1998, 64(12):4820. Appl. Environ. Microbiol. 

JoséAparecida Hebling
Carlos Pagnocca, Odair Correa Bueno and Maria 
Célia Gomes De Siqueira, Maurício Bacci Jr., Fernando
 

 L.Atta sexdens
Symbiotic Fungus of the Leaf-Cutting Ant 

, theLeucoagaricus gongylophorus
Metabolism of Plant Polysaccharides by

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APPLIED AND ENVIRONMENTAL MICROBIOLOGY,
0099-2240/98/$04.0010

Dec. 1998, p. 4820–4822 Vol. 64, No. 12

Copyright © 1998, American Society for Microbiology. All Rights Reserved.

Metabolism of Plant Polysaccharides by Leucoagaricus
gongylophorus, the Symbiotic Fungus of the Leaf-Cutting Ant

Atta sexdens L.
CÉLIA GOMES DE SIQUEIRA, MAURÍCIO BACCI, JR.,* FERNANDO CARLOS PAGNOCCA,

ODAIR CORREA BUENO, AND MARIA JOSÉ APARECIDA HEBLING

Centro de Estudos de Insetos Sociais, Universidade Estadual Paulista, Rio Claro, SP. CEP 13506-900, Brazil

Received 9 February 1998/Accepted 7 October 1998

Atta sexdens L. ants feed on the fungus they cultivate on cut leaves inside their nests. The fungus, Leucoag-
aricus gongylophorus, metabolizes plant polysaccharides, such as xylan, starch, pectin, and cellulose, mediating
assimilation of these compounds by the ants. This metabolic integration may be an important part of the
ant-fungus symbiosis, and it involves primarily xylan and starch, both of which support rapid fungal growth.
Cellulose seems to be less important for symbiont nutrition, since it is poorly degraded and assimilated by the
fungus. Pectin is rapidly degraded but slowly assimilated by L. gongylophorus, and its degradation may occur
so that the fungus can more easily access other polysaccharides in the leaves.

Leaf-cutting ants in the genera Atta and Acromyrmex are
assumed not to feed on solid plant material (16, 20) but to
utilize instead the liquid nutrients gathered from both the
leaves they cut (3, 13, 14) and the fungus, Leucoagaricus gongy-
lophorus, that they cultivate in their nests (4, 21, 26, 27). The
fungus metabolizes cellulose (1, 15), which is the most common
plant polysaccharide (12). Thus, current opinion is that the
symbiosis is based on the ability of ants to feed on cellulose
through the fungus (8). However, besides cellulose, vegetation
contains xylan, pectin, and starch, in amounts up to 60% of the
leaf dry weight (6, 12). This abundant source of nutrients could
be assimilated by the fungus and thus utilized by the ants.

To test this hypothesis, we have studied the metabolism of
plant polysaccharides by L. gongylophorus. The fungus was
cultured in single carbon sources, such as cellulose, xylan, pec-
tin, starch, and the hydrolysis products of some of these poly-
mers. After cultivation, substrate assimilation and polymer
degradation were evaluated. Our results show that L. gongylo-
phorus is able to mediate the assimilation by A. sexdens of all
plant polysaccharides. However, contrary to current thought,
cellulose seems not to be the most important carbon source for
symbiont nutrition.

MATERIALS AND METHODS

Organism and culture conditions. Strains CCT1, CCT2, and CCT3 of L.
gongylophorus (formerly called Leucocoprinus gongylophorus) have been isolated
from different nests of A. sexdens L. and are deposited in the Tropical Culture
Collection, Campinas, SP., Brazil, under the accession numbers CCT 6414, CCT
6415, and CCT 6416. The isolates were kept at 25°C in the dark in culture
medium A (18). Cells (41 6 14 mg [dry weight]) from 30-day cultures were
transferred to 250-ml Erlenmeyer flasks containing 50 ml of yeast nitrogen base
(YNB; Difco) medium (pH 6.0) and 0.25 g of a single carbon source. After 30
days of incubation at 25°C in the dark, the metabolic ability of the fungus was
evaluated by determining the cell mass variation, degradation of polysaccharides,
and efficiency of growth on polysaccharide hydrolysis products.

