Water-borne hyphomycetes in tree canopies of Kaiga  
(Western Ghats), India

NAGA M. SUDHEEP and KANDIKERE R. SRIDHAR

Department of Biosciences, Mangalore University 
Mangalagangotri, Mangalore IN-574-199, India, sirikr@yahoo.com

Sudheep N. M., Sridhar K. R.: Water-borne hyphomycetes in tree canopies of Kaiga (Western 
Ghats), India. Acta Mycol. 45 (2): 185–195, 2010.

The canopy samples such as trapped leaf litter, trapped sediment (during summer), 
stemflow and throughfall (during monsoon) from five common riparian tree species (Artocarpus 
heterophyllus, Cassia fistula, Ficus recemosa, Syzygium caryophyllatum and Xylia xylocarpa) in 
Kaiga forest stand of the Western Ghats of southwest India were evaluated for the occurrence 
of water-borne hyphomycetes. Partially decomposed trapped leaf litter was incubated in 
bubble chambers followed by filtration to assess conidial output. Sediments accumulated 
in tree holes or junction of branches were shaken with sterile leaf disks in distilled water 
followed by incubation of leaf disks in bubble chamber and filtration to find out colonized 
fungi. Stemflow and throughfall samples were filtered directly to collect free conidia. From five 
canopy niches, a total of 29 water-borne hyphomycetes were recovered. The species richness 
was higher in stemflow and throughfall than trapped leaf litter and sediments (14-16 vs. 6-10 
species). Although sediments of Syzygium caryophyllatum were acidic (5.1), the conidial output 
was higher than other tree species. Stemflow and throughfall of Xylea xylocarpa even though 
alkaline (8.5-8.7) showed higher species richness (6-12 species) as well as conidial load than 
rest of the tree species. Flagellospora curvula and Triscelophorus acuminatus were common in 
trapped leaf litter and sediments respectively, while conidia of Anguillospora crassa and A. 
longissima were frequent in stemflow and throughfall. Diversity of water-borne hyphomycetes 
was highest in throughfall of Xylea xylocarpa followed by throughfall of Ficus recemosa. Our 
study reconfirms the occurrence and survival of diverse water-borne hyphomycetes in different 
niches of riparian tree canopies of the Western Ghats during wet and dry regimes and predicts 
their possible role in canopy as saprophytes, endophytes and alternation of life cycle between 
canopy and aquatic habitats.   
Key words: water-borne hyphomycetes, diversity, conidia, canopy, leaf litter, sediment, 
stemflow, throughfall

 ACTA MYCOLOGICA
 Vol. 45 (2): 185–195
 2010

Dedicated to Professor Barbara Gumińska 
on the occasion of her eighty-fifth birthday



