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Revista de Biología Tropical

On-line version ISSN 0034-7744Print version ISSN 0034-7744

Rev. biol. trop vol.61 n.2 San José Jun. 2013

 

Distribution of bioluminescent fungi across old-growth and secondary tropical rain forest in Costa Rica

Carolina Seas-Carvajal1*  & Gerardo Avalos1,2*

*Dirección para correspondencia:


Abstract

Most research on bioluminescent fungi is concentrated on their taxonomic relationships, while the basics of their natural history and ecological relationships are poorly understood. In this study, we compared the distribution of bioluminescent fungi between old-growth and secondary forest as related to four different soil types at the tropical rainforest of La Selva Biological Station in Costa Rica. The study was conducted during the wet season of 2009. Bioluminescent fungi were sought following eight different transects distributed evenly in old-growth and secondary forests across four different soil types, covering an area of 9 420m2. We found fungi in four different substrates: litter, fallen branches, dead trunks, and roots, for a total of 61 samples. Correspondence analysis showed that the occurrence of fungi and soil types were related (inertia=0.21, p=0.071). We found a significant relationship between the presence of fungi and the distribution of soil types (X2=18.89, df=9, p=0.026). We found only three samples with fruiting bodies, two of which had Mycena and the other had one fungus of the order Xylariales (possibly Hypoxylon sp., Kretzschmariella sp., Xylaria sp.). Future work will concentrate on exploring other aspects of their ecology, such as their dispersal and substrate preference. This information will facilitate field identification and will foster more research on the distribution, seasonality, reproductive phenology and ecological requirements of this group of Fungi.

Key words: bioluminescence fungi, Costa Rica, La Selva, Mycena, tropical rain forest.

Resumen

La mayoría de las investigaciones sobre los hongos bioluminiscentes se ha centrado en relaciones taxonómicas. Los aspectos básicos de la historia natural y relaciones ecológicas de este grupo son poco conocidos. En este estudio, comparamos la distribución de  hongos bioluminiscentes entre el bosque  primario y el secundario en la Estación Biológica La Selva, Costa Rica en relación con cuatro tipos de suelo. El estudio se realizó durante la estación lluviosa del 2009. Se  buscaron hongos bioluminiscentes en ocho transectos distribuidos de manera uniforme  en  el bosque primario y secundario y en cuatro tipos de suelo, cubriendo un área de 9 420m2. Se encontraron hongos en cuatro sustratos: arena, ramas caídas, troncos muertos, y raíces muertas, para un total de 61 muestras. Se encontró una relación significativa entre la presencia de hongos y la distribución de los  tipos de suelo (x2=18.89,  gl=9, p=0.026). Sólo  se encontraron tres muestras con cuerpos fructíferos, dos de ellos del género Mycena, mientras que el otro presentaba un hongo del  orden Xylariales (posiblemente Hypoxylon sp.  Kretzschmariella  sp.  Xylaria  sp.).  Futuras  líneas  de investigación deben concentrarse en aspectos básicos de la ecología del grupo, tales como su dispersión y preferencia de sustrato. Esta información fomentará una mayor investigación sobre la distribución, la estacionalidad y fenología reproductiva, y los requerimientos ecológicos de este grupo de hongos.

Palabras clave: bioluminiscencia, bosque tropical lluvioso, Costa Rica, hongos, La Selva, Mycena.



Bioluminescent organisms are diverse and extensively distributed among many groups including bacteria, dinoflagellates, insects and fungi. Bioluminescence refers to the emission of visible light by living organisms mediated by an enzyme-catalyzed (luciferase) reaction of oxygen with a substrate (luciferin). Luciferases do not show homology relative to each other; and luciferins are chemically and phylogenetically unrelated (Weitz 2004). Molecular oxygen is the only common feature of bioluminescent reactions, showing that luminescent systems in most organisms may have evolved independently (Wilson & Hastings 1998).