Cell mass variation. Flasks with culture medium were weighed before and
after cell transfer, and the inoculum dry weight (I) was estimated as 5% of the net
weight. After incubation, fungal mycelia were collected, dried at 70°C for 24 h,
and weighed, and the final cell mass (F) was calculated. Cell mass variation (V)
was estimated by the equation V 5 F/I. The growth rate is constant for 50 days

when cells are incubated on glucose or starch and for over 60 days when they are
incubated on cellulose or carboxymethylcellulose (data not shown). The cell mass
variation was calculated after 30 days of cultivation to estimate fungal ability to
assimilate different carbon sources.

Sugar determination. Reducing sugars were assayed by the method of Miller
(17). The concentration of cellulose or starch hydrolysis products was calculated
with glucose as the standard; galacturonic acid and xylose were used as standards
for the quantitation of pectin and xylose hydrolysis products, respectively.

Growth efficiency. Growth efficiency (Y%) was calculated by the equation Y%
5 100 X/M, where X is the cell mass production (in milligrams [dry weight]) and
M is the substrate consumed (in milligrams).

Enzyme assay. After the fungus was cultured, the culture medium (50 ml) was
filtered through a 0.45-mm-pore-size Millipore filter and the proteins were pre-
cipitated in an ice-cold bath with 40 mg of ammonium sulfate and diluted in 50
mM phosphate buffer, pH 6.0. Enzyme activity was determined at 25°C in the
same buffer containing 2% (wt/vol) of the substrate (xylan, pectin, starch, mi-
crocrystalline cellulose, carboxymethylcellulose, or acid-swollen cellulose) and
0.10 mg of protein/ml. The reaction mixture was incubated on a reciprocating
shaker (100 rpm); samples were collected every 15 min of incubation, boiled for
1 min, and centrifuged, and the concentration of reducing sugars in the super-
natant was determined. The sugar concentration increased linearly during incu-
bation (1 h for xylan, pectin, or starch and 4 h for microcrystalline cellulose,
carboxymethylcellulose, or acid-swollen cellulose), so linear regression was used
to calculate the enzyme activity, which was expressed in micromoles of hydrolysis
products per gram of cells (dry weight) per hour.

Substrates. The substrates used were purchased from Sigma (St. Louis, Mo.)
and Merck (Darmstadt, Germany), as well as the Brazilian companies Reagen,
Synth, and Polyfarma (São Paulo). Xylan from birchwood (Sigma catalog no.
X-0502), soluble starch (Reagen catalog no. 8412), pectin from citrus (Sigma
catalog no. P-9135), cellulose (Sigma catalog no. C-6288), microcrystalline cel-
lulose (Merck catalog no. 2331), carboxymethylcellulose (Polyfarma catalog no.
1221), acid-swollen cellulose (obtained from microcrystalline cellulose [Merck
catalog no. 2331] as described previously [28]), maltose (Sigma catalog no.
M-5885), D-cellobiose (Sigma catalog no. C-7252), D-glucose (Synth catalog no.
32850), D-xylose (Sigma catalog no. X-1500), L-arabinose (Sigma catalog no.
A-3256), and D-galacturonic acid (Sigma catalog no. G-2125) were used.

Statistics. Each analysis was carried out four to nine times. The results are
expressed as means 6 standard deviations and were subjected to the Krustal-
Wallis test followed by the nonparametric Dunn’s test for multiple-column com-
parisons or to the Mann-Whitney test for two-column comparisons (30).

RESULTS

We used several polysaccharides as sole carbon sources for
L. gongylophorus CCT 6414. Depending on the substrate added
to YNB medium, the cell mass variation was 1.02 to 1.77
(Table 1). Growth was significantly faster on xylan or starch
than on pectin or different sources of cellulose. In a control
experiment with YNB alone, the cell mass variation was 0.65,

* Corresponding author. Mailing address: Centro de Estudos de
Insetos Sociais, Universidade Estadual Paulista, Av. 24A, 1515. Rio
Claro, SP. CEP 13506-900, Brazil. Phone: 011-55-19-534-8523. Fax:
011-55-19-534-0009. E-mail: mbacci@life.ibrc.unesp.br.

4820

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probably because of the consumption of stored fungal nutri-
ents.

