Jan. 2017.
http://www.inmet.gov.br/... ).

Eschweilera tetrapetala Mori is a tree 5 - 20 m tall, with glabrous leaves with entire to slightly serrate leaf margins. The flowers are white and yellow, large and perfumed. The fruits (pyxis type) have oily seeds (Fig. 2A-E). The species is known as "sapucaia" in the Chapada Diamantina; its fruits are used in traditional craft works, and its seeds can be consumed by humans (Mori 1995Mori SA. 1995. Observações sobre as espécies de Lecythidaceae do leste do Brasil. Boletim de Botânica 14: 1-31.; Funch et al. 2004Funch LS, Harley R, Funch R, Giulietti AM, Melo E. 2004. Plantas úteis da Chapada Diamantina. São Carlos, Rima.).

Figure 2
Habitat and observed phenophases of Eschweilera tetrapetala Mori: A. Habitat; B. Inflorescences; C. Flower; D. Immature fruits; E. Mature fruit, during dispersal.

Phenology

Phenological observations were performed on a monthly basis during three periods: the first period extended from January/2011 to December/2011; the second from January/2012 to December/2012; and the third from October/2015 to September/2016 (including the El Niño event). Phenological observations were made within 30 permanent random plots (10 x 10 m; total 0.3 ha) established by Couto-Santos et al. (2015Couto-Santos APL, Conceição AA, Funch LS. 2015. The role of temporal scale in linear edge effects on a submontane Atlantic forest arboreal community. Acta Botanica Brasilica 29: 190-197.), with 15 plots along the forest edge (0-100 m from an electrical line corridor) and 15 plots in the forest interior (>150 m from the edge). Couto-Santos et al. (2015)Couto-Santos APL, Conceição AA, Funch LS. 2015. The role of temporal scale in linear edge effects on a submontane Atlantic forest arboreal community. Acta Botanica Brasilica 29: 190-197. inventoried 55 individuals of E. tetrapetala (DBH≥5.0 cm) in the area. The numbers of individuals observed in the forest interior (n=49) and along the forest edge (n=6) reflected their densities in our study area, with that species being significantly more abundant in the forest interior (Importance Value of 42.3 %; Relative Density 22.5 %) than along the forest edge (Importance Value 6.53 %; Relative Density 2.49 %) (Couto-Santos et al. 2015Couto-Santos APL, Conceição AA, Funch LS. 2015. The role of temporal scale in linear edge effects on a submontane Atlantic forest arboreal community. Acta Botanica Brasilica 29: 190-197.). We chose thirty individuals to follow their phenological events.

The phenophases monitored were: production of floral buds, opened flowers, and immature and mature fruits (Fig. 2B-E). The intensity of each phenophase was estimated by establishing classes from 0 to 4, with 25 % intervals between them, according to the semi-quantitative method of Founier (1974). The phenological patterns were described following Newstrom et al. (1994Newstrom, LE, Frankie GW, Baker HG. 1994. A New Classification for Plant Phenology Based on Flowering Patterns in lowland tropical rain forest trees at La Selva, Costa Rica. Biotropica 26: 141-159.), based on the frequencies and durations of those episodes.

We also counted the total number of fruits produced by each individual of E. tetrapetala on a monthly basis to estimate fruit set.

Floral visitors and potential pollinators

We made focal observations of floral visitors on five individual trees (two along the forest edge and three in the forest interior). The low number of individuals monitored reflected their heights, the low intensity of floral production, and the low flowering synchrony of the population, with few individuals flowering at the same time. Daytime observations were made during 15 minutes per hour, totally 24 hours along the forest edge and 36 hours in the forest interior, in April/2016 and June/2017. We recorded floral visitor behaviors, their contact with reproductive structures, the floral resource consumed, the numbers of flowers visited by each animal, and the durations of the visits.

Any floral visitor landing on a flower was considered a visit. The insects were collected using an insect net and then sacrificed using ethyl acetate vapors. All floral visitors collected were sent to specialists for taxonomic identification, and subsequently mounted in the laboratory and deposited in the Johann Becker Entomology Collection at the Zoology Museum of the State University of Bahia at Feira Santana (MZUEFS). Floral visitors observed in the forest interior could not be collected due to the heights of the trees, but were photographed and/or filmed.

