ote

JHR 37: 113-126 (2014) JOURNAL OF *0eerriewed opevaccersjoural
doi: 10.3897/JHR.37.6824 (ME Hymenopter a

www.pensoft.net/journals/jhr The iternaonl Sociey of Hymenopexriss, RESEARCH

Organ-specific patterns of endopolyploidy
in the giant ant Dinoponera australis

Daniel R. Scholes', Andrew V. Suarez', Adrian A. Smith',
J. Spencer Johnston’, Ken N. Paige'

I School of Integrative Biology, University of Illinois at Urbana-Champaign, 505 S. Goodwin Ave., Urbana,
IL, USA 61801 2. Department of Entomology, Texas A@M University, College Station, TX, USA 77843

Corresponding author: Daniel R. Scholes (scholes2@illinois.edu)

Academic editor: /. Neff | Received 16 December 2013 | Accepted 4 March 2014 | Published 28 March 2014

Citation: Scholes DR, Suarez AV, Smith AA, Johnston JS, Paige KN (2014) Organ-specific patterns of endopolyploidy in
the giant ant Dinoponera australis. Journal of Hymenoptera Research 37: 113-126. doi: 10.3897/JHR.37.6824

Abstract

Endoreduplication is an alternative cell cycle that omits cell division such that cellular ploidy increases,
generating “endopolyploidy”. Endoreduplication is common among eukaryotes and is thought to be
important in generalized cell differentiation. Previous research on ants suggests that they endoreduplicate
in body segment-dependent manners. In this study, we measured endopolyploidy of specific organs within
ant body segments to determine which organs are driving these segment-specific patterns and whether
endopolyploidy is related to organ function. We dissected fourteen organs from each of five individu-
als of Dinoponera australis and measured endopolyploidy of each organ via flow cytometry. Abdominal
organs had higher levels of endopolyploidy than organs from the head and thorax, driven by particularly
high ploidy levels for organs with digestive or exocrine function. In contrast, organs of the reproductive,
muscular, and neural systems had relatively low endopolyploidy. These results provide insight into the
segment-specific patterns of endopolyploidy previously reported and into the specific organs that employ
endoreduplication in their functional development. Future work aimed at quantifying the metabolic and
gene expression effects of endoreduplication will clarify how this often overlooked genomic event con-
tributes to the development and function of specialized organs across the breadth of taxa that are known
to endoreduplicate.

Keywords

Endoreduplication, ploidy, Hymenoptera, digestion, exocrine, development

Copyright Daniel R. Scholes et al. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC
BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

114 Daniel R. Scholes et al. / Journal of Hymenoptera Research 37: 113-126 (2014)

Introduction

Endoreduplication is the replication of the nuclear genome without cell division such
that cellular ploidy increases with each round of replication, generating endopolyploidy.
This process can proceed independently among cells and create a mosaic of ploidy levels
within an organism (Nagl 1976, 1978, Barlow 1978, Lee et al. 2009). Endopolyploidy
has been found in a variety of animals, including many insect orders (Nagl 1976, White
1977, Johnston et al. 2004, Aron et al. 2005). In insects, the occurrence of endopoly-
ploidy is tissue-dependent and is perhaps best characterized in Drosophila melanogaster,
where ploidy levels as high as 1024C are found among the polytene chromosomes
of the salivary glands and follicle cells, with lower levels of endopolyploidy occurring
throughout the organism (Balbiani 1881, Mulligan and Rasch 1985, Lilly and Duro-
nio 2005, Johnston et al. 2013). The highest level of endopolyploidy observed so far
is in the insect Bombyx mori, whose silk-producing glands are reported to exceed one
million-ploid as a result of intensive artificial selection (Perdix-Gillot 1979).

Given the wide range of taxa and cell types that endoreduplicate, endopolyploidy
is presumed to have beneficial effects on the basic properties of the cell (Nagl 1976,
1978, Lee et al. 2009). These “nucleotypic effects” (Bennett 1972, 1982) are in part
due to the bulk nuclear DNA content that influences cell size, the rate of cell division,
and water and nutrient transport efficiency (Nagl 1976, 1982, Barlow 1978, Lee et
al. 2009). Other hypothesized benefits of high DNA content, and in particular en-
dopolyploidy, include increased cellular metabolism and gene expression owing to the
increase in available gene templates for transcription (Nagl 1976, 1978, Galitski et al.
1999, Osborn et al. 2003). Collectively, the effects of endopolyploidy can influence
the development and functioning of highly specialized tissues (Lee et al. 2009) and
may occur in response to physiological stress (e.g. Britton and Edgar 1998, Engelen-
Eigles et al. 2001, Fusconi et al. 2006, Jimenez et al. 2010, Scholes and Paige 2011).

