Open access journal: http://periodicos.uefs.br/ojs/index.php/sociobiology
ISSN: 0361-6525

DOI: 10.13102/sociobiology.v63i4.1027Sociobiology 63(4): 1005-1014 (December, 2016)

Lipid Mobilization and Acyl-Coenzyme A Dehydrogenase Abundance in the Postpharyngeal 
Gland of a Leaf-Cutting Ant

Introduction

The Atta and Acromyrimex genera are popularly known 
as leaf-cutting ants, the most economically important ants. 
These ant species cut large amounts of fresh plant material 
to feed the symbiotic fungus Leucoagaricus gongylophorus 
Singer (M.), which in turn provides food for the larvae and 
in part for the adult (Hölldobler & Wilson, 1990). The fatty 
acids may come either from feeding fungi or sap. Fungi are 
rich in carbohydrates and protein, and low in lipids (Martin 
et al., 1969). Sap may be ingested by workers while they 
are cutting and trimming leaves and, therefore, take lipids 
directly (Quinlan & Cherrett, 1979). Therefore, studies have 
shown that the postpharyngeal glands (PPGs) are involved in 
lipid accumulation. PPG anatomy and lipid content were first 
described by Peregrine et al. (1972, 1973), Peregrine and Mudd 
(1974), Delage-Darchen (1976), and Vieira and Bueno (2015).

Abstract
The postpharyngeal gland (PPG) in ants has a central role in lipid 
accumulation. Our objective was to investigate whether the PPG of 
workers of the leaf-cutting ant Atta sexdens rubropilosa (F.) performs 
lipid mobilization to the hemolymph, and to verify whether lipids 
in gland cells are in part oxidized to acetyl-CoA. Increased levels 
of fatty acids were observed in both the PPG and the hemolymph 
after 48 h of lipid supplementation. In contrast, after 120 h of lipid 
supplementation, fatty acid levels were reduced in the PPG and 
significantly increased in the hemolymph. The gland cells of the PPG 
of workers supplemented with lipids exhibited a high amount of Acyl-
CoA dehydrogenase, and the lipids were in part β-oxidized to Acetyl-
CoA. These findings suggest that the PPG of A. sexdens rubropilosa 
workers mobilize fatty acids from their gland cells to the hemolymph. 
Further work will be needed to elucidate lipid transport from the 
hemolymph to other organs in this organism.

Sociobiology
An international journal on social insects

AS Vieira, OC Bueno

Article History

Edited by
Evandro Nascimento Silva, UEFS, Brazil
Received                        14 March 2016
Initial acceptance      08 June 2016
Final acceptance          15 December 2016
Publication date          13 January 2017

Keywords 
Attini, confocal microscopy, hemolymph, 
insects, GC-MS.

Corresponding author
Alexsandro Santana Vieira
Centro de Estudos de Insetos Sociais 
Instituto de Biociências - UNESP
Av. 24A, nº. 1515, Cx. Postal 199
CEP: 13506-900, Rio Claro-SP, Brasil
E-Mail: alexsvieira@yahoo.com.br

PPGs, the salivary system of ants, occur in pairs and 
are located dorsally in the transition between the pharynx and 
the esophagus regardless of sex, caste, or lifestyle (Hölldobler 
& Wilson, 1990; Caetano, 1998). PPGs are of ectodermal 
origin and form during post-embryonic development (late 
prepupal stage) from two dorsal evaginations of the pharyngeal 
epithelium (Gama, 1985; Janet, 1905). Until recently, PPGs 
were thought to be exclusive to Formicidae (Delage-Darchen, 
1976; Hölldobler & Wilson, 1990), but Herzner et al. (2007) 
found them in the solitary wasps Philanthus triangulum (F.), 
Ampulex compressa (F.), Trachypus boharti (R.-E.), and 
Trachypus elongatus (F.) (Herzner et al., 2011; 2013).

PPGs also play a role in lipid metabolism (Peregrine 
et al., 1972, 1973; Peregrine & Mudd 1974; Delage-Darchen, 
1976; Decio et al., 2016). In insects, the fat body is the central 
organ for lipid metabolism, synthesizing several proteins and 
also acting as the storage site for carbohydrates, proteins, and 

Universidade Estadual Paulista (UNESP), Rio Claro-SP, Brazil

RESEARCh ARTICLE - ANTS



AS Vieira; OC Bueno – Lipid and Acyl-CoA dehydrogenase in PPG of leaf-cutting ants1006

mainly lipids (Arrese & Soulages, 2010). However, the source 
of lipids in the PPG is controversial. One possibility is that 
lipids originate from secretions of the glandular epithelium 
itself. Another possibility is that it is taken up from the diet. 
Delage-Darchen (1976) proposed three hypotheses about the 
accumulation of lipid in PPGs: 1) transcellular route: lipids 
would penetrate the gland cells and be metabolized; 2) extra-
oral route: lipids would be regurgitated directly from the 
glands to other members of the colony; and 3) digestive 
route: lipids would flow from the glands to the crop and then 
to the midgut. Using labeled isotopes, Phillips and Vinson 
(1980) observed that, in Solenopsis invicta (B.), fatty acids 
and triacylglycerides injected into the hemolymph were not 
transferred to the PPGs, suggesting that lipids in this gland 
would be derived from food.