Floral visitors were classified based on the terminology proposed by Inouye (1980Inouye DW. 1980. The terminology of floral larceny. Ecology 61:1251-1253.), following the identification of legitimate or illegitimate visits, as: i) pollinators (legitimate visitors), which demonstrated behavior conducive to effective pollination, including visits to the flowers during their period of pollen availability, and lifting the androecial hood that restricts access to the nectar so that the dorsal portion of the insect touches the stamen whorl and the stigma (Mori et al. 1978Mori SA, Prance GT, Bolten AB. 1978. Additional Notes on the Floral Biology of Neotropical Lecythidaceae. Brittonia 30: 113-130.); ii) thieves (illegitimate visitors), visitors that collected floral resources, without damaging the flowers but without specific pollination behavior; iii) robbers (illegitimate visitors), visitors that damage floral tissues while collecting floral resources, thus reducing the attractiveness of those flowers.

Data analyses

Reproductive phenological intensity and its correlation with environmental variables

The intensity of the reproductive phenologies and their correlations with environmental variables were analyzed using Cross Correlation Analysis to evaluate the lag period between the phenophases studied and the environmental factors considered (photoperiod, temperature, relative humidity of the air, solar radiation, and precipitation). We considered in these analyses only significant results (p<0.05) and those with plausible biological effects. The cross correlation analyses were carried out using free access PAST version 2.17c software (Hammer et al. 2001Hammer Ø, Harper DAT, Ryan DP. 2001. Past: Paleontological statistics software package for education and data analysis. Vol. 4. Harper, Palaeontologia Electronica. ). The Kruskal-Wallis and Wilcoxon signed-rank tests were used to evaluate if there were inter-annual variations in the intensities of the phenological events and if they were repeated in subsequent years (Zar 2010Zar JH. 2010. Biostatistical analysis. 5th. edn. Upper Saddle River, Pearson Prentice-Hall.; Morellato et al. 2010Morellato LPC, Alberti LF, Hudson IL. 2010. Applications of circular statistics in plant phenology: a case studies approach. In: Keatley M, Hudson IL. (eds.) Phenological research: methods for environmental and climate change analysis. New York, Springer. p. 357-371.). The Kruskal-Wallis tests were performed using BioEstat 5.3 software (Ayres et al. 2007Ayres M, Ayres JRM, Ayres DL, Santos AAS. 2007. Bioestat: aplicações estatísticas nas áreas das ciências bio-médicas. Belém, Sociedade Civil Mamirauá. ). Spearman correlations (r _s) were performed using R software, version 3.2.3, (R Core Team 2014R Core Team. 2014. R: a language and environment for statistical computing. Vienna, R Foundation for Statistical Computing.).

Seasonality

The seasonality of the phenological data (flowering and fruiting) was analyzed based on circular statistics, in which the months of the year were converted into 30° angle intervals (Morellato et al. 2010Morellato LPC, Alberti LF, Hudson IL. 2010. Applications of circular statistics in plant phenology: a case studies approach. In: Keatley M, Hudson IL. (eds.) Phenological research: methods for environmental and climate change analysis. New York, Springer. p. 357-371.). For each phenophase, we calculated: (i) the mean angle, which represents the mean date of the phenological activity considered; (ii) the length of the r vector, which reflects aggregation of the dates (event synchrony) as well as the seasonality of the species studied (with high r values [> 0.5] indicating aggregation and therefore the seasonality of the phenological event under consideration); (iii) the Rayleigh test (z) to determine if the dates demonstrated uniform distributions throughout the year (Zar 2010Zar JH. 2010. Biostatistical analysis. 5th. edn. Upper Saddle River, Pearson Prentice-Hall.). The Mardia-Watson-Wheeler (W) test was used to compare the mean dates of each phenophase during the study periods (Batschelet 1981Batschelet E. 1981. Circular Statistics in Biology. New York, Academic Press. ). This latter test is nonparametric (and an alternative to the Watson-Williams (F) test, which is parametric) and compares how similar two or more distributions appear to be, with values of p < 0.05 rejecting the null hypothesis, under the assumption that the sets of dates demonstrate distinct distributions (Zar 2010Zar JH. 2010. Biostatistical analysis. 5th. edn. Upper Saddle River, Pearson Prentice-Hall.). The circular statistical analyses and the Mardia-Watson-Wheeler tests were performed using R software, with the addition of the "circular” package version 3.2.3 (R Core Tean 2014R Core Team. 2014. R: a language and environment for statistical computing. Vienna, R Foundation for Statistical Computing.).