Many reasons for the role of bioluminescence in fungi have been suggested. Some of these hypotheses suggest that luminescence helps to attract invertebrates to assist in spore dispersal (Sivinski 1981, 1998). Other hypotheses suggest that bioluminescence excludes negatively phototropic fungivores, or can even work as a warning signal to nocturnal fungivores (Sivinski 1998). Tentative explanations indicate that bioluminescence is a by-product of a biochemical reaction, and that it has no ecological role (Weitz 2004). There is only limited evidence in support of each of these hypotheses, due to the paucity of actual field evidence (Weitz 2004).

Luminous fungi belong to the phylum Basidiomycota, and are found in tropical as well  as  temperate  climates,  always  associated with hydrated substrates, with the possible exception of the ascomycete Xylaria hypoxylon (Foerster et al. 1965). They emit a greenish, cold light with a maximum intensity of 520-530nm (O’Kane et al. 1990). It is not known whether the biochemistry of bioluminescence in fungi is the same as in other bioluminescent groups, such as bacteria, unicellular algae, coelenterates, beetles, fishes and others (Wilson & Hastings 1998).

Relatively little research has been conducted on bioluminescent fungi. There are currently more than 64 species in three distinct lineages: Ompholatus, Armillaria and mycenoid (Desjardin et al. 2008). Examples of luminescent mushrooms include Armillaria mellea, Mycena citricolor and Omphalotus olearius. Panellus stipticus is unusual in that luminescence is exhibited only by the North American strains and not by the Eurasian ones (Peterson & Bermudes 1992). Luminescence may occur in both mycelia and fruiting bodies, like in P. stipticus and O. olearius; or only in mycelia and young rhizomorphs, as in A. mellea (Herring 1994 in Weitz 2004). However, there have been very few ecological studies of bioluminescent fungi, and no examination of their distribution and substrate requirements across different habitat types in tropical regions. Only a few studies of bioluminescent fungi have been carried out in the tropics. One study in Panama examined how bioluminescence characteristics were affected by temperature, humidity, and exposure to light, but the species was not identified (Deheyn 2007). A group of researchers in Brazil recently discovered a new species of bioluminescent fungus of the genus Gerronema (Desjardin et al. 2005), and are in the process of describing several others species (Desjardin et al. 2007, Capelari et al. 2011). Our study aims to add to this growing body of knowledge by comparing the distribution of bioluminescent fungi across successional  and  soil  gradients  considering old-growth and secondary forests and four different soil types. Understanding the physical conditions that affect the distribution and abundance of bioluminescent fungi will provide insights for determining the role that these organisms play across successional stages.

Materials and methods

Study site: The study was conducted during the wet season (June-August) of 2009 at La Selva Biological Station (10°26’ N - 83°59’ W), Sarapiquí, Heredia, Costa Rica. La Selva comprises 1 600ha of tropical wet forests, with an annual rainfall and temperature average of 3 800mm and 26°C, respectively (not a single month receives less than 100mm; McDade & Hartshorn 1994). Altitude varies from approximately 30m to 150m (Matlock & Hartshorn 1999).  The  landscape  is  of  volcanic  origin, and the topography varies from flat, alluvial terraces to moderately undulating hills derived from Pleistocene lava flows (McDade & Hartshorn 1994). The soils are deep inceptisols, and despite their young age, are generally rock-free and fairly rich in organic matter (Lieberman & Lieberman 1987).

Collection of fungal samples: Mycelia of bioluminescent fungi were collected by hand at night along eight 325m long transects, distributed evenly in old-growth and secondary forests taking into account four different soil types: Andic Humitropept (AH), Typic Tropohumult (TT), Typic Humitropept (TH) and Andic Dystropept  (AD)  according  to  the  original  version  of  Soil  Taxonomy  (USDA Soil  Survey Staff 1975 in Sancho & Mata 1987, McDade & Hartshorn 1994). At every 25m along the transect, we turned off all lights and searched for bioluminescent fungi within a 5m radius. We surveyed each transect 15 times. The fungi were collected from decaying pieces of wood or leaves showing bright bioluminescence and then were placed in clean wax paper envelopes.