186 N. M. Sudheep and K. R. Sridhar 

INTRODUCTION

Forest canopies are endowed with a mosaic of flora, fauna and microbes (Nadkarni 
et al. 2001). Tropical canopy of Ecuador trap about 200-300 kg dry mass of litter per 
hectare consisting of at least 500-600 m of rhizomorphs (e.g., Marasmius spp.) per 
kg litter, which is equivalent to approximately 180 km per hectare (Hedger 1990). 
A rough estimate of microfungal biomass in twigs and needle surfaces of old-growth 
Douglas fir forest canopies was up to 450 kg/ha/yr (Carroll et al. 1980). Thus, can-
opies provide a wide variety of niches and accommodate a broad group of fungi 
(e.g., phylloplane fungi, endophytes, pathogens, lignicolous fungi) (Lodge, Cantrell 
1995; Stone et al. 1996; Shaw 2004). Besides these, water-borne fungi (aquatic and 
aero-aquatic hyphomycetes) are also known from canopies. They have been re-
ported from the epiphytes, tree holes, trapped leaf litter, stemflow, throughfall and 
other niches of canopy in temperate and tropical regions (e.g., Ando, Tubaki 1984; 
Czeczuga, Orłowska 1998a, 1999; Gönczöl, Révay 2006; Sridhar et al. 2006; Karam-
chand, Sridhar 2008, Sridhar 2009; Sridhar, Karamchand 2009). Typical water-borne 
hyphomycetes are also endophytic in needles of black spruce (Picea mariana) of 
a mixed woody forest in Canada (Sokolski et al. 2006). Tree holes (formed due to 
decomposition of branches) and junctions of branches act as receptacles for deposi-
tion of water, sediment, leaf litter and other canopy debirs, which constitute ideal 
substratum for colonization and survival of water-borne hyphomycetes. Water from 
mist or rain flowing along the trunks (stemflow) and dripping from foliage (through-
fall) are also major sources of conidia of water-borne hyphomycetes. About 33 spe-
cies of fungi encompassing many water-borne hyphomycetes have been reported 
in rainwater dripping through building roofs in Poland and predicted their survival 
due to accumulation of sediments on undulating roof surfaces (Czeczuga, Orłowska 
1997). Floral honey and honeydew excreted by the aphids in canopies are also serve 
as niches for fungi (Magyar et al. 2005). So far, about 125 species of water-borne hy-
phomycetes have been reported from the tree canopies (Sridhar 2009; Karamchand, 
Sridhar 2009; Sridhar, Karamchand 2009).

The Western Ghats of India (8°20’–20°40’ N and 73°–77° E) as a hotspot of bio-
diversity endowed with moist deciduous and montane rain forests at an elevation up 
to 2000 m asl. The vegetation mainly consists of scrub jungle, grasslands, moist to dry 
deciduous forests, tropical evergreen forests and sholas. Water-borne hyphomyc-
etes have been explored from streams and rivers of coastal, mid-altitude (foothill) 
and mountain regions of the Western Ghats (e.g., Sridhar, Kaveriappa 1989; Chan-
drashekar et al. 1990; Sridhar et al. 1992; Raviraja et al. 1998; Rajashekhar, Kaveri-
appa 2003). In view of limited studies on water-borne hyphomycetes of tree canopies 
in tropics (Sridhar et al. 2006; Karamchand, Sridhar 2008; Sridhar, Karamchand 
2009), the present investigation aims at exploring their assemblage and diversity in 
canopies of selected tree species during summer and monsoon seasons in Kaiga 
forest stand located at the Western Ghats of southwest India.



 Water-borne hyphomycetes 187

MATERIALS AND METHODS

The location selected for study is situated adjacent to the River Kali near Kaiga nu-
clear power station of the southwest India (~35 km east of the Karwar City; ~55-70 
m asl; 14°50′–14°51′ N, 74°26′ E). Three trees each of five species (Artocarpus het-
erophyllus Lam., Cassia fistula L., Ficus recemosa Linn., Syzygium caryophyllatum (L.) 
Alston and Xylia xylocarpa Roxb. Taub.) distributed in an area of 300 m2 were chosen 
for study. The canopies of trees selected were free from interference of other trees. 
During April 30, 2009 (summer), partially decomposed trapped leaf litter at the 
tree holes or junctions of branches were sampled (the mean rainfall, temperature 
and humidity during April 2009 in Kaiga forest was 0.7 mm, 30.8°C and 71.1% re-
spectively). They were transported to the laboratory and rinsed in distilled water to 
remove adhered debris. Small segments (5–8) weighing about 100–250 mg dry mass 
were aerated up to 48 h in 250 ml Erlenmeyer flasks containing 150 ml of sterile dis-
tilled water (bubble chamber) at laboratory temperature (28±2°C). Aerated water 
was filtered through Millipore filters (5 μm; diam., 47 mm) to trap released conidia 
of water-borne hyphomycetes. The filters were stained with 0.1% aniline blue in lac-
tophenol. Each stained filter was cut in to half, mounted on a microscope slide with 
a few drops of lactic acid for screening conidia (Nikon OPTIPHOT, Japan: 20 ×, 
40 ×, 100 ×) and they were identified based on conidial morphology using primary 
literature and monographs (Ingold 1975a; Nawawi 1985; Marvanová 1997; Gulis et 
al. 2005). Sediments accumulated at the tree holes or junctions of branches sampled 
during April 30, 2009 were assessed for the presence of water-borne hyphomycetes 
by indirect method (Sridhar et al. 2008). Five pre-weighed sediment samples (200-
300 mg dry mass) were used (parallel samples were weighed before and after drying 
at 100°C for 24 h to convert wet to dry mass). Each sediment sample was transferred 
to 250 ml Erlenmeyer flask containing 150 ml sterile distilled water with 5 sterile 
banyan leaf (Ficus benghalensis L.) disks (1.5 cm diam.). The flasks were incubated 
on a rotary shaker for 14 days (150 rpm, 28±2°C). The leaf disks were harvested, 
rinsed in distilled water to eliminate sediments and incubated in bubble chambers 
to stimulate production of conidia from colonized fungi and assessed further as de-
scribed above.  