Delage-Darchen (1976) and Forbes and Macfarlane 
(1961) hypothesized that PPGs would be responsible for the 
digestion of ingested fats based on the presence of digestive 
enzymes such as lipases in the gland lumen (Peregrine et 
al., 1973; Vinson et al., 1980). The digestive route hypothesis 
proposed by Delage-Darchen (1976) was tested by Bueno 
(2005), which demonstrated that Atta sexdens rubropilosa 
workers were capable of separating, in the final portion of the 
pharynx, lipid from non-lipid compounds present in the ingested 
food. On a lipid-rich diet, these compounds would reach the 
PPGs and the non-lipid components (e.g., carbohydrates) 
would move to the crop, which would allow adults to use 
lipids available in nature (Bueno et al., 2008). Under extreme 
conditions, in which a large amount of lipid is offered to ants, 
some of it reaches the crop; however, sometime later, they 
return through the esophagus and enter the PPG (Phillips & 
Vinson, 1980; Wheeler, 1994; Jesus, 2006; Bueno et al., 2008). 
Moreover, using autoradiography, liquid scintillation counting, 
and tritiated oleic acid, Bueno (2005) showed that lipids are 
mobilized into the lumen of glands of A. sexdens rubropilosa 
workers and queens, with subsequent absorption by the gland 
epithelium. However, little is known about the presence of 
fatty acids in the hemolymph. Therefore, the transcellular 
route hypothesis of Delage-Darchen (1976) should be tested: 
is the PPG of workers of the leaf-cutting ant A. sexdens 
rubropilosa capable of mobilizing lipids to the hemolymph?

In this way, the present study aimed to investigate 
whether the PPG of workers of the leaf-cutting ant A. sexdens 
rubropilosa performs lipid mobilization to the hemolymph. 
Workers of A. sexdens rubropilosa ants supplemented with 
lipids showed an increase in the amount of mitochondria and 
peroxisomes within PPG cells compared to those without 
supplement (Vieira & Bueno, 2015) so, another aimed to 
verify whether lipids are in part oxidized to Acetyl-CoA in 
the mitochondria of gland cells.

Material and Methods

Part I – Gas chromatography/mass spectroscopy – lipid 
mobilization to the hemolymph

Bioassays I

Medium workers of A. sexdens rubropilosa were 
divided into three groups. Group BLS (before lipid supplement) 
received a pure diet and groups ALS (after lipid supplement) 
received pure diet with lipid supplementation for 48 h and 120 
h. The pure diet consisted of 5 % glucose, 1 % casein peptone, 
0.1 % brewer’s yeast extract, and 1.5 % bacteriological agar. 
The diet of groups ALS consisted of 0.3 mL of soybean oil 
in 30 mL of pure diet. Each group contained 50 individuals 
that were placed in five Petri dishes (10 ants in each dish), 
and 0.5 g of supplementation was added daily to each dish for 
25 days. The dishes were kept in a chamber incubator (BOD, 
Biochemistry Oxygen Demand) at 25 ± 1 °C and at a relative 
humidity of 70 %. Five replicates were performed for each 
experimental group.

Chromatographic analysis was performed using 
medium workers of the group BLS, ALS 48 h and ALS 120 h. 
A total of 114 workers were used for this analysis, or 57 ants 
for each extraction (hemolymph and PPG): 18 ants for group 
BLS, 18 for group ALS 48 h, and 18 for group ALS 120 h.

The hemolymph of the workers was extracted by 
capillarity. With a microcapillary tube, 0.5 to 0.75 µL of 
hemolymph was extracted from the neck region of each ant 
and placed in vials. Each vial contained hemolymph from 
three ants, totaling six vials per group. After extraction, 0.5 
mL of acetone was added to each vial.

PPGs from ants fed with and without lipid 
supplementation were extracted and three glands were placed 
in each vial, resulting in six vials per group; 0.5 mL of acetone 
was added to each vial and the PPGs were then macerated. 

Fischer Esterification (Methylation)

Fischer esterification is a special type of esterification 
by refluxing a carboxylic acid and an alcohol in the presence 
of an acid catalyst (Fischer & Speier, 1895). In our study, the 
hydrolysis of lipids through esterification was performed to 
obtain the corresponding fatty acid ester and thus facilitate its 
movement through the injector and chromatography column 
in the gas phase chromatography. Due to the esterification 
process, the fatty acids were identified in their ester form.

Samples underwent Fischer esterification prior 
to chromatographic analysis. The vials containing the 
hemolymph and the macerated PPGs were left half open to 
allow evaporation of acetone in an infrared weighing-machine 
at 60 °C (for approximately 20 min). A saponification 
reaction was carried out by adding 0.3 mL of 0.5 N KOH in 
anhydrous methanol, and the mixture was then homogenized 
and incubated at 60 °C for 20 min. The esterification reaction 
was initiated by the addition of 0.5 mL of 0.9 N H2SO4 in 
anhydrous methanol, and the mixture was homogenized and 
incubated at 60 °C for 20 min. Next, 1 mL of hexane was 
added for spectrometry and the mixture homogenized. A 
biphasic solution was obtained, and 50 µL were taken from 



Sociobiology 63(4): 1005-1014 (December, 2016) 1007

the upper (aqueous) phase and placed in a new vial. The 
contents were then diluted with 450 µL of hexane, and 1 µL 
was injected into the gas chromatograph.

Gas Phase Chromatography - Mass Spectrometry

Chemical analyses were conducted at the Laboratory 
of Apicultural Products (Laboratório de Produtos Apícolas), 
Center for Studies of Social Insects (Centro de Estudos de 
Insetos Sociais - CEIS), using a gas chromatograph GC-210 
(Shimadzu Scientific Instruments, Japan) equipped with an 
RTX MS capillary column (30 m × 0.25 mm ID, 0.25-μm thick 
film) coupled to a mass-selective detector (Shimadzu GCMS-
QP2010 Plus). The gas chromatograph was connected to a 
computer and the data were processed using GCMSsolution 
software version 2.5. Elution was carried out with helium at 1 
mL/min. Samples were injected using the splitless mode (port 
temperature: 250 °C) and held for 1 min. The temperature of 
the column was set to start at 160 °C for 5 min, increase to 
200 °C at 5 °C/min, remain at 200 °C for 3 min, increase to 
280 °C at 8 °C/min, and remain at 280 °C for 6 min. The mass 
spectrometer was operated in the Electron Ionization mode 
at 70 eV, with a scanning range of 40 to 500 m/z. To allow 
sample identification and quantification, a calibration curve 
was obtained using fatty acid standards (lauric, myristic, 
palmitic, linoleic, oleic, stearic, and erucic acid) from Sigma-
Aldrich at the following concentrations: 0.5, 1, 2, 3, and 5 ppm.