We also surveyed each of the transects twice during the day to search for fruiting bodies,  once  in  the  morning  following  the night survey, and again three days later. When fruiting bodies were found, the samples were placed in clean wax paper envelopes and taken to a dark room to confirm the presence of bioluminescence.  Species  were  described  using the diagnostic features of their fruiting bodies, considering traits such as the pileus, context, lamellae and stipe among other morphological characters (Mueller et al. 2004).

To determine the degree of association between fungal substrates, forest successional stages, and soil type we applied a correspondence analysis. A logistic regression was used to measure the effects of forest and soil type on the probability of belonging to a particular substrate category. All analyses were performed using JMP 7.0 statistical software.

Results

Collection of fungal samples: One hundred and twenty survey points were sampled in the eight transects, 60 per forest type, and 15  per  soil  type,  covering  a  total  area  of  9  420m2. We found fungi only at 21 sampling stations in four different substrates: litter, fallen branches, dead trunks, and roots, for a total of 61 samples. The transect in the old-growth forest on AD soil type presented the most bioluminescent fungi, followed by the transect in the secondary forest on TH soil type. Decomposing organic matter (dead trunks and litter) was the preferred substrate used by bioluminescent fungi (Table 1, Fig. 2E, 2F).

The   correspondence   analysis   did   not show a clear association between the different substrates and forest types (inertia=0.069). There was, however, a significant association between fungus substrate and soil type. In this case, dead trunks and roots were associated with TT and AD soils, whereas fallen branches were associated with AH, and litter was associated with TH (Fig. 1), explaining the variation across two axes (inertia values=0.21, 0.071).

The results of the logistic regression show that the interaction of forest successional stage and soil type explained the distribution of fungi on the different substrate categories (X2=23.21, df=12,  p=0.025).  Forest  type  by  itself  did not explain the distribution of bioluminescent fungi in these four substrates (X2=6.08, df=3, p=0.10),  whereas  soil  type  had  a  relevant effect on the probability of fungi occurrence in different substrate categories (X2=18.89, df=9, p=0.026).

Field records: Only three samples had fruiting  bodies;  two  samples  had  Mycena s.l.,  and  the  other  had  a  fungus  belonging to  the  order  Xylariales  (possibly  Hypoxylon sp., Kretzschmariella sp., Xylaria sp.). The description of the samples with fruiting bodies is as follows:

Mycena  s.l.  1.  Pileus:  0.8-3.0cm  diameter, slightly umbilicate, surface striated and translucent toward the margin, striated margin, light brown color. Context: less than 0.1cm, concolor with the pileus. Hymenium: lamellae free, subdistant, with three different size lamellulae. Stipe: 1-1.5cm long and 1-2mm wide, cylindric, position central, surface fibrillose, concolor with the pileus. Ocurrence: gregarious. Substrate: growing on wood. Habitat: Old-Growth  forest,  AD  soil,  sendero  Atajo. Location: survey point at 25m and 125m from trail head (Fig. 2A, 2B).

Mycena s.l. 2. Pileus: 2.0-5.0mm diameter, slightly umbilicate, surface striated and translucent toward the margin, striated margin, light brown color. Context: less than 0.1cm, concolor with the pileus.   Hymenium: lamellae free, subdistant, with three different size lamellulae. Stipe: 1.0-1.5cm long and 1-2mm wide, cylindric, position central, surface fibrillose, concolor with the pileus. Ocurrence: gregarious. Substrate: growing on wood. Habitat: Old-Growth forest, TT soil, sendero Surá. Location:  survey  point  at  1 000m  from  trail head (Fig. 2C, D).