The order Hymenoptera has a long history for studies on intra-individual variation
in ploidy (Merriam and Ris 1954, Mittwoch et al. 1966, Rasch et al. 1975). Recently,
Aron et al. (2005) demonstrated that haploid males in many hymenoptera generate
endopolyploidy such that they are functionally diploid, with the proportion of dip-
loid cells in thoracic, mandibular, and fore-, mid-, and hindleg muscles comparable
between males and females of the bumble bee Bombus terrestris. Scholes et al. (2013)
surveyed endopolyploidy within and between castes of four polymorphic ant species
and found that endopolyploidy varied between workers of different body sizes. Addi-
tionally, when body segments were examined separately, ploidy levels of the abdomen
were significantly greater than those of the head and thorax, which had comparable
ploidy levels. Given the presumed roles of endopolyploidy in cell differentiation, we
propose that ploidy levels may be greatest in the abdomen to aid in the development,
functioning, and metabolism of the specialized tissues therein.

What is now needed is a fine-scale survey of endopolyploidy to document the de-
gree to which ploidy varies within the body segments, and to determine how ploidy

Endopolyploidy of ant organs 115

may be differentially affecting organ development, specialization, and function. In
this study, we surveyed endopolyploidy of a variety of organs within individuals of
the ant Dinoponera australis (Hymenoptera: Formicidae: Ponerinae). D. australis is
a large (mean 105 mg dry mass and > 2 cm in length), queenless ant that occurs in
northern Argentina, Paraguay, and southern Brazil (Paiva and Brandao 1995). Colo-
nies are relatively small with a range of 18 to 86 females (Paiva and Brandao 1995).
As with other members of the genus, all females are born physiologically capable of
reproducing; however, a single dominant “gamergate” is responsible for egg-laying
(Monnin and Peeters 1999, Monnin et al. 2003). D. australis has a relatively large
genome among ants (554.7 Mb / 1C; Tsutsui et al. 2008) that is composed of nu-
merous small chromosomes (57 chromosomes / 1C; Santos et al. 2012). Given its
large genome size, endopolyploidy will conceivably have a major effect in this spe-
cies. We chose D. australis for this research to determine whether the patterns of seg-
ment-specific endopolyploidy previously reported in numerous ant species (Scholes
et al. 2013) are also evident in this unusual ant. Its large size additionally allowed for
the extraction of organs from individual ants that were of adequate mass to estimate
organ-specific ploidy.

Initial characterization of the patterns of endopolyploidy among D. australis body
segments made it possible to determine which specific organs were underlying the seg-
ment-specific patterns observed. Given the assumption that endopolyploidy is related
to cellular differentiation and function (Nagl 1978, Cavalier-Smith 1985, Gregory
and Hebert 1999), we additionally tested whether levels of endopolyploidy correlate
with organ function to infer whether organs of similar general function also have com-
parable levels of endopolyploidy regardless of the segment within which they reside.
This information provides important insights into organ development, specialization,
and function, with potential further implications into the basis for behavior and social-
ity given a better understanding of insect physiology.

Methods

Organism collection and dissection

We excavated a single colony in August 2011 from Iguazt National Park, Misiones
Province, in northeastern Argentina. The colony was maintained in an insectary at the
University of Illinois on a diet of sugar water and crickets. Individuals were a mini-
mum of two years old at the time of analysis. We used carbon dioxide from sublimat-
ing dry ice to incapacitate five non-reproducing females prior to dissection. For each
individual, we dissected as many organs as possible from each of the head, thorax, and
abdominal segments. Dissected organs were placed in a 0.2 ml centrifuge tube on ice
until preparation for cytometric analysis. A complete list of organs sampled is provided

in Table 1.

116 Daniel R. Scholes et al. / Journal of Hymenoptera Research 37: 113-126 (2014)

Table |. Organs analyzed for nuclear DNA content by flow cytometry. Identity of the 14 organs ana-
lyzed, their abbreviations (Abbrev), the segment within which they reside, their demonstrated functions,

and the number of nuclei analyzed for each organ (mean + SE). Symbols designate reference (Ref) or

general functional system (Function).