Statistics

After testing the data for normality, analysis of variance 
(ANOVA) was conducted with a significance level of 5 % 
(0.05) between group BLS and groups ALS 48 h and ALS 
120 h. When significant differences were observed, a pairwise 
Tukey test was performed to check which groups were 
different from each other using Statistical software version 7. 

Part II - Confocal Microscopy - β-oxidation of fatty acids

Bioassays II 

Medium workers were divided into three groups 
of 24 individuals: two groups were fed a diet without lipid 
supplementation and starved for 48 h (FAST 48 h) and 120 h 
(FAST 120 h), whereas two groups were fed a diet supplemented 
with 2 µL soybean oil placed in the mouthparts and starved for 
48 h (LIPID 48 h). Workers were placed individually in plastic 
containers (200 mL) and kept in a BOD incubator under 
controlled conditions (25 ± 1 °C; relative humidity of 70 %). 
Workers were anesthetized by cooling (4 °C) for a few min, 
their heads were removed and placed in Petri dishes, and PPGs 
were dissected in insect saline solution (0.128 M NaCl, 0.016 M 
Na2HPO4, and 0.019 M KH2PO4, pH 7.2) under a stereomicroscope 
using fine-tipped tweezers and surgical microscissors. 

Confocal Laser Scanning Microscopy – immunofluorescence of 
the enzyme acyl-CoA dehydrogenase - β-oxidation of fatty acids

PPGs from groups FAST 48 h, FAST 120 h, and 
LIPID 48 h were used. After dissection, 24 glands were fixed 
in 4 % paraformaldehyde for 30 min and then permeabilized 
with 0.1 % Triton® X-100 for 30 min. The glands were 
incubated at 4 °C for 16 h with 10 μg/mL of anti-acyl-CoA 
dehydrogenase primary mouse monoclonal antibody (very 
long-chain acyl-CoA dehydrogenase, VLCAD, monoclonal 
antibody, Molecular Probes). Cy5-conjugated goat anti-mouse 
IgG (H+L) (Molecular Probes) diluted 1:1,000 and incubated 
for 1 h was used as secondary antibody. At all stages, 10 % 
goat serum was used as a blocking agent. Cell nuclei were 
counterstained with DAPI (4 ‘,6-diamino-2-fenilindol).

Immunofluorescence from VLCAD and nuclei (DAPI) 
in the PPGs were recorded in a confocal laser scanning 
microscope LSM780-NLO (Zeiss). Fluorescent images were 
obtained using lasers with 405 nm and 633 nm excitation 
wavelengths. Optical sections were acquired in a suitable 
Z-axis sectioning step (0.63 µm and 0.67 µm). Photography 
parameters were the same for all groups to quantify the 
emitted fluorescence intensity and to acquire images of the 
total gland area. ImageJ software and different modules of the 
Zeiss LSM780-NLO software were used for image analysis, 
including maximum projection (join all Z-axis sectioning step 
sizes). Fluorescence emission of PPG without incubation with 
primary antibody but only with Cy5 secondary antibody was 
used as negative control.

Statistical Analysis

Fluorescence emitted (grayscale) by 
immunofluorescence of the acyl-CoA dehydrogenase enzyme 
was quantified using ImageJ software. Using BioEstat 
statistical software, the Shapiro-Wilk test was carried out 
to assess normal distribution of data, and then the one-way 
ANOVA parametric statistical test was performed.

Results

Lipid mobilization to the hemolymph

Overall, four fatty acids (C16, C18:2, C18:1, and C18) 
were present in both the hemolymph and PPG of ants from 
groups BLS and ALS. Only two fatty acids, C16 and C18, 
were found in group BLS (Table 1, Fig 1A, 1B, and 1C).  

Fatty acids
BLS

Hemolymph 
(ppm)

Hemolymph 
(%)

PPG
(ppm)

PPG
(%)

Palmitic acid 0.04716 53.43 0.06840 49.99
Linoleic acid 0 0 0 0
Oleic acid 0 0 0 0
Stearic acid 0.04110 46.57 0.06844 50.01
Total 0.08826 100 0.13685 100

Table 1. Fatty acid quantification in the hemolymph and 
postpharyngeal glands (PPG) of Atta sexdens rubropilosa workers 
before lipid supplementation (BLS).



AS Vieira; OC Bueno – Lipid and Acyl-CoA dehydrogenase in PPG of leaf-cutting ants1008

In addition to C16 and C18, two other fatty acids, C18:2 and 
C18:1, were found in the hemolymph and PPG in groups ALS 
48 h and ALS 120 h (Tables 2 and 3; Fig 1B and 1C).

Fatty acid content in the hemolymph increased 
considerably in groups ALS 48 h and ALS 120 h. Interestingly, 
fatty acid content increased in the PPG in the first 48 h of lipid 

Fig 1. Chromatographic analysis of fatty acids in the hemolymph and postpharyngeal glands (PPG) of Atta sexdens 
rubropilosa workers. A. Group of workers before lipid supplementation (BLS). B. Group of workers after lipid 
supplementation for 48 h (ALS 48 h). C. Group of workers after lipid supplementation for 120 h (ALS 120 h). 1, 
palmitic acid; 2, stearic acid. Arrows indicate a saturated hydrocarbon (alkane) with different retention times. 



Sociobiology 63(4): 1005-1014 (December, 2016) 1009

supplementation, but decreased after 120 h (Tables 1 to 3).
Palmitic Acid - C16. C16 was the predominant fatty 

acid in the hemolymph in group BLS (Table 1; Fig 1A), 
whereas in groups ALS 48 h and ALS 120 h it corresponded 
to the second and third most abundant fatty acid, respectively 
(Tables 2 and 3; Figs 1B and 1C). C16 was the second most 
abundant fatty acid in the PPG in group BLS (Table 1; Fig 
1A), and the third most abundant in groups ALS 48 h and 
ALS 120 h (Tables 2 and 3; Fig 1B and 1C). 