Stemflow and throughfall of each tree were collected during July 30, 2009 (mon-
soon) (mean rainfall, temperature and humidity during July 2009 in Kaiga forest was 
1767 mm, 26.9°C and 98.2% respectively). Shortly after the beginning of the rainy 
period (20–30 min), about 200 ml of water draining through the main stem was col-
lected in sterile polythene bags and transferred to sterile glass bottles. A clean poly-
thene sheet (2 m2) was spread below the canopy of each tree (~1 m above ground 
and ~3 m away from tree base), up to 200 ml of water dripping through each canopy 
was sampled and transferred to sterile glass bottles. Within 30 min of sampling, aliq-
uots (25 ml) of stemflow and throughfall were separately filtered through Millipore 
filters to assess the free conidia of water-borne hyphomycetes.    

Sediment moisture (gravimetric), pH and conductivity (1:2 dilution with distilled 
water) were assessed using water analysis kit (Water Analyzer 371, Systronics, Gu-
jarat, India). Similarly, temperature, pH and conductivity of stemflow and through-
fall were assessed at the sampling site. Parts of stemflow and throughfall samples 



188 N. M. Sudheep and K. R. Sridhar 

were fixed at the site to estimate dissolved oxygen by Winkler’s method (APHA 
1995). 

Based on occurrence of water-borne hyphomycetes in trapped leaf litter, sedi-
ment, stemflow and throughfall, Shannon diversity [H’ = – ∑ (pi × ln pi)] (Magurran 
1988) and Pielou’s equitability (J′ = H′ ÷ H′max) (Pielou 1975) were determined 
(where pi is the relative abundance of species i and H′max is the maximum value of 
diversity for the number of fungal species present).

RESULTS

Average moisture content of the trapped leaf litter and sediments of the five tree 
species was 6.7% (range 5.5–8.1%) and 6.6% (range 5.1–8.1%) respectively (Tab. 1). 
The mean temperature of stemflow and throughfall ranged between 24.4°C and 25°C 
respectively. The mean pH of sediment was acidic (6.1) than stemflow (7.1) as well 
as throughfall (7.6). Sediments of Xylea xylocarpa and Syzygium caryophyllatum were 
acidic (4.8 and 5.1), while stemflow and throughfall of X. xylocarpa were alkaline (8.5 
and 8.7). The mean conductivity of sediment was higher (288 μS/cm) than stemflow 
(60 μS/cm) and throughfall (61 μS/cm). Average dissolved oxygen in stemflow and 
throughfall was 7.1 mg/l (range 6.9–7.5 mg/l). 