Organ Abbrev Function # Nuclei

Brain BRN Sensory processing (+) 8861 + 1589
Mandibular muscle Mandibular movement (§$) 517 + 141
Foreleg muscle Locomotion (§$) 221 + 83
Thoracic muscle Locomotion (§$) 1165 + 435
Abdominal segmental

Articulation of abdomen (§$) 763 + 272
muscle

Dufour’s gland DUF Pheromone production (£+) 384 + 68

Fat body Nutrient metabolism, storage (||) | 704 + 202
Foregut (crop) Ingestion & storage (||) 1357 + 618
Hindgut Absorption & excretion (||) 1656 + 313
Midegut Digestion & absorption (||) 2582 + 916

Malpighian tubules Excretion, osmoregulation (||) 435 +254

Abdomen

MPG
Ovaries OVA Ege production (€4) 4305 + 2057

Poison gland POI Venom production (£4) 290 + 92

+ Gronenberg et al. 2008; $ Oldham et al. 1994; § Klowden 2007; | Monnin et al. 2002;
§ Gullan and Cranston 2005; # Johnson et al. 2010

+t Neural; $4 exocrine; §§ muscular; || digestive; ¢§ reproduction

Cytometric analysis

Flow cytometry methods were modified from those described by Johnston et al. (2004).
Each isolated organ was placed into one milliliter of Galbraith buffer (sodium citrate,
3-morpholinopropane-1-sulfonic acid, magnesium chloride, Triton X-100; Galbraith
et al. 1983) in a 2 ml Kontes Dounce. Nuclei were released by grinding with ten very
gentle strokes with an A pestle. The released nuclei in the buffer were filtered through a
40 um nylon mesh, brought to a 1 ml total volume with additional buffer, and stained
with 25 ul of propidium iodide (0.25 mg PI/ ml). After at least 30 minutes of staining
in the dark at 4°C, the number of stained nuclei at each ploidy level was scored on the
basis of relative fluorescence using a Partec (Miinster, Germany) Cyflow cytometer.
Care was taken to set the 2C fluorescence peak at channel 25 so that a total of 6 ploidy
levels could be scored. Gates set on scatter and peak/area were set up for doublet dis-
crimination and identification of broken nuclei or nuclei with cytoplasmic tags. The
total number of counted gated and ungated nuclei at each ploidy level in each organ
was based on the analysis of approximately half (0.5 ml) of each prepared sample. The
“cycle value” for each sample was then calculated by the equation:

Gycle-value = (nO en ts S82, Ae Oe i a Ne)

UAC Sean Nae (Peas ce IS tn

6C 64C

Endopolyploidy of ant organs Ta?

as the sum of the number of nuclei at each ploidy level multiplied by the number of
endocycles required to achieve that ploidy level, divided by the total number of nuclei
measured. The cycle value is interpreted as the average number of endocycles under-
gone per nucleus in the sample, and is thus directly proportional to endopolyploidy
(Barow and Meister 2003).

Statistical analysis

Statistical analyses were conducted as mixed models with SAS PROC MIXED
(v.9.2, Cary, North Carolina, USA). To assess whether organs differed from each
other across the measured ploidy levels, the proportion of nuclei at each ploidy level
was compared among organs by ANOVA with individual as a random effect with
five levels (individuals 1-5), ploidy level as a fixed effect with six levels (2C, 4C,
8C, 16C, 32C, 64C), and organ as a fixed effect with fourteen levels (14 organs;
see Table 1). Body segments were similarly compared but with body segment as a
fixed effect with three levels (head, thorax, abdomen). Additionally, to determine
whether differences among body segments were due to differences in the propor-
tion of endopolyploid cells, the proportions of endopolyploid (4C-—64C) nuclei
were compared among body segments via ANOVA with post-hoc linear contrasts.
All proportions were arc-sin square-root transformed prior to statistical analysis to
satisfy the assumption of NID(0,o”).

To determine if endoreduplication differed among organs, the composite measure
of endoreduplication, the cycle value, was compared among organs by ANOVA with
individual as a random effect with five levels (individuals 1-5) and organ as a fixed
effect with fourteen levels (14 organs; see Table 1). Comparing endopolyploidy via
cycle values rather than across six ploidy levels individually is useful here due to the
number of organs compared. Cycle values of body segments were compared similarly
with body segment as a fixed effect with three levels (head, thorax, abdomen). For both
the organ and body segment models, differences among organs/body segments were
determined by Tukey’s Studentized range test (i.e. Tukey’s Honest Significant Differ-
ence) to correct for multiple comparisons (Tukey 1953) with SAS PROC MIXED.
The effect of the individual on cycle values was tested via the Random-Effects Analysis
in PROC GLM.