Linoleic Acid (C18:2). C18:2 was absent from the 
hemolymph in group BLS (Table 1; Fig 1A), whereas it was 
the predominant fatty acid in groups ALS 48 h and ALS 120 
h (Tables 2 and 3; Fig 1B and C). C18:2 was also absent 
from the PPG in group BLS (Table 1; Fig 1A), but it was the 
predominant fatty acid in groups ALS 48 h and ALS 120 h 
(Tables 2 and 3; Fig 1B and 1C).

Oleic Acid (C18:1). C18:1 was absent from the 
hemolymph in group BLS (Table 1; Fig 1A). On the other 
hand, this fatty acid was the third and second most abundant 
in groups ALS 48 h and ALS 120 h, respectively (Tables 
2 and 3; Fig 1B and 1C). C18:1 was also absent from the 
PPG in group BLS (Table 1; Fig 1A), but it was the second 
most abundant fatty acid in groups ALS 48 h and ALS 120 h 
(Tables 2 and 3; Fig 1B and 1C).

Stearic Acid (C18). Ants of group BLS showed C18 as 
the second most abundant fatty acid in the hemolymph (Table 
1; Fig 1A). C18 was the fourth most abundant fatty acid in 
groups ALS 48 h and ALS 120 h (Tables 2 and 3; Fig 1B 
and 1C). C18 was the predominant fatty acid in the PPG in 
group BLS (Table 1; Fig 1A), but it was only the fourth most 
abundant in groups ALS 48 h and ALS 120 h (Tables 2 and 
3; Fig 1B and 1C).

Hydrocarbons (HC). As can be seen in Figure 1A, two 
HCs identified as alkanes were detected in the PPG in group 
BLS. HCs were also observed in ants of groups ALS 48 h and 
ALS 120 h, although with a smaller area than that in group 
BLS (Fig 1B and 1C).

One-way ANOVA revealed a statistically significant 
difference in fatty acid content in the hemolymph of groups 
ALS 48 h and ALS 120 h (F = 6.9161, p = 0.0151) in 
comparison with group BLS (Fig 2). A posteriori Tukey test 
revealed a statistically significant difference between groups 

Fatty acids
ALS 48 H

Hemolymph
(ppm)

Hemolymph
(%)

PPG
(ppm)

PPG
(%)

Palmitic acid 0.03918 21.22 0.50576 9.36
Linoleic acid 0.07802 42.25 3.03704 56.18
Oleic acid 0.03816 20.67 1.55904 28.84
Stearic acid 0.02929 15.86 0.30375 5.62
Total 0.18465 100 5.40559 100

Table 2. Fatty acid quantification in the hemolymph and 
postpharyngeal glands (PPG) of Atta sexdens rubropilosa workers 
after lipid supplementation for 48 h (ALS 48 h). 

Fatty acids
ALS 120 H

Hemolymph
(ppm)

Hemolymph
(%)

PPG
(ppm)

PPG
(%)

Palmitic acid 0.12077 19.94 0.45538 9.59
Linoleic acid 0.26897 44.41 2.65249 55.85
Oleic acid 0.14476 23.90 1.35750 28.58
Stearic acid 0.07113 11.75 0.28409 5.98
Total 0.60563 100 4.74946 100

Table 3. Fatty acid quantification in the hemolymph and 
postpharyngeal glands (PPG) of Atta sexdens rubropilosa workers 
after lipid supplementation for 120 h (ALS 120 h). 

Fig 2. Mean concentration (ppm) and standard deviation of fatty 
acid content in the hemolymph in groups of workers before lipid 
supplementation (BLS) and after lipid supplementation (ALS 
48 h and ALS 120 h). Bars marked with the same letter show no 
statistically significant difference (p > 0.05); bars marked with 
different letters show statistically significant differences (p < 0.05). 
P values below 5 % were considered significant. 

A statistically significant difference in fatty acid 
content was found in PPGs of ants in group BLS compared 
to that in groups ALS 48 h and ALS 120 h (F = 13.6607; 
p = 0.0001). A posteriori Tukey test revealed a statistically 
significant difference between group BLS and groups ALS 48 
h and ALS 120 h (p < 0.01), but not between group ALS 48 h 
and group ALS 120 h (Fig 3). The same pattern was found for 
individual fatty acids (Table 4). A schematic representation of 
lipid mobilization from the PPG to the hemolymph after lipid 
supplementation in leaf-cutting ants is shown in Fig 4.

β-oxidation of fatty acids

The PPGs of A. sexdens rubropilosa medium workers 
have two lobes (named left and right). These lobes have 
digitiform prolongations formed by a simple epithelium 
composed of epithelial cells with large, round nuclei (shown in 
Fig 5 in blue). Indirect immunofluorescence analysis of PPGs 

BLS and ALS 120 h (p < 0.05), as well as between groups ALS 
48 h and ALS 120 h (p < 0.05). Although fatty acid content 
increased from group BLS to group ALS 48 h, no statistically 
significant difference was found between these groups (Fig 2).



AS Vieira; OC Bueno – Lipid and Acyl-CoA dehydrogenase in PPG of leaf-cutting ants1010

Fig 4. Schematic representation of lipid mobilization from 
the postpharyngeal gland (PPG) to the hemolymph after lipid 
supplementation in the leaf-cutting ant Atta sexdens rubropilosa. 
Lipids from the diet are forwarded (white arrow) to the lumen (L) 
of a digitiform prolongation in the PPG and arrive at the secretory 
cell (SC) after crossing the cuticle (cut). Once inside the cell, lipids 
are mobilized (black arrow) to the hemolymph. Fatty acids identified 
by GC-MS are shown as colored ovals: C16, green; C18, yellow; 
C18:1, blue; C18:2, black. Oval size is proportional to the amount 
of fatty acid detected.