Five canopy niches surveyed yielded a total of 29 species of water-borne hy-
phomycetes (Tabs 2 and 3). Ten species ranging from 2 (Ficus recemosa) to 6 (Cas-
sia fistula) were recovered from the trapped leaf litter. Six species ranging from 1 
(Xylea xylocarpa) to 3 (Artocarpus heterophyllus and F. recemosa) were found in sedi-
ment. Conidial output from trapped leaf litter and sediment was highest in Syzygium 
caryophyllatum and least in X. xylocarpa (Fig. 1). Flagellospora curvula was found in 

Table 1 
Physicochemical features of canopy samples of five tree species of Kaiga forest assessed for 
water-borne hyphomycetes (n=3, mean) (Ah, Artocarpus heterophyllus; Cf, Cassia fistula; Fr, 

Ficus recemosa; Sc, Syzygium caryophyllatum; Xx, Xylia xylocarpa)

Parameter Tree species Mean 
(n=5)Ah Cf Fr Sc Xx

Trapped leaf litter
Moisture (%) 7.5 5.6 8.1 6.9 5.5 6.7

Trapped sediment
Moisture (%) 8.1 6.6 5.1 7.2 5.9 6.6
pH 6.5 7.1 7.1 5.1 4.8 6.1
Conductivity (μS/cm) 302.3 75.3 276.7 554 232.7 288.2

Stemflow
Temperature (°C) 24 24.5 25 25.5 26 25.0
pH 7.3 7.5 7.3 7.2 8.5 7.6
Conductivity (μS/cm) 20 63.6 60.1 16.4 142 60.4
Dissolved oxygen (mg/l) 7.5 7 7 7.2 7 7.1

Throughfall
Temperature (°C) 24 24 25 25 24 24.4
pH 7.5 7.7 7 7.3 8.7 7.6
Conductivity (μS/cm) 45.1 75.7 64.6 24.5 94.4 60.9
Dissolved oxygen (mg/l) 7 7.4 6.9 7 7 7.1



 Water-borne hyphomycetes 189

Table 2 
Percentage contribution of water-borne hyphomycete species to conidial production and 

diversity in trapped leaf litter and trapped sediment (in parenthesis) of five tree species of 
Kaiga forest (Ah, Artocarpus heterophyllus; Cf, Cassia fistula; Fr, Ficus recemosa; Sc, Syzy-

gium caryophyllatum; Xx, Xylia xylocarpa)

Taxon Tree species
Ah Cf Fr Sc Xx

Flagellospora curvula Ingold 13.9 6.1 25.8 1.4 9.2
Triscelophorus acuminatus Nawawi (71.4) (95.6) (96) (100)
Lunulospora curvula Ingold 27.8 6.5

(28.6)
47

Anguillospora longissima (Sacc. & P. Syd.) Ingold 31.1
(8.1)

1.4 5.2

Flagellospora penicillioides Ingold 13.9 79 74.2
Cylindrocarpon sp. 13.2

(65.7)
(0.2)

Campylospora parvula Kuzuha 53 29.4
Tetracladium setigerum (Grove) Ingold 2.9 9.2
Triscelophorus konajensis K.R. Sridhar & Kaver. (0.4) (4)
Campylospora filicladia Nawawi 44.2
Triscelophorus monosporus Ingold (26.2)
Tripospermum myrti (Lind) S. Hughes 2.9
Unidentified (Tricladium-like conidia) 2.9
Total species 5

(3)
6

(2)
2

(3)
4

(2)
5

(1)
Shannon diversity 2.215

(1.198)
1.216

(0.863)
0.824

(0.060)
1.179

(0.042)
1.886

Pielou’s equitability 0.954
(0.756)

0.470
(0.863)

0.824
(0.038)

0.589
(0.242)

0.812

Table 3 
Percentage contribution of water-borne hyphomycete species to conidial production and 
diversity in stemflow and throughfall (in parenthesis) of five tree species of Kaiga forest 

(Ah, Artocarpus heterophyllus; Cf, Cassia fistula; Fr, Ficus recemosa; Sc, Syzygium caryophyl-
latum; Xx, Xylia xylocarpa) (*new record to canopy)

Taxon Tree species
Ah Cf Fr Sc Xx

Anguillospora crassa Ingold 34
(11.1)

50
(100)

16.7 (19.4)

Anguillospora longissima (Sacc. & P.  
Syd.) Ingold

(3.3) (28.6) 16.7
(40)