To determine whether the level of endopolyploidy is correlated with organ func-
tion, cycle values were compared via ANOVA with individual as a random effect with
five levels (individuals 1-5) and functional system as a fixed effect with five levels
(digestive, exocrine, reproduction, muscular, neural; see Table 1 for a list of organs
comprising each system). Differences among functional systems in their cycle values
were determined by Tukey’s Studentized range test to correct for multiple compari-

sons (Tukey 1953) with SAS PROC MIXED.

118 Daniel R. Scholes et al. / Journal of Hymenoptera Research 37: 113-126 (2014)

Results

Proportion of nuclei of ploidy levels among organs and body segments

We quantified nuclei via flow cytometry at ploidy levels doubling from 2C to 64C
in 14 organs, though not all organs were composed of all six ploidy levels scored
(Figure 1). A comparison of gated and ungated counts showed that careful prepara-
tion produced less than 2% of counts of doublets and broken or cytoplasmic tagged
nuclei (data not shown). Total, ungated counts are therefore reported at each of the
ploidy levels. Overall, organs vary significantly in the proportions of nuclei among
the ploidy levels (F(70,320) = 7.13, p < 0.0001; Figure 1). When assessed across
all organs from each body segment, the head, thorax, and abdomen differ in their
proportions of nuclei among ploidy levels (F(10,392) = 10.33, p < 0.0001), due pri-
marily to the abdomen having more nuclei at endopolyploid levels (4C, 8C, 16C,
32C, and 64C) than the head and thorax (abdomen vs. head 4C—64C: +(62) = 4.4,
p < 9.0001; abdomen vs. thorax 4C-—64C: 74(62) = 5.2, p < 0.0001; Figure 2). The
head and thorax do not differ in their proportion of endopolyploid nuclei (¢(62) =
1.24, p = 0.2198; Figure 2).

100
[~] 2c
[+1 4c
im sc
HG 16C
MM 32Cc
MM G4c

80

60

Nuclei (%)

40

20

MDGMDM BRN FLG THM DUF MID MPG FOR HIN FAT OVA POI ABM

Head Thorax Abdomen
Organ

Figure |. Distribution of ploidy among organs. Percentage of nuclei at each of the ploidy levels observed
(2C-64C) within each organ analyzed. Organs are presented by body segment in descending order of

cycle value.

Endopolyploidy of ant organs 119

80
B

Ey,
=
— 60
2
rT)
5
c A
oO
Oo 40
= A
re)
a.
=
= 20
Wu

0

Head Thorax Abdomen

Figure 2. Differences in endopolyploidy among body segments. Percentage of endopolyploid (4C, 8C,
16C, 32C, and 64C) nuclei for each body segment. Shown are means + standard error across 5 individu-
als. Letters indicate significant (« = 0.05) differences among body segments. Significance was determined

by analysis of arc-sine square-root transformed proportions.

Endopolyploidy among organs and body segments

Organs differ overall in their cycle values (F(13,51) = 9.57, p < 0.0001), covering a
nearly 31-fold range in ploidy (brain: 0.08, Dufour’s gland: 2.47; Figure 3). Overall,
these organs comprise two main statistical groups: the Dufour’s gland, midgut, Mal-
pighian tubules, foregut, hindgut, and the mandibular gland have the highest cycle
values (group A) while the fat body, ovary, poison gland, foreleg muscle, abdominal
muscle, mandibular muscle, thoracic muscle, and brain have the lowest cycle values
(group D), although there is some overlap in the statistical groupings for organs of
intermediate cycle values (Figure 3). There is no significant relationship between the
numbers of nuclei counted and the cycle values among organs (F(1,67) = 2.03, p =
0.159; Table 1), so differences among organs in their cycle values are not likely due to
differences in cell number (i.e. organ size) or technical artifact. We additionally note
no significant individual effect on cycle values (F(4,64) = 0.78, p = 0.5453), indicating
that differences in cycle values are not dependent on the individual from which they
were measured. When organs are considered in relation to their body segments, the
abdomen has the highest cycle values (abdomen vs. head: t(62) = 2.88, p < 0.05; abdo-
men vs. thorax: (62) = 3.49, p < 0.01), with no difference between cycle values of the
head and thorax (#62) = 0.88, p = 0.6532).