Fatty acids 
- PPG

ANOVA
Tukey

BLS and 
ALS 48 h

BLS and 
ALS 120 h

ALS 48 h and
ALS 120 h

Palmitic 
acid

F(2.15) = 26.952, 
p < 0.01

p < 0.01 p < 0.01 p > 0.05

Linoleic 
acid

F(2.15) = 24.426, 
p < 0.01

p < 0.01 p < 0.01 p > 0.05

Oleic acid
F(2.15) = 33.718, 
p < 0.01

p < 0.01 p < 0.01 p > 0.05

Stearic 
acid

F(2.15) = 32.302, 
p < 0.01

p < 0.01 p < 0.01 p > 0.05

P values below 5 % were considered significant.

Table 4. One-way ANOVA of fatty acid content in the 
postpharyngeal gland (PPG) of A. sexdens rubropilosa workers 
between groups before lipid supplementation (BLS) and after lipid 
supplementation (ALS) for 48 and 120 h. P values below 5 % were 
considered significant. 

of A. sexdens rubropilosa workers revealed a low fluorescence 
intensity, and therefore a low acyl-CoA dehydrogenase 
abundance, in cells of the digitiform prolongation in the PPGs 
in groups FAST 48 h and FAST 120 h (Fig 5A to 5D, red). 
In contrast, a strong fluorescence signal was detected in the 
PPGs of group LIPID 48 h, indicating an abundance of acyl-
CoA dehydrogenase in these cells (Fig 5E and 5F, red).

After quantification of the emitted fluorescence intensity, 
statistical analysis was performed. A statistically significant 
difference was found between groups with (LIPID 48 h) and 
without (FAST 48 h and FAST 120 h) lipid supplementation 
(F = 7.978; p = 0.0065). A posteriori pairwise Tukey test 
revealed a significant difference between groups FAST 48 h 
and LIPID 48 h (p < 0.05), as well as between groups FAST 
120 h and LIPID 48 h (p < 0.01) (Fig 6). P values below 5 % 
were considered significant.

Fig 3. Mean concentration (ppm) and standard deviation of the fatty 
acid content in the postpharyngeal gland (PPG) in groups before 
lipid supplementation (BLS) and after lipid supplementation (ALS 
48 h and ALS 120 h). Bars marked with the same letter show no 
statistically significant difference (p> 0.05); bars marked with different 
letters show statistically significant differences (p < 0.01). P values 
below 5 % were considered significant.

Fig 6. One-way ANOVA analysis of fluorescence intensity (values 
in grey scale) reflecting acyl-CoA dehydrogenase abundance in the 
measured areas of a gland cell of postpharyngeal glands of Atta 
sexdens rubropilosa workers in groups without (FAST 48 and FAST 
120 h) and with (LIPID 48 h) lipid supplementation. Bars marked 
with the same letter show no statistically significant difference (p > 
0.05); bars marked with different letters show statistically significant 
differences (p < 0.05). P values below 5 % were considered significant.



Sociobiology 63(4): 1005-1014 (December, 2016) 1011

Discussion

The presence of lipid inside PPGs has been observed 
in several ant species, and its origin is controversial. One 
possibility is that lipid would originate from secretions of the 
glandular epithelium itself; others believe it comes from food. 

Our study has shown that A. sexdens rubropilosa workers 
from group BLS contained two fatty acids (C16 and C18) 
both in the PPG and hemolymph. Fatty acids may come 
either from feeding the fungi or from sap. Fungi are rich in 
carbohydrates and protein, but poor in lipids (Martin et al., 
1969). Workers may ingest sap during cutting and trimming 

Fig 5. Confocal microscopy analysis of postpharyngeal glands (PPG) of Atta sexdens rubropilosa workers 
showing the fluorescence emitted (Cy5) by immunofluorescence of Acyl-CoA dehydrogenase (red) and 
stained (DAPI) nuclei (blue). A-B. Digitiform prolongation of the PPG of a worker from group FAST 
48 h showing nuclei and the low abundance of Acyl-CoA dehydrogenase in gland cells. C-D. Digitiform 
prolongation of the PPG of a worker from group FAST 120 h showing nuclei and the low abundance of Acyl-
CoA dehydrogenase in gland cells. E-F. Digitiform prolongation of the PPG of a worker from group LIPID 
48 h showing nuclei and the high abundance of Acyl-CoA dehydrogenase in gland cells.



AS Vieira; OC Bueno – Lipid and Acyl-CoA dehydrogenase in PPG of leaf-cutting ants1012

leaves, and, therefore, lipids may be taken directly (Quinlan 
& Cherrett, 1979). The two fatty acids (C16 and C18) we 
have detected in the PPG may thus be obtained either from 
fungal food or from cutting leaves.

In previous studies using cytochemical ultrastructural 
analysis, Vieira and Bueno (2015) observed lipid droplets in 
the basal plasma membrane near the hemolymph. Our study 
demonstrated that when ants were supplemented with lipids 
(groups ALS 48 h and ALS 120 h), two additional fatty acids 
(18:2 and C18:1) were found both in the PPG and hemolymph. 
These results are in agreement with the transcellular route 
hypothesis of Delage-Darchen (1976), in which lipids go 
from the lumen to the gland cells and are then metabolized. 
Phillips and Vinson (1980) observed in S. invicta that fatty 
acids and triacylglycerides injected into the hemolymph 
did not reach the interior of the PPGs. According to Arrese 
and Soulages (2010), in insects, lipids from food reach the 
digestive tract and are then transported by lipoproteins to 
the fat body for storage. After metabolization of these lipids 
according to nutritional needs, they are transported to the 
hemolymph and from there distributed to the tissues. We 
suggest that lipids reach the hemolymph from the PPG after 
lipid supplementation. The PPG would therefore be capable 
of storing lipids and of secreting them into the hemolymph, 
from which these molecules can be stored in the fat body.