4.8
(2.2)

Triscelophorus acuminatus Nawawi (53.3) 50 14.3 4.8
(7.5)

Lunulospora curuvla Ingold (3.3) 33.3
(20)

76.2
(14.2)

Flagellospora curvula Ingold 28.6 (20) 4.8
(14.9)

Ceratosporium cornutum Matsush. 27.7 (14.3) (4.5)
Triscelophorus monosporus Ingold (28.9) 16.7 4.8
Helicomyces scandens Morgan  6.4 16.7
Trinacrium sp. (14.3) (2.2)
Flabellospora crassa Alas. (13.3) (2.2)
Dwayaangam sp. 28.6
Unidentified (sickle-shaped conidia) 28.6
Dwayaangam cornuta Descals (26.1)
Trisulcosporium acerinum H.J. Huds. & B. Sutton (20)
Flabellospora verticillata Alas. (14.3)
Tricladium sp. (14.3)



190 N. M. Sudheep and K. R. Sridhar 

trapped leaf litter of all tree species, while Triscelophorus acuminatus was more com-
mon in sediments of four tree species. Fungal diversity in trapped leaf litter as well 
as sediment of A. heterophyllus was higher than other tree species. 

The species richness was higher in stemflow and throughfall than trapped leaf 
litter and sediments (23 vs. 13 species) (Tab. 3). Stemflow represented by 14 species 
ranging from 2 (Cassia fistula) to 6 (Artocarpus heterophyllus and Xylea xylocarpa). 
Throughfall consists of 16 species ranging from 1 (C. fistula) to 12 (X. xylocarpa). 
The conidial concentration in stemflow and throughfall was highest in X. xylocarpa 
and least in C. fistula (Fig. 1). Anguillospora crassa was common in stemflow of three 
out of five tree species, while Anguillospora longissima was seen in throughfall of four 
tree species. Fungal diversity was highest in throughfall of X. xylocarpa, while it was 
highest in trapped leaf litter in A. heterophyllus.  

DISCUSSION

Water-borne hyphomycetes in tree canopies have been explored extensively in tem-
perate regions than tropical regions. Niches in tree canopies investigated in temper-
ate regions (mainly from Canada, Europe and Japan) were gymnosperm needles, 
angiosperm leaves, tree hole, honey dew, melting snow, stemflow and throughfall 
(e.g., Ando, Tubaki 1984; Czeczuga, Orłowska 1998a, 1998b; Magyar et al. 2005; 
Gönczöl, Révay 2003, 2004, 2006; Sokolski et al. 2006). Recently, a few niches in tree 
canopies (epiphytic fern, tree hole, stemflow and throughfall) of the west coast and 
Western Ghats of India have been studied (Sridhar et al. 2006; Sridhar, Karamchand 
2009; Karamchand, Sridhar 2009).

The trapped leaf litter collected during summer consists of 10 species of water-
borne hyphomycetes in our study. Such trapped leaf litter in tree holes and epiphytic 
fern in Sampaje of the Western Ghats during summer yielded 13 and 15 species 
(Karamchand, Sridhar 2008, 2009). However, conidial output from the trapped leaf 
litter in our study is considerably lower than Sampaje region (35–192 vs. 363-601/g). 
As colonized fungi are viable in trapped leaf litter even during dry season, they will 
be disseminated within or across the canopy and also to aquatic bodies.