Reproductive phenology and the production of fruits in the forest interior and edge

One-Way ANOVA tests were used to analyze the differences between the numbers of E. tetrapetala individuals that flowered and fructified in the forest edge and in the forest interior, as well as fruit set in both environments.

Floral visitors in the forest edge and interior

The Wilcoxon-Mann-Whitney test was used to analyze the differences in the species richness of floral visitors to E. tetrapetala between the forest edge and forest interior. The Wilcoxon-Mann-Whitney and ANOVA One-Way tests were performed using BioEstat 5.3 software (Ayres et al. 2007Ayres M, Ayres JRM, Ayres DL, Santos AAS. 2007. Bioestat: aplicações estatísticas nas áreas das ciências bio-médicas. Belém, Sociedade Civil Mamirauá. ).

Results

Phenology

In general, the reproductive events of E. tetrapetala were seasonal, with low intensities during all of the observed phases (Fig. 3A-D, Tab. 1). The beginning of flowering changed during the observation period, occurring during the rainy season (between December and January) in the first and second years (2011-2013), and during the transition from the dry to rainy season (between April and July/2016) in the third year (2015-2016), during the occurrence of an El Niño event. This shift was marked by significant inter-annual variations of the mean dates of floral budding and immature and mature fruit stages (Tab. 1; Tab. 2). Significant differences were observed in mean mature fruit production among the different years (W=7.78, p=0.02), varying from August (in the first and second year) to November (in the third year, during the El Niño event) (Tab. 1; Tab. 2). Inter-annual variations were observed in floral budding and immature fruit intensity between the second (2012) and third years (2015-2016), while mature fruit production exhibited inter-annual variations between the first (2011) and third year (Tab. 2).

Figure 3
Reproductive phenology of Eschweilera tetrapetala Mori, in the interior and along the edge of a seasonal submontane forest, in the municipality of Lençóis, Chapada Diamantina, Bahia State, Brazil. A. Floral buds and open flowers (2011-2012); B. Floral buds and open flowers (2015-2016); C. Unripe and ripe fruits (2011-2012); D. Unripe and ripe fruits (2015-2016); E. Set fruit (2011-2012); F. Set fruit (2015-2016). Please see the PDF version for color reference.

During the first and second years, E. tetrapetala fructified only in the forest interior (Fig. 3A). During the third year, within the El Niño event, buds, open flowers and immature fruit production were observed in the edge site, without significant differences between the edge and interior (Tab. 3). Significant differences were observed, however, for fruit set in the edge (n=7) and forest interior (n=27) during the third year (F= 79.78, GL=1, p<0.05).

The flowering and fruiting of E. tetrapetala appeared to be associated with all of the environmental factors analyzed. Flowering demonstrated positive correlations with precipitation, photoperiod, and solar radiation during the first and second years. During the El Niño event, flowering was positively correlated with precipitation and humidity, and negatively correlated with photoperiod and temperature. Fruiting was observed to be positively correlated with precipitation and negatively correlated with temperature, photoperiod, and solar radiation during the first and second years. During the El Niño event, fruiting was positively correlated with humidity and solar radiation, and negatively correlated with temperature and photoperiod (Tab. 4).

Floral visitors and pollinators

Bees and butterflies were observed visiting E. tetrapetala flowers. Xylocopa sp. was observed only in the forest interior, totaling 18 visits. This bee was the only floral visitor classified as a pollinator, as it lifted the androecial hood to collect nectar, and the dorsal portion of its body contacted the reproductive structures of the flower. Xylocopa sp. visits occurred between 07h00min and 11h00min, with durations of approximately 18 seconds each. Individuals of Xylocopa sp. were observed flying above the canopies of E. tetrapetala along the forest edge, but they were not observed visiting their flowers.