The entry of lipids into the PPGs and subsequent 
mobilization to the hemolymph requires some type of 
hydrolysis. The hydrolysis of triacylglycerol to free fatty acids 
may initially involve lipases (Alberts et al., 2010). Lipases have 
not been found in the PPGs of Acromyrmex octospinosus (F.) 
(Febvay & Kermarrec, 1986), and α-glucosidase and esterase 
were detected at low levels in the PPG. The authors suggested 
that this gland does not have a digestive function, as hypothesized 
by Delage-Darchen (1976). It has been shown that lipids from 
the diet go straight to the PPG and that, when large amounts of 
lipids are offered to ants, some of it reaches the crop, but not 
the midgut (Bueno et al., 2008). Erthal et al. (2004) detected 
α-glucosidase as the most abundant enzyme in the midgut of 
leaf-cutting ants, indicating that it is probably involved in glucose 
assimilation from nutrient sources such as maltose and sucrose 
present in plant material. Decio et al. (2016) showed that the 
PPG is an organ specialized for lipid nutrition in leaf-cutting ants, 
and this organ is responsible for lipid metabolism in A. sexdens 
rubropilosa. Furthermore, two proteins responsible for lipid 
transport in PPG cells, long-chain fatty acid transport protein and 
fatty acid binding protein, were shown to be present in higher 
amounts in ants fed with lipid supplementation than in ants fed 
without lipid supplementation (Decio et al., 2016). These proteins 
act as carriers and direct the mobilization of lipids into or out of 
the cell (Börchers & Spener, 1994; Schaffera & Lodish, 1994). 
Based on our results, we believe that the PPG of leaf-cutting ants 
is also specialized in lipid mobilization to the hemolymph. 

Statistical analysis showed that lipid supplementation 
caused fatty acid accumulation in the PPG during the 

first 48 h, with moderate mobilization of individual fatty 
acids to the hemolymph. However, after 120 hours of lipid 
supplementation, mobilization of fatty acids to the hemolymph 
was greatly increased, with a concomitant decrease in fatty 
acid content in the PPG. These results are in agreement 
with those described by Bueno (2005), in which A. sexdens 
rubropilosa workers fed on tritiated oleic acid showed a 
decrease in lipid content in the PPG after 120 h. Therefore, 
our results indicate that lipid mobilization from the PPG to 
the hemolymph occurs after some time, and that this delay 
reflects the storage capacity of its gland cells. 

Since the abundance of different fatty acids in the PPG 
and the hemolymph vary between groups BLS and ALS, we 
believe that lipid mobilization from the PPG to the hemolymph 
may depend on both the nutritional needs and the resources 
available to A. sexdens rubropilosa workers. Furthermore, 
C18:1 and C18:2 in group ALS may be used as vehicles for 
active ingredients in the chemical control of leaf-cutting ants. 
Corroborating this idea, we detected C18:2 as the most 
abundant fatty acid in both the hemolymph and PPG in groups 
ALS 48 and ALS 120 h, whereas C18:1 was the second most 
abundant. Thus, after lipid supplementation, C18:2 becomes 
the main fatty acid in the PPG and hemolymph of A. sexdens 
rubropilosa workers. Toxicological bioassays conducted 
with hydramethylnon diluted in soybean oil and A. sexdens 
rubropilosa (Sumida, 2007; Decio et al., 2013) showed a 
possible alternative route of ingestion of this active ingredient 
in the PPGs of leaf-cutting ants with increased pesticide action.

The presence of hydrocarbons (alkanes) in the PPGs 
of groups BLS, ALS 48 h, and ALS 120 h may result from 
allogrooming or from the cuticle. Soroker et al. (1998) and 
Morgan (2008) showed that hydrocarbon mobilization to the 
PPG could occur by allogrooming. A study on hydrocarbon 
biosynthesis in Cataglyphis niger (A.) showed that some 
lipids, but not hydrocarbons, are synthesized in the gland 
(Soroker & Hefetz, 2000). Still, Bagnères and Morgan (1991) 
demonstrated that, in several ant species, the PPGs contain 
the same substances that are found in the cuticle, i.e., mainly 
long-chain acids and esters. It is possible that the presence of 
hydrocarbons in the PPG of A. sexdens rubropilosa reflects 
the fact that this organ is of ectodermal origin, i.e., it has a 
cuticle, and that these alkanes originate from the cuticle.

The most abundant organelles in PPGs are 
mitochondria, distributed throughout the cytoplasm. In the 
PPG of Camponotus rufipes (F.), Dinoponera australis (E.), 
and Dinoponera quadriceps (K.), mitochondria are elongated 
and show different sizes (Falco, 1992; Schoeters & Billen, 
1997). Recent studies by Vieira and Bueno (2015) have found 
an increase in the number of peroxisomes and mitochondria 
in gland cells of the PPG of A. sexdens rubropilosa workers 
when subjected to lipid supplementation. The mitochondrial 
organelle is responsible for the β-oxidation of fatty acids 
to Acetyl-CoA, which then enters the citric acid cycle to 
be further oxidized and generate ATP (Alberts et al., 2010; 



Sociobiology 63(4): 1005-1014 (December, 2016) 1013

Nelson & Cox, 2014). Decio et al. (2016) showed that part of 
the lipids in the PPG of mated females are used as substrate 
for the synthesis of Acetyl-CoA. Based on these findings, 
we investigated the β-oxidation of fatty acids in the PPG of 
workers and the results were surprising: they show a low 
abundance of Acyl-CoA dehydrogenase in PPG cells of 
workers in groups FAST 48 h and FAST 120 h, and a high 
abundance in group LIPID 48 h. PPGs of both the mated 
females (Decio et al., 2016) and the A. sexdens rubropilosa 
workers in our study metabolized part of the lipids by 
β-oxidation. We hypothesize that the energy produced in 
gland cells by β-oxidation is necessary for lipid mobilization 
between the PPG and the hemolymph.