Helicomyces roesus Link 12.8
*Hydrometrospora symmetrica J. Gönczöl & Révay 12.8
Flagellospora penicillioides Ingold 6.4
Diplocladiella scalaroides G. Arnaud ex M.B. Ellis 4.8
Clavatospora tentacula Sv. Nilsson (2.2)
Alatospora acuminata Ingold (2.2)
Triscelophorus konajensis K.R. Sridhar & Kaver.  (2.2)
Total species 6

(5)
2

(1)
4

(6)
5

(4)
6

(12)
Shannon diversity 2.308

(1.678)
1.00

 
1.950

(2.518)
2.258

(1.922)
1.350

(2.985)
Pielou’s equitability 0.893

(0.723)
1.00

 
0.975

(0.974)
0.970

(0.961)
0.522

(0.833)

Tab. 3. cont



 Water-borne hyphomycetes 191

Fig. 1. Conidial output of water-borne hyphomycetes from trapped leaf litter, trapped sedi-
ment and conidial load in stemflow and throughfall of five tree species of Kaiga forest of the 
Western Ghats given in decreasing order (n=3, mean±SD) (Tree species: Ah, Artocarpus 
heterophyllus; Cf, Cassia fistula; Fr, Ficus recemosa; Sc, Syzygium caryophyllatum; Xx, Xylia 
xylocarpa). 



192 N. M. Sudheep and K. R. Sridhar 

The sediment analysis employed in our study is an indirect method to evaluate 
viable propagules (either spores or mycelia) of water-borne hyphomycetes capable 
of colonizing baited sterile leaf disks (Sridhar et al. 2008). The species richness in 
sediments was lower than trapped leaf litter, stemflow and throughfall (6 vs. 10-16) 
reveals survival of a few species in tree sediments. Triscelophorus acuminatus was 
most common in sediments collected from four tree species. Similarly, T. acumi-
natus and T. konajensis were fairly dominant in sediments sampled from Kaiga re-
gion (Kaiga stream, Kali River and Kadra Dam) (K.R. Sridhar and N.M. Sudheep; 
unpublished observations) indicates their survival under low O-R potential. These 
species were also dominant in trapped leaf litter in tree holes of Sampaje region in 
spite of low dissolved oxygen in tree hole waters (1.14 mg/l) (Karamchand, Sridhar 
2009). Anguillospora longissma, Flagellospora curvula, Lunulospora curvula, T. acumi-
natus and T. konajensis were highly colonized the leaf disks immersed in tree holes 
of Konaje region of the west coast of India in spite of low dissolved oxygen in tree 
hole waters (1.1–5.7 mg/l) (Karamchand 2008). Except for T. konajensis, rest of the 
species dominated in leaf litter or sediment, stemflow and throughfall in our study 
(see Tabs 2 and 3). Although the dissolved oxygen was low (3.8 mg/l) in a thermal 
spring of Southern India, 14 species of water-borne hyphomycetes were recovered 
by Chandrashekar et al. (1991). Survival of aquatic hyphomycetes up to 12 months 
under anaerobic conditions has been demonstrated by Field and Webster (1983). 
Depletion of oxygen from 94% to 4% saturation in microcosms resulted in 90% 
decrease in fungal biomass, the sporulation was strongly inhibited due to reduction 
of dissolved oxygen and the species richness was dropped to 60% (Medeiros et al. 
2009). Viability of water-borne hyphomycetes in tree holes in spite of low dissolved 
oxygen during wet season and dry season facilitates recolonization of organic matter 
on the onset of wet conditions. 

The pH of sediment collected from Xylia xylocarpa, Syzygium caryophyllatum 
and Artocarpus heterophyllus was acidic (4.8, 5.1 and 6.1). But the diversity of water-
borne hyphomycetes was highest in A. heterophyllus and the leaf disks baited with 
sediment collected from S. caryophyllatum showed high conidial output. On the con-
trary, stemflow and throughfall of X. xylocarpa were alkaline (8.5, 8.7), but the spe-
cies richness (6–12 species) and the Shannon’s diversity (2.985) in throughfall were 
the highest among tree species studied. Bärlocher (1987) compared Canadian and 
European streams and demonstrated a slow or negligible decrease in species rich-
ness in circumneutral waters (5.7–7.2) with a rapid decline in alkaline waters (>7.2). 
Raviraja et al. (1998) supported this view by demonstrating a negative correlation 
between species richness vs. pH in Western Ghat streams. The species richness in 
throughfall and stemflow was higher than trapped leaf litter and sediment (14–16 
vs. 6-10 species) corroborates earlier study on water-borne hyphomycetes in non-
riparian tree species of the west coast of India (Sridhar, Karamchand 2009). The 
pH of tree hole waters in Sampaje region was close to neutral (6.98), while in our 
study, stemflow and throughfall were alkaline (7.2–8.5 and 7.3–8.7) (exception of 
throughfall of one tree species). The conidial concentration was highest in stemflow 
and throughfall of Xylia xylocarpa in spite of alkaline pH (8.5 and 8.7). 