Trigona spinipes was observed in large numbers, primarily visiting the flowers of forest edge trees. These bees demonstrated behavior compatible with resource robbers, as they fed on the apical and lateral portions of the androecial hood, opening holes through which they could penetrate into the flowers and forage in their interiors. Visits by Trigona spinipes occurred between 05h00min and 16h00min, and lasted approximately 15 minutes each. Up to six bees were observed visiting a single flower at the same time, showing territorial and antagonistic behaviors in relation to other visitors. The frequencies of floral visits by T. spinipes in the forest interior were lower than along the forest edge, with only a single visit per flower, totaling 16 visits in the interior site and 220 visits along the forest edge.

We observed five species of Lepidoptera visiting the flowers of E. tetrapetala, but only in the forest interior. Those visitors showed thieving behavior, as they landed on the androecial hood, inserted their proboscis into the lateral sides of the androecial hood, and consumed nectar from flowers without contact with the reproductive structures.

The species richness in both environmental contexts were significantly distinct (U= 7, p=0.02), with seven species of floral visitors in the interior but only one along the forest edge.

Discussion

We investigated whether there were shifts in the reproductive phenology of E. tetrapetala associated with seasonality and the edge-interior contexts in a seasonal submontane forest in the Chapada Diamantina Mountains in northeastern Brazil. Additionally, we sought to verify if there were variations in the species richness of floral visitors to E. tetrapetala between the two environmental contexts. In agreement with our hypothesis, we found that the intensities of the reproductive events of E. tetrapetala were affected principally by inter-annual variations in rainfall related to the El Niño phenomenon. We also observed that the edge context affected flowering and fruiting intensity, fruit production, and the richness of floral visitors to E. tetrapetala. Our results highlight the relevance of rainfall seasonality in controlling phenological changes in E. tetrapetala. We also noted that differences in local conditions (forest edge and interior) can be important in determining the temporal patterns of E. tetrapetala and floral visits.

The phenological seasonality observed in E. tetrapetala was similar to that of other Lecythidaceae species such as Eschweilera tenuifolia(Maia & Piedade 2000Maia LA, Piedade MTF. 2000. Phenology of Eschweilera tenuifolia (Lecythidaceae) in flooded forest of the Central Amazonia - Brazil. In: German-Brazilian Workshop on Neotropical Ecosystems, Achievements and Prospects of Cooperative Research. Session 4: Living Resources Management: Approaches, Techniques, Variability. Hamburg, GKSS-Geesthacht. ), Bertholletia excelsa (Tonini 2011Tonini H. 2011. Fenologia da castanheira-do-brasil (Bertholletia excelsaHumb. Bonpl., Lecythidaceae) no sul do estado de Roraima. Cerne 17: 123-131.), and Lecythis poiteaui (Freitas et al. 2015Freitas JL, Silva RBL, Cruz-Júnior FO, Barbosa-Filho MN, Cantuária PC. 2015. Fenologia reprodutiva de cinco espécies arbóreas em ecossistema de terra firme na Amazônia Brasileira. Biota Amazônia 5: 38-44.). The pattern described by Mori (1988Mori SA. 1988. Biologia da polinização em Lecythidaceae. Acta Botanica Brasilica 1: 121-124.) for the Lecythidaceae, with flowering occurring during the dry season and fruiting at the beginning of the rainy season, was not observed in E. tetrapetala.

The inter-annual variations in the mean dates of flowering initiation and fruit maturation observed in E. tetrapetala were demonstrated by the Mardia-Watson-Wheeler test (W), possibly associated with climatic oscillations resulting from El Niño events during the third study period. Events associated with the El Niño phenomenon are a major source of climatic variation in the tropics, provoking long droughts, decreased cloud cover, as well as increases in solar radiation and environmental temperatures (Malhi & Wright 2004Malhi Y, Wright J. 2004. Spatial patterns and recent trends in the climate of tropical rainforest regions. Philosophical Transactions of the Royal Society B 359: 311-329.). Monitoring flower and seed production during annual cycles could help us to better understand the effects of climatic variations on plant reproduction, as the reproduction rates of many species accompany those inter-annual climatic variations and respond to El Niño/La Niña oscillations (Wright & Calderon 2006Wright SJ, Calderon O. 2006. Seasonal, El Niño and longer term changes in flower and seed production in a moist tropical forest. Ecology Letters 9: 35-44.). In the first and second years of the study, the flowering of E. tetrapetala occurred during the rainy season. In the third year, however, the El Niño phenomenon resulted in a long drought that extended from the beginning of 2015 until the beginning of 2016 (INMET 2017INMET - Instituto Nacional de Meteorologia. 2017. http://www.inmet.gov.br/. 2 Jan. 2017.
http://www.inmet.gov.br/... ), apparently delaying flowering in E. tetrapetala, which occurred then during the transition from the rainy to the dry season.