Finally, we conclude that the PPG of A. sexdens 
rubropilosa workers mobilize fatty acids from their gland 
cells to the hemolymph. Therefore, in addition to performing 
lipid metabolism (Decio et al., 2016), the PPG is also an organ 
specialized in lipid mobilization to the hemolymph. Further 
work will be needed to elucidate lipid transport from the 
hemolymph to other organs in this organism.

Acknowledgements

We thank technician Sebastião Zanão from the Gas 
Chromatography - Mass Spectrometry Laboratory (UNESP) 
for his help with the protocol and handling of the equipment 
and technician Mariana Ozello Baratti from the Confocal 
Microscopy Laboratory INFABIC-UNICAMP, Campinas, 
SP, Brazil. We also thank the São Paulo Research Foundation 
(FAPESP) (Grant 2012/12541-3) and the National Council 
for Scientific and Technological Development (CNPq) (Grant 
157837/2015-7) for financial support.

References

Alberts, B., Johnson, A. & Walter, P. (2010). Biologia 
Molecular da Célula, vol. 1054 (5). Artmed, Porto Alegre.

Arrese, E.L. & Soulages, J.L. (2010). Insect fat body: energy, 
metabolism, and regulation. Annual Review of Entomology, 
55: 207-225. doi: 10.1146/annurev-ento-112408-085356

Bagnères, A.-G. & Morgan, E.D. (1991). The postpharyngeal 
gland and the cuticle of Formicidae contain the same 
characteristic hydrocarbons. Experientia (Basel), 47: 106-111.

Börchers, T., Spener, F. (1994). Fatty acid binding proteins. 
In: Hoekstra D. editor. Cell Lipids. London: Academic Press. 

Bueno, O.C., Morini, M.S.C., Pagnocca, F.C., Hebling, 
M.J.A. & Silva, O.A. (1997). Sobrevivência de operárias de 
Atta sexdens rubropilosa Forel (Hymenoptera: Formicidae) 
isoladas do formigueiro e alimentadas com dietas artificiais 
Anais da Sociedade Entomológica do Brasil, 26: 107-112. 

Bueno, O.C. (2005). Filtro infrabucal e glândulas pós-faríngeas 
da saúva-limão Atta sexdens rubropilosa Forel (Hymenoptera, 

Formicidae). 107f. Tese (Livre-Docência) – Instituto de 
Biociências, Universidade Estadual Paulista “Júlio de 
Mesquita Filho”, Rio Claro. 

Bueno, O.C., Bueno, F.C., Diniz, E.A. & Schneidar, M.O. 
(2008). Utilização de alimento pelas formigas-cortadeiras. In: 
Vilela, E. F. (ed) et al. Insetos Sociais: da biologia a aplicação. 
Viçosa: UFV, p. 96-114.

Caetano, F.H. (1998). Aspectos ultramorfológicos, ultra-
estruturais e enzimológicos da glândula pós-faríngea de 
Dinoponera australis (Formicidae: Ponerinae). 137f. Tese 
(Livre-Docência), Instituto de Biociências, Universidade 
Estadual Paulista “Júlio de Mesquita Filho”, Rio Claro.

Decio, P., Silva-Zacarin, E.C.M., Bueno, F. & Bueno, 
O.C. (2013). Toxicological and histopathological effects of 
hydramethylnon on Atta sexdens rubropilosa (Hymenoptera: 
Formicidae) workers. Micron, 45: 22–31. doi: 10.1016/j.
micron.2012.10.008

Decio P., Vieira, A.S., Dias, N.B., Palma, M.S., Bueno, 
O.C. (2016). The Postpharyngeal Gland: Specialized Organ 
for Lipid Nutrition in Leaf-Cutting Ants. PLOS ONE 11(5): 
e0154891. doi:10.1371/ journal.pone.0154891

Delage-Darchen, B. (1976). Les glandes postpharyngeal dês 
fourmis connaissances actuellessur leur structure, leur 
fonctionnement, leur rôle. L'Année Biologique, 15(1-2): 63-76.

Erthal, M.Jr., Silva, C.P. & Samuels, R.I. (2004). Digestive 
enzymes of leaf-cutting ants, Acromyrmex subterraneus 
(Hymenoptera: Formicidae: Attini): distribution in the gut of 
adult workers and partial characterization. Journal of Insect 
Physiology, 50: 881–891. doi: 10.1016/j.jinsphys.2004.06.009

Falco, J.R. (1992). Comparação ultraestrutural entre 
glândulas pós-faríngeas de Camponotus rufipes (Hymenoptera: 
Formicidae) parasitadas e não por nematoides, 70f. Trabalho 
de Conclusão de Curso (Ciências Biológicas) – Instituto 
de Biociências, Universidade Estadual Paulista “Júlio de 
Mesquita Filho”, Rio Claro.

Febvay, G. & Kermarrec, A, (1986). Digestive Physiology of 
leaf-cutting ants. In: Lof-gren, C.S., Vander Meer, R.K. (Eds.), 
Fire ants and leaf-cutting ants: Biology andmanagement. 
Westview Press, Boulder, pp. 274–285.

Fischer, E. & Speier, A. (1895). “Darstellung der Ester”. 
Chem. Ber., 28: 3252-3258.

Forbes, J. & Mcfarlane, A.M. (1961). The comparative 
anatomy of digestive glands in the female castes and the 
male of Camponotus pennsylvanicus Degeer (Formicidae, 
Hymenoptera). Journal of the New York Entomological 
Society, 69: 92-103.

Gama, V. (1985). O sistema salivar de Camponotus 
(Myrmothrix) rufipes (Fabricius, 1775), (Hymenoptera: 
Formicidae). Revista Brasileira de Biologia, 45: 317-359.