Order  Xylariales  (possibly  Hypoxylon sp., Kretzschmariella sp., Xylaria sp.). These were found growing in roots of the palm Geonoma  congesta  in  old-growth  forest  and TT soil, sendero Surá survey point at 1 025m from trail head.

Additional observations: Although most of the bioluminescent fungi were found growing on decaying wood, those that were growing on decomposing trunks or roots were frequently found on leaves and trunks of palms, as well as trees of Fabaceae (Mimosaceae), and lianas. We  also  searched  for  luminescent  mycelia, but it was not possible to identify the hyphal development. We did observe that wood with bioluminescent mycelia was always orange in color and the luminescence was brighter on transects closer to streams.

On each of the three samples with fruiting bodies, unidentified insects were present. This potentially supports the hypothesis that bioluminescence serves to attract insects for spore dispersal, although more studies are needed. A few samples with fungi colonizing wood were placed  in  closed  plastic  bags,  which  developed fruiting bodies during the same week, although these fruiting bodies did not emit any light at all.

Discussion

Abundance of bioluminescent fungi: Bioluminescent fungi represent a rare sight in tropical rainforests. Their distribution depends on the nature of the substrates they colonize (Mata 1995, 1997). Fungi from the order Agaricales, which comprise the majority of bioluminescent fungi (Desjardin et al. 2008), are associated with habitat type (Alexopoulus et al. 1996). The two transects with the highest frequency of fungi had fertile soils, creating a higher probability of increased diversity of woody  plants,  and  thus,  more  substrates  for the  fungi  (which  are  primarily  decomposers of lignin and cellulose). The abundance of bioluminescent fungi at La Selva is certainly influenced by humidity, temperature, exposure to light (Bermudes et al. 1990) and the pervasive presence of streams. For these reasons, the interaction of forest type and soil type explained the distribution of bioluminescence fungi, with soil type as the most important variable.

Field records: The identification of fruiting bodies is still one of the fastest ways to perform fungi identification in the field. Mycena s.l. is very common in tropical rainforests and has been well studied (Mata 1995, 1997, Desjardin et al. 2007). Xylariaceous mycelia have been reported with variable levels of bioluminescence by Shimomura (2011). Harvey (1952 in Weitz 2004) mentioned a possible exception of bioluminescent fungus, Xylaria hypoxilon. The order Xylariales is very specific with respect to substrates types (Lodge 2001), and there could be a possible relationship between this group and Geonoma congesta, or the family Arecaceae in general.

Future work should concentrate on the basic ecology, dispersal, substrate preferences, and  temporal  cycles  in  the  light  emission of fungal mycelia related to weather conditions. Once more information is accumulated, and locating of bioluminescent fungi at night becomes more efficient, we will be able to gather more evidence to understand the role that these organisms play across successional gradients, and how they affect the patterns of diversity of tropical forests in general.

Acknowledgments

The authors thank the Costa Rica-USA Foundation and the Organization for Tropical Studies for funding REU for this research. Erin Marnocha and Carlos Rojas made comments that significantly improved the manuscript. Andrés Jiménez and Maricela Pizarro helped in the field, and Gustavo Gutiérrez provided logistical support.



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*Correspondencia a:

Carolina Seas-Carvajal. Escuela de Biología, Universidad de Costa Rica, 2060 San José, Costa Rica; carolina.seas@ucr.ac.cr.
Gerardo Avalos. Escuela de Biología, Universidad de Costa Rica, 2060 San José, Costa Rica; The School for Field Studies, Center for Sustainable Development Studies,10 Federal St., Salem, MA 01970 USA; gerardo.avalos@ucr.ac.cr
1. Escuela de Biología, Universidad de Costa Rica, 2060 San José, Costa Rica; carolina.seas@ucr.ac.cr.
2. The School for Field Studies, Center for Sustainable Development Studies,10 Federal St., Salem, MA 01970 USA; gerardo.avalos@ucr.ac.cr.

Received 25-I-2012.    Corrected 20-IX-2012.    Accepted 22-X-2012.

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