After cultivation, reducing sugars were detected in culture
media with xylan, starch, or pectin but not in culture media
with different sources of cellulose. However, reducing sugars
could be detected in culture media with microcrystalline cel-
lulose or carboxymethylcellulose, in which cultivation was ex-
tended for 60 days (Table 1).

Enzyme activity was also determined in culture media after
30 days of cultivation (Table 1). After cell growth on pectin,
pectinase production was significantly higher than amylase or
xylanase production after culture on starch and xylan, respec-
tively. Cellulase or CMCase were not detected after 30 days of
cultivation on cellulose or its derivatives but could be esti-
mated after 60 days of cultivation.

Further information on L. gongylophorus metabolism was
obtained by culturing the fungus in some of the polysaccharide
hydrolysis products, the consumption of which was 57 to 170
mg (Table 2). Cell mass variation and growth efficiency on
these substrates varied, with high mean values for glucose and
xylose, intermediate values for maltose and cellobiose, and low
values for arabinose and galacturonic acid.

Cellulose metabolism was also evaluated in other strains of
L. gongylophorus. As was observed with CCT1, CCT2 and
CCT3 grew significantly more slowly on cellulose than on glu-
cose (Table 3) and failed to produce cellulase or detectable
amounts of reducing sugars after 30 days of cultivation on
cellulose.

DISCUSSION

Leaf-cutting ants must feed on their symbiotic fungus to
survive. Their dependence is such that the insect population
size is affected by the fungal growth rate (24). Thus, there must

be a means to transfer carbon from the vegetation to the
fungus and then to the ants.

Cellulose is often thought to be the central carbon source for
this integration (8). However, our results showed that L. gongy-
lophorus CCT 6414 grows poorly on cellulose, acid-swollen
cellulose, microcrystalline cellulose, or carboxymethylcellulose
(Table 1). Strains CCT 6415 and CCT 6416 also grew poorly on
cellulose (Table 3), indicating that a poor ability to metabolize
this polysaccharide is characteristic of the fungus symbiotic
with A. sexdens L. Microbial degradation of cellulose involves
endoglucanase, which randomly cleaves the polysaccharide;
exoglucanase, which breaks cellulose ends to originate cellobi-
ose and glucose; and b-glucosidase, which hydrolyzes cellobi-
ose (25). Since the fungus grows well on cellobiose and glucose
but slowly on cellulose (Tables 1 and 2), poor cellulose assim-
ilation is secondary to low glucanase production. Inefficient
metabolism of cellulose from various sources by L. gongylopho-
rus suggests a different scenario from that drawn by Martin and
Weber (15), who credit the symbiotic fungus of Atta colombica
tonsipes with the consumption of at least 45% of the cellulose
from leaves during vegetation processing in the ants’ nest.

Unlike cellulose, starch and xylan are likely to be rapidly
consumed from vegetation by L. gongylophorus. The fungus
could efficiently hydrolyze these polysaccharides (Table 1) and
assimilate the resulting xylose, maltose, and glucose (Table 2).
Cell mass production from xylan or starch was at least 13 times
faster than that from cellulose. A high growth rate on xylan and
starch may be important for the fungus to outcompete other
microorganisms in ant nests, such as bacteria (2, 19), yeasts (7),
and other fungi (11), some of which are able to metabolize leaf
polysaccharides (2, 22, 23). Leaves may contain up to 10%
starch (6) and 22% xylan (12), which could support fungal
growth in ant nests. Since ant nutrition relies on the fungus,

TABLE 1. Cell mass variation and reducing sugars and enzymes produced after 30 days of cultivation of L. gongylophorus CCT1
on polysaccharides

Carbon source Cell mass variation [mean (SD)]a Reducing sugar production (mg) [mean (SD)]a Enzyme activityb (mmol/g/h) [mean (SD)]a

Xylan 1.8 (0.13)1 47 (5.8)1,2 190 (56)1

Starch 1.7 (0.15)1 44 (26)1,2 620 (250)1

Pectin 1.3 (0.25)1,2 190 (25)1 4,600 (1,100)2

Cellulose 1.0 (0.06)2 NDc ND
Acid-swollen cellulose 1.1 (0.28)2 ND ND
Microcrystalline cellulose 1.0 (0.13)2 1.4 (1.1)2d 23 (5.7)1d

Carboxymethylcellulose 1.1 (0.11)2 29 (3.0)2d 120 (90)1d

None 0.65 (0.10)

a Values followed by distinct numbers are significantly different from each other (Dunn’s test).
b Enzyme activities assayed were xylanase after growth on xylan, amylase after growth on starch, pectinase after growth on pectin, CMCase after growth on

carboxymethylcellulose, and cellulase after growth on acid-swollen cellulose or microcrystalline cellulose.
c ND, not detected.
d Detected in 60-day cultures but not in 30-day cultures.