AS Vieira; OC Bueno – Lipid and Acyl-CoA dehydrogenase in PPG of leaf-cutting ants1014

Herzner, G., Goettler, W., Kroiss, J., Purea, A., Webb, A.G., 
Jakob, P.M., Rössler, W. & Strohm, E. (2007). Males of a 
solitary wasp possess a postpharyngeal gland. Arthropod 
Structure & Development, 36: 123-133.

Herzner, G., Ruther, J., Goller, S., Schulz, S., Goettler, 
W. & Strohm, E. (2011). Structure, chemical composition 
and putative function of the postpharyngeal gland of the 
emerald cockroach wasp, Ampulex compressa (Hymenoptera, 
Ampulicidae). Zoology [S.I.], 114: 36–45. doi: 10.1016/j.
zool.2010.10.002.

Herzner,   G., Kaltenpoth, M., Poettinger, T., Weiss, K., 
Koedam, D., Kroiss, J. & Strohm, E. (2013). Morphology, 
Chemistry and Function of the Postpharyngeal Gland in 
the South American Digger Wasps Trachypus boharti and 
Trachypus elongates. PLOS ONE, 8(12): e82780. doi:  10.1371/
journal.pone.0082780

Hölldobler, B. & Wilson, E.O. (1990). The ants. London: 
Springer, 732p.

Janet, C. (1905) Anatomie de la tête du Lasius niger. Paris: 
Limoges Impremeire-libraire. Ducourtieux et Gout, 40p.

Jesus, C.M. (2006). Utilização de alimentos contendo 
substâncias lipídicas e açucaradas por formigas urbanas. 99 f. 
Dissertação (Mestrado) - Instituto de Biociências, Universidade 
Estadual Paulista “Júlio de Mesquita Filho”, Rio Claro, SP.

Nelson, D.L. & Cox, M.M. (2014). Princípios de bioquímica 
de Lehninger. Porto Alegre: Artmed, 6. ed. Porto Alegre: 
Artmed.

Martin, M.M., Carman, R.M. &  MacConnel,  J.G. (1969).  
Nutrients  derived  from  the  fungus  cultured by the attini ant 
Atta colombica tonsipes. Annals of the Entomological Society of 
America, 62: 1386-1387.

Morgan, E.D. (2008). Chemical sorcery for sociality: Exocrine 
secretions of ants (Hymenoptera: Formicidae). Myrmecol 
News, 11: 79-90.

Peregrine, D.J., Mudd, A. & Cherret, J.M. (1973). Anatomy 
and preliminary chemical analysis of postpharyngeal glands 
of leaf-cutting ant, Acromyrmex octospinosus (Reich.) (Hym., 
Formicidae). Insectes Sociaux, 20(4): 355-363

Peregrine, D.J. & Mudd, A. (1974). The effects of diet on 
the composition of the postpharyngeal glands of Acromyrmex 
octospinosus (Reich). Insectes Sociaux, 21: 417–424.

Peregrine, D.J., Percy, H.C. & Cherrett, J.M. (1972). Intake 
and possible transfer of lipid by the postpharyngeal glands of 
Atta cephalotes L. Entomologia Experimentalis Et Applicata, 
15: 248–258.

Phillips, S.A. (1979). Physiology of the postpharyngeal 
glands and comparative morphology of glands associatedwith 
the mouthparts among castes of the red imported fire ant, 
Solenopsis invicta Buren. 67 f. Dissertação (Mestrado) - 
Texas A & M University

Phillips, -Jr.S.A. & Vinson, S.B. (1980). Source of the 
postpharyngeal gland contents in the red imported fire ant, 
Solenopsis invicta. Annals of the Entomological Society of 
America, 73: 257-261.

Quinlan,  R.J. &  Cherrett,  J.M. (1979).  The  role  of  fungus  
in  the  diet  of  the  leaf-cutting  ant  Atta  cephalotes (L.).  
Ecological Entomology, 4: 151-160.

Schaffera, J.E., Lodish, H.F. (1994). Expression cloning and 
characterization of a novel adipocyte long chain fatty acid 
transport protein. Cell, 79: 427–436. PMID: 7954810.

Schoeters, E. & Billen, J. (1997). The postpharyngeal gland 
in Dinoponera ants (Hymenoptera: Formicidae): unusual 
morphology and changes during the secretory process. 
International Journal of Insect Morphology and Embryology, 
25: 443-447. doi: 10.1016/S0020-7322(96)00016-5

Soroker, V., Fresneau, D. & Hefetz, A. (1998). Formation of 
colony odor in ponerine ant Pachychondyla apicalis. Journal 
of Chemical Ecology, 24: 1077–1090.

Soroker, V. & Hefetz, A. (2000). Hydrocarbon site of 
synthesis and circulation in the desert ant Cataglyphis niger. 
Journal of Insect Physiology, 46: 1097–1102. doi: 10.1016/
S0022-1910(99)00219-X

Sumida, S.S. (2007). Trabalho de Conclusão de Curso 
(Graduação em Ciências Biológicas), Análise Morfológica 
dos túbulos de Malpighi, do ventrículo e das glândulas pós-
faríngeas das operárias adultas de Atta sexdens rubropilosa, 
Forel,1908, tratadas com compostos químicos. 53f. Instituto 
de Biociências, UNESP, Rio Claro, São Paulo.

Vieira, A.S. & Bueno, O.C. (2015). Mitochondrial and 
peroxisomal population in postpharyngeal glandsof leaf-
cutting ants after lipid supplementation. Micron, 68: 8–16. 
doi:10.1016/j.micron.2014.08.004

Vinson, S.B., Phillips, S.A. & Willians, H.J. (1980). The 
function of the postpharyngeal glands of the red imported fire 
ant, Solenopsis invicta, Buren. Journal of Insect Physiology, 20: 
645-650.

Wheeler, D.E. (1994). Nourishment in ants: patterns in 
individuals and societies. In: Hunt, J. H.; Nalepa, C. A. 
(Ed.). Nourishment & evolution in insect societies. Boulder, 
Colorado: Westview Press. p. 245-278.