The inter-annual variations in flowering and fruiting in E. tetrapetala were correlated with most of the environmental predictors analyzed, especially precipitation. As in many tropical species that produce flowers coinciding with increases in solar radiation, temperature, and photoperiod (Bhat 1992Bhat DM. 1992. Phenology of tree species of tropical moist forest of Uttara Kannada District, Karnataka, India. Journal of Biosciences 17: 325-352. ; Wright & Schaik 1994Wright SJ, Schaik CP. 1994. Light and the phenology of tropical trees. The American Naturalist 143: 192-199.; Talora & Morellato 2000Talora DC, Morellato PC. 2000. Fenologia de espécies arbóreas em floresta de planície litorânea do sudeste do Brasil. Revista Brasileira de Botânica 23: 13-26. ; Marchioretto et al. 2007Marchioretto MA, Mauhs J, Budke JC. 2007. Fenologia de espécies arbóreas zoocóricas em uma floresta psamófila no sul do Brasil. Acta Botanica Brasilica 21: 193-201.), E. tetrapetala flowering showed correlations with solar radiation and photoperiod in some study years, but not with temperature. E. tetrapetala altered its flowering period to accompany rainfall oscillations provoked by the El Niño phenomenon.

Tropical species can maintain their floral buds in a quiescent state during periods of water stress but, after rehydration at the start of the rainy season, those buds expand and enter into anthesis (Borchert et al. 2004Borchert R, Meyer SA, Felger RS, Porter-Bolland L. 2004. Environmental control of flowering periodicity in Costa Rican and Mexican tropical dry forests. Global Ecology and Biogeography 13: 409-425.). As such, the availability of water resources appears to be a preponderant factor for determining the reproductive phenology of E. tetrapetala, as flowering was consistently found to occur after high rainfall in the study area. This observation was supported by cross correlation analyses, which demonstrated that flowering was associated with increases in precipitation and/or humidity.

Changes in the reproductive phenologies of plants can result in the temporal asynchrony of plant-pollinator interactions, with plant species flowering when pollinator activities have already concluded, or not yet initiated (Bartomeus et al. 2011Bartomeus I, Ascherb JS, Wagnerc D, et al. 2011. Climate-associated phonological advances in bee pollinators and bee-pollinated plants. Proceedings of the National Academy of Sciences 108: 20645-20649. ; Forrest 2015Forrest JRK. 2015. Plant - pollinator interactions and phenological change: what can we learn about climate impacts from experiments and observations? Oikos 124: 4-13.). Such asynchrony can negatively affect plant and/or animal populations, reducing resource availability for animals and/or reducing the reproductive potentials of plants (Rusterholz & Erhardt 1998Rusterholz HP, Erhardt A. 1998. Effects of elevated CO2 on flowering phenology and nectar production of nectar plants important for butterflies of calcareous grasslands. Oecologia 113: 341-49.; Kudo et al. 2004Kudo G, Nishikawa Y, Kasagi T, Kosuge S. 2004. Does seed production of spring ephemerals decrease when spring comes early? Ecological Research 19: 255-259.; Thomsom 2010Thomson JD. 2010. Flowering phenology, fruiting success, and progressive deterioration of pollination in an early-flowering geophyte. Philosophical Transactions of the Royal Society B 365: 3187- 3199.). Longer observation periods will be required to better define the interactions between abiotic and biotic factors, although Wright & Calderon (2006Wright SJ, Calderon O. 2006. Seasonal, El Niño and longer term changes in flower and seed production in a moist tropical forest. Ecology Letters 9: 35-44.) noted that any reported relationships between El Niño/La Niña oscillations and living organisms will contribute to our understanding of directional changes in the dynamics of tropical forest species and their responses to climatic and anthropogenic alterations.