120 Daniel R. Scholes et al. / Journal of Hymenoptera Research 37: 113-126 (2014)

Head
[J Thorax
[7] Abdomen

Cycle value

i
ut |

DUF MID MPG FOR HIN MDG FAT OVA POI FLG ABM MDM THM BRN

Organ
Figure 3. Cycle values for each organ analyzed within each body segment. Shown are means + standard
error across 5 replicates of each organ within each body segment. Organs are presented in descending
order of mean cycle value. Bars labeled with letters denote statistical groups determined by Tukey’s Stu-

=0.05),

dentized range test (significance tested at a,
amily

Endopolyploidy of organs by function

Upon relating organs to their functional groups (Table 1), endopolyploidy, measured
by cycle value, differs among major functional systems (F(4,60) = 11.83, p < 0.0001).
Specifically, systems comprise two main statistical groups—the digestive and exocrine
systems have the highest cycle values (group A), while the muscular and neural systems
have the lowest cycle values (group B; Figure 4). The reproductive system has an inter-
mediate cycle value and is shared among statistical groups (group AB). Further, while
the fat body is typically considered to be part of the digestive system, it is not directly
part of the ingestion/excretion pathway (i.e. the gut). Upon exclusion of the fat body
from the gut (i.e. the foregut, midgut, hindgut, and Malpighian tubules), the average
cycle value of the digestive system increases from a value of 1.51 with the fat body to
1.70. This exclusion changes the significance groups such that the digestive system has
the highest cycle value (group A), the muscular and neural systems have the lowest
(group C), and the exocrine and reproductive systems have intermediate cycle values

(groups AB and BC, respectively).

Endopolyploidy of ant organs pal

Cycle value

Digest. Exocrine Reprod. Muscular Neural

System
Figure 4. Endopolyploidy of organs by functional system. Cycle value of organs within each functional
system (abbreviations “Digest.”: digestive; “Reprod.”: reproductive). Shown are means + standard error
across 5 replicates of each organ within each system. Systems are presented in descending order of mean
cycle value. Bars labeled with letters denote statistical groups determined by Tukey’s Studentized range

test (significance tested at a = 0.05). Numbers above each bar indicate the number of organs that

family
comprise each respective system.

Discussion

Previous studies have documented instances of insect endopolyploidy in a qualitative
(White 1977 and references therein) or semi-quantitative (e.g. Johnston et al. 2004,
Aron et al. 2005, Scholes et al. 2013) manner. Here, we show that flow cytometry can
be utilized to provide a fully quantitative comparison of endopolyploidy within and
among organs. Using this technique, we are able to quantify for the first time the extent
to which endopolyploidy varies within an insect, with a wide range of ploidy levels de-
tected across the 14 organs examined in the ant Dinoponera australis. Specifically, organs
from the abdomen collectively had greater endopolyploidy than those of either the head
or the thorax. Ploidy levels were highest in organs of the digestive and exocrine systems,
and especially of the gut, suggesting that endoreduplication may be particularly impor-
tant in development and/or organ function in these systems. This information provides
the basis from which questions regarding the role of endopolyploidy in insect develop-
ment, behavior, physiology, body size, caste differentiation, etc. may be addressed.

122 Daniel R. Scholes et al. / Journal of Hymenoptera Research 37: 113-126 (2014)

Our results for this unusual ant support the body segment-specific differences pre-
viously reported for four other ant species (Scholes et al. 2013). Specifically, Scholes
et al. (2013) determined that regardless of species, caste, or worker body size, the
abdomen had consistently greater endopolyploidy than the head and thorax, which
had lower, comparable levels. However, our tissue-specific analyses revealed substantial
variation in endopolyploidy among organs within body segments. The importance
of endoreduplication in segment function and development may therefore be mis-
represented if not assessed with regard to specific organs or tissues. For example, the
abdomen has high endopolyploidy overall, yet is composed of a variety of organs with
relatively high or low endopolyploidy.

Patterns in segment-specific cycle values appear to be driven strongly by organ func-
tion. For example, the abdominal organs of the digestive system (and particularly the
gut) and the Dufour’s gland of the exocrine system have high endopolyploidy. The man-
dibular gland of the exocrine system also has high endopolyploidy, yet it resides within
the head, where the organs otherwise analyzed have very low endopolyploidy and serve
other functions. Given endoreduplication’s presumed roles in cellular development (Nag
1976, Lee et al. 2009), endopolyploidy may therefore be particularly beneficial for cells
of digestive and exocrine function by increasing metabolic potential and gene expres-
sion through increased genome copy number, and/or by increasing cell volume for the
production and storage of metabolites (Nagl 1976, 1978, Lee et al. 2009). While ploidy
has not yet been related to measures of digestive demands or the production or storage of
chemicals within these organs, the extremely high ploidy of the Bombyx mori silk gland
(Perdix-Gillot 1979), as well as of the Drosophila melanogaster nurse cells and salivary
gland (Balbiani 1881, Mulligan and Rasch 1985), suggests that endoreduplication can
be an effective mechanism to support high cell metabolism and specialized