TABLE 2. Cell mass variation, substrate consumption, and growth efficiency after 30 days of cultivation of L. gongylophorus CCT1 on
polysaccharide hydrolysis products

Carbon source Cell mass variation [mean (SD)]a Consumption (mg) (mean
[SD])a Growth efficiency [mean (SD)]a

Glucose 1.9 (0.32)1 170 (26)1 12 (3.1)1

Xylose 1.8 (0.41)1 170 (42)1 12 (4.3)1

Maltose 1.5 (0.29)1,2 150 (21)1,2 4.7 (1.4)1,2

Cellobiose 1.4 (0.12)1,2 150 (21)1,2 4.4 (0.9)1,2

Arabinose 1.1 (0.08)2 57 (17)2 3.4 (2.1)2

Galacturonic acid 1.1 (0.05)2 130 (23)1,2 0.8 (0.6)2

a Values followed by distinct numbers are significantly different from each other (Dunn’s test).

VOL. 64, 1998 POLYSACCHARIDE METABOLISM IN L. GONGYLOPHORUS 4821

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xylan and starch are probably key carbon sources for insect
survival as well.

We were surprised at the high levels of pectinase that we
found and the efficient hydrolysis of pectin by the fungus (Ta-
ble 1). The levels of pectinase secreted were more than 7 times
higher than those of amylase, 24 times higher than those of
xylanase, 38 times higher than those of CMCase, and 200 times
higher than those of cellulase. Nevertheless, pectin did not
support rapid fungal growth (Table 1), a fact possibly explained
by the low efficiency of growth on galacturonic acid (Table 2),
which is the major pectin component (12).

Pectin is located in the intercellular space and acts as a
cement to aggregate leaf cells (29). Pectin degradation sepa-
rates plant cells from each other (5, 10) and has been suggested
as essential for fungal invasion of plant tissue (5, 9). Thus, the
high levels of pectinase and pectin degradation may be primar-
ily used by L. gongylophorus to macerate leaf tissue and access
its nutrients. Pectin from leaves, however, is probably poorly
assimilated by the fungus.

Once L. gongylophorus degrades and assimilates cellulose,
xylan, pectin, and starch, it is able to mediate the transferring
of carbon from leaves to the ants. This metabolic integration
may provide ants with solid plant material not otherwise avail-
able to them. It is important to note that there are factors that
may influence the ants’ utilization of leaf polysaccharides
through the fungus, including the kind of vegetation cut by the
ants, the modulation of fungal metabolism by the ants, com-
pounds liberated during leaf maceration, or competition by
other microorganisms for the leaf polysaccharides. However, if
L. gongylophoprus behavior in laboratory cultures typifies the
fungal role in the symbiosis, then xylan and starch rather than
cellulose would be the main leaf polysaccharides supporting
ant nutrition.

ACKNOWLEDGMENTS

This work was supported by Fundação de Amparo a Pesquisa do
Estado de São Paulo (FAPESP 95/04229-2), Conselho Nacional de
Desenvolvimento Cientı́fico e Tecnológico (CNPq 521472/94), and
Fundação para o Desenvolvimento da UNESP (FUNDUNESP 339/
94). C.G.S. was the recipient of fellowships from CNPq (208/91-7) and
FAPESP (95/9071-8).

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TABLE 3. Cell mass variation after 30 days of cultivation of
different L. gongylophorus strains on glucose or cellulose

Carbon source
Cell mass variation [mean (SD)]a

CCT 6414 CCT 6415 CCT 6416

Glucose 1.9 (0.32)1 1.9 (0.22)1 1.9 (0.18)1

Cellulose 1.0 (0.06)2 1.1 (0.18)2 1.1 (0.05)2

a Values followed by distinct numbers are significantly different from each
other (Mann-Whitney test).

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