The linear edge negatively affected the population density of E. tetrapetala and its reproductive events, as the individuals in that context were not observed flowering during the first two study years, and produced reduced numbers of fruits in the third study period in relation to the forest interior. Numerous studies have demonstrated that edge effects reduce the availability of abiotic resources such as water and soil nutrients (Dunley et al. 2009Dunley B, Freitas L, Galetto L. 2009. Reproduction of Byrsonima sericea (Malpighiaceae) in resting fragmented habitats in Southeastern Brazil. Biotropica 41: 692-699.; Athayde & Morellato 2014Athayde EA, Morellato LPC. 2014. Anthropogenic edges, isolation and the flowering time and fruit set of Anadenanthera peregrina, a cerrado savanna tree. International Journal of Biometeorology 58: 443-454.; Aizen & Feinsinger 1994Aizen MA, Feinsinger P. 1994. Habitat fragmentation, native insect pollinators, and feral honey bee in Argentine ‘Chaco Serrano’. Ecological Applications 4: 378-392.; Franceschinelli et al. 2015Franceschinelli EV, Carmo RM, Silva Neto CM, Gonçalves BB, Bergamin LL. 2015. Reproductive success ofCabralea canjerana(Meliaceae) in Atlantic forest fragments, Brazil. Revista de Biologia Tropical 63: 515-524. ), and diminish fruit set as compared to that seen in the forest interior (Dunley et al. 2009Dunley B, Freitas L, Galetto L. 2009. Reproduction of Byrsonima sericea (Malpighiaceae) in resting fragmented habitats in Southeastern Brazil. Biotropica 41: 692-699.; Athayde & Morellato 2014Athayde EA, Morellato LPC. 2014. Anthropogenic edges, isolation and the flowering time and fruit set of Anadenanthera peregrina, a cerrado savanna tree. International Journal of Biometeorology 58: 443-454.).

Edge effects were also noticeable in terms of the richness of floral visitors to E. tetrapetala. Among the floral visitors of E. tetrapetala, Xylocopa sp. was the only insect classified as an effective pollinator, even though it showed a low visitation frequency and was not observed visiting individuals near the forest edge. Xylocopa sp. has been identified as a potential pollinator of other species of Eschweilera (Krause 2008Krause L. 2008. Floral biology, flowering phenology and floral visitors of five insect-pollinated tree species in a tropical lowland rainforest remnant of Pernambuco, Brazil. PhD Thesis, Ulm Universitat, Ulm.; Potascheff et al. 2013Potascheff CM, Mori SA, Lombardi JA. 2013. Pollination ecology of the Cerrado species Eschweilera nana (Lecythidaceae subfam. Lecythidoideae). Brittonia 66: 191-206.) and of other genera of Lecythidaceae (e.g., Couropita guianensis and Lecythis lurida (Mori et al. 1978Mori SA, Prance GT, Bolten AB. 1978. Additional Notes on the Floral Biology of Neotropical Lecythidaceae. Brittonia 30: 113-130.; Ormond et al. 1981Ormond WT, Pinheiro MCB, Castells ARC.1981. A contribution to the floral biology and reproductive system of Couroupita guianensis Aubl. (Lecythidaceae). Annals of Missouri Botanical Garden 68: 514-523.)). Pollination by bees is widely observed in Lecythidaceae (Knudsen & Mori 1996Knudsen JT, Mori SA. 1996. Floral scents and pollination in Neotropical Lecythidaceae. Biotropica 28: 42-60.), and most studies of the genus Eschweilera have reported pollination by Hymenoptera (Prance 1976Prance GT. 1976. The Pollination and Androphore Structure of Some Amazonian Lecythidaceae. Biotropica 8: 235-241.; Mori et al. 1978Mori SA, Prance GT, Bolten AB. 1978. Additional Notes on the Floral Biology of Neotropical Lecythidaceae. Brittonia 30: 113-130.; Gamboa-Gaitán 1997Gamboa-Gaitán MA. 1997. Biologia reproductiva de Eschweilera bogotensis (Lecythidaceae), en la Cordillera Occidental de Colombia. Caldasia 19: 479-485.; Krause 2008Krause L. 2008. Floral biology, flowering phenology and floral visitors of five insect-pollinated tree species in a tropical lowland rainforest remnant of Pernambuco, Brazil. PhD Thesis, Ulm Universitat, Ulm.; Potascheff et al. 2013Potascheff CM, Mori SA, Lombardi JA. 2013. Pollination ecology of the Cerrado species Eschweilera nana (Lecythidaceae subfam. Lecythidoideae). Brittonia 66: 191-206.). According to Mori & Prance (1981)Mori SA, Prance GT. 1981. Relações entre a classificação genérica de Lecythidaceae do Novo Mundo e seus polinizadores e dispersadores. Revista Brasileira de Botânica 4: 31 -37., bees of the Euglossinae group that have long glossa and are able to reach the nectar in the coiled hood (e.g., E. grandiflora and E. decolorans), but they were not observed visiting Eschweilera tetrapetala.