The conductivity was higher in sediment (288 μS/cm) as seen in tree hole waters 
of Sampaje (148 μS/cm) (Karamchand, Sridhar 2008). Compared to sediments and 
tree hole waters, the conductivity of stemflow and throughfall was low in our study 



 Water-borne hyphomycetes 193

(mean, 60–61 μS/cm) as evident in an earlier investigation (10.1–72.9 μS/cm) in the 
west coast (Sridhar, Karamchand 2009).  

Three known and six unknown conidial morophotypes of Dwayaangam species 
have been reported in rainwater samples (15 out of 25 tree species) in different 
locations of Europe (Gönczöl, Révay 2006). Interestingly, Dwayaangam heterospora 
is known to parasitize eggs of rotifers and nematodes (Barron 1991). Dwayaangam 
colodena has also been reported as an endophyte in canopy needles of black spruce 
(Picea mariana) (Sokolski et al. 2006). In our study, Dwayaangam cornuta and 
Dwayaangam sp. contributed conidia between 26.1% (throughfall of Xylia xylocarpa) 
and 28.6% (stemflow of Ficus recemosa) respectively indicates their possible role as 
saprophytes, parasites and possibly endophytes in tree canopies. 

The multiradiate conidial shape of aquatic hyphomycetes is the product of con-
vergent evolutions and secondary adaptation to aquatic mode of life (Ingold 1975b; 
Belliveau, Bärlocher 2005). Stone et al. (1996) suggested that canopy fungi may be 
the early colonizers of tissues in intact leaves and twigs, and act as a link between 
soil and aquatic food webs by completing their life cycles. Studies on perfect-im-
perfect connections of aquatic hyphomycetes showed that the majority of species 
have evolved from ascomycetes found in decaying tree branches in streams (Web-
ster, Descals 1979; Webster 1992; Marvanová 1997; Sivichai et al. 2002; Sivichai, 
Jones 2003) and molecular studies also confirmed their terrestrial relatives (Liew 
et al. 2002). Selosse et al. (2008) proposed a hypothesis that a large numbers of 
conidia of water-borne hyphomycetes congregate in stream foam disperse through 
wind or aerosols to tree canopies facilitating their survival as epiphytes, endophytes 
or saprophytes. 

Our study supports the view that at least a few water-borne hyphomycetes survive 
in trapped leaf litter and sediments in tree canopies in viable state for a considerable 
period during dry season facilitating their perpetuation on the onset of wet sea-
son. Conidia in stemflow and throughfall during wet season are easily disseminated 
to other parts of the canopy or nearby aquatic habitats. Widespread occurrence of 
water-borne hyphomycetes in tree canopies and their adaptation to wide range of 
canopy ecological conditions in temperate and tropical regions suggests their life 
cycle alternates between aquatic and canopy habitats. Further studies are necessary 
to understand the functional significance of water-borne hyphomycetes, role in nu-
trient cycling in canopies and impacts of atmospheric pollution.   

Acknowledgements. The authors are grateful to Mangalore University for permission to carry out this 
study at the Department of Biosciences and Nuclear Power Corporation of India Ltd. (NPCIL), Mum-
bai, India for financial support and award of research fellowship. Authors are thankful to Dr. H.M. So-
mashekarappa, University Science Instrumentation Centre, Mangalore University and Dr. P.M. Ravi, 
NPCIL, Kaiga, Karnataka for support.   



194 N. M. Sudheep and K. R. Sridhar 

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