The territorial behavior of Trigona species represents a very common defense strategy among social insects (Nieh et al. 2005Nieh JC, Kruizinga K, Barreto LS, Contrera FAL, Imperatriz-Fonseca VL. 2005. Effect of grupe size on the aggression strategy of an extirpating stingless bee, Trigona spinipes. Insectes Sociaux 52: 147-154.) and has been reported in other studies involving species of Lecythidaceae (Santos & Absy 2010Santos CF, Absy ML. 2010. Polinizadores de Bertholletia excelsa (Lecythidales: Lecythidaceae): interações com abelhas sem ferrão (Apidae: Meliponini) e nicho trófico. Neotropical Entomology 39: 854-861.; Potascheff et al. 2013Potascheff CM, Mori SA, Lombardi JA. 2013. Pollination ecology of the Cerrado species Eschweilera nana (Lecythidaceae subfam. Lecythidoideae). Brittonia 66: 191-206.) as well as other tropical families (in which those bees were classified as robbers) (Roubik 1982Roubik DW. 1982. Obligate necrophagy in a social bee. Science 217: 1059-1060.). Interestingly, resource pillaging by melipona bees, as well as their aggressive behavior, have both been evaluated as positive factors in some studies. Decreasing resources offered to pollinators force them to visit more flowers to obtain their required energetic resources, enhancing the chances of cross pollination (e.g., Malloof & Inouye 2000Maloof JE, Inouye D. 2000. Are nectar robbers cheaters or mutualists? Ecology 81: 2651-2661. ; Silva et al. 2014Silva CI, Marchi P, Aleixo KP, et al. 2014. Manejo dos polinizadores e polinização de flores do maracujazeiro. 1st. edn. São Paulo, Instituto de Estudos Avançados da Universidade de São Paulo / Ministério do Meio Ambiente. ). We observed aggressive behavior by T. spinipes bees only at the forest edge, which may explain why Xylocopa sp. was not observed visiting flowers in that environment context. The frequency of T. spinipes diminished significantly in the forest interior, favoring the presence of the effective pollinator Xylocopa sp.

During the third study period, when E. tetrapetala flowered and fructified both at the forest edge and in its interior, there were significant differences in fruit production between those two contexts. The reduced fruit production observed at the forest edge may be associated with the absence of effective pollinators in that context. The observed differences in floral visitor frequencies and behaviors may alter the quality and quantities of pollen grains deposited on the stigmas and, consequently, fruit and seed production (Rathcke & Jules 1993Rathcke BJ, Jules ES. 1993. Habitat fragmentation and plant pollinator interactions. Current Science (Bangalore) 65: 273-277.). Additionally, most studies of the reproductive systems of Lecythidaceae have reported self-incompatible species, and without the presence of pollinators there would be no cross pollination and consequently little or no fruit formation (Moritz 1984Moritz A. 1984. Estudos biológicos da floração e da frutificação da castanha-do-Brasil (Bertholletia excelsa H. B. K.). Embrapa-CPATU 29: 1-82.; Lepsch-Cunha & Mori 1999Lepsch-Cunha N, Mori SA. 1999. Reproductive phenology and mating potential in a low density tree population of Couratari multiflora (Lecythidaceae) in central Amazonia. Journal of Tropical Ecology 15: 97-121.; Gusson et al. 2006Gusson E, Sebbenn AM, Kageyama PY. 2006. Sistema de reprodução em populações de Eschweilera ovata (Cambess.) Miers. Árvore 30: 491-502.; Mori & Kallunki 1976Mori SA, Kallunki JA. 1976. Phenology and floral biology of Gustavia superba (Lecythidaceae) in Central Panama. Biotropica 8: 184-92.; Potascheff et al. 2013Potascheff CM, Mori SA, Lombardi JA. 2013. Pollination ecology of the Cerrado species Eschweilera nana (Lecythidaceae subfam. Lecythidoideae). Brittonia 66: 191-206.). Although low fruit set has previously been noted in the Lecythidaceae family (Potascheff et al. 2013Potascheff CM, Mori SA, Lombardi JA. 2013. Pollination ecology of the Cerrado species Eschweilera nana (Lecythidaceae subfam. Lecythidoideae). Brittonia 66: 191-206.), fruit set by E. tetrapetala was even lower at the edge than in the interior.

Eschweilera tetrapetala is more abundant in the submontane forest interior (Couto-Santos et al. 2015Couto-Santos APL, Conceição AA, Funch LS. 2015. The role of temporal scale in linear edge effects on a submontane Atlantic forest arboreal community. Acta Botanica Brasilica 29: 190-197.), providing evidence that it is quite sensitive to niche alterations. It is important to note that, like most of the taxa of Lecythidaceae, E. tetrapetala requires insect pollinators for cross pollination and fruit set (Moritz 1984Moritz A. 1984. Estudos biológicos da floração e da frutificação da castanha-do-Brasil (Bertholletia excelsa H. B. K.). Embrapa-CPATU 29: 1-82.; Lepsch-Cunha & Mori 1999Lepsch-Cunha N, Mori SA. 1999. Reproductive phenology and mating potential in a low density tree population of Couratari multiflora (Lecythidaceae) in central Amazonia. Journal of Tropical Ecology 15: 97-121.; Gusson et al. 2006Gusson E, Sebbenn AM, Kageyama PY. 2006. Sistema de reprodução em populações de Eschweilera ovata (Cambess.) Miers. Árvore 30: 491-502.; Mori & Kallunki 1976Mori SA, Kallunki JA. 1976. Phenology and floral biology of Gustavia superba (Lecythidaceae) in Central Panama. Biotropica 8: 184-92.; Potascheff et al. 2013Potascheff CM, Mori SA, Lombardi JA. 2013. Pollination ecology of the Cerrado species Eschweilera nana (Lecythidaceae subfam. Lecythidoideae). Brittonia 66: 191-206.). Decreases in successful reproduction in fragmented forest environments have been associated with decreases in the qualities and quantities of pollinators found there (Aguillar & Galleto 2004Aguilar R, Galetto L. 2004. Effects of forest fragmentation on male and female reproductive success in Cestrum parqui (Solanaceae). Oecologia 138: 513-520.). Similar results were observed with Cabralea canjerana (Meliaceae), which was visited by fewer pollinators, and demonstrated limited reproductive success in forest fragments when compared to continuous areas of Atlantic Forest (Franceschinelli et al. 2015Franceschinelli EV, Carmo RM, Silva Neto CM, Gonçalves BB, Bergamin LL. 2015. Reproductive success ofCabralea canjerana(Meliaceae) in Atlantic forest fragments, Brazil. Revista de Biologia Tropical 63: 515-524. ).

In conclusion, we confirmed our general hypotheses that E. tetrapetala demonstrated inter-annual variations in the intensity and seasonality of flowering and fruit production, possibly linked to climatic alterations due to El Niño-provoked rainfall variations during the study period. We also observed that flowering and fruiting were more intense in the forest interior. Additionally, our study demonstrated how climatic changes (due to El Niño) and anthropogenic alterations (in this case related to edge creation) can influence both resource robbers and pollinators. Our study complemented existing knowledge of the reproductive phenology of Lecythidaceae and its floral visitors, and contributed to our understanding of the relative importance of two sources of variability (El Niño and edge effects) to the reproductive phenology of tropical plants.

Acknowledgements

The authors would like to thank the Coordenação de Aperfeiçoamento de Pessoal do Nível Superior (CAPES) for the grant awarded to the first author; Isys Mascarenhas Souza for her suggestions and help with the fieldwork; Favizia Freitas de Oliveira for identifying the Hymenoptera; Thamara Zacca for identifying the Lepidoptera; and the Fundação da Chapada Diamantina for the use of their lodging infrastructure and assistance with the fieldwork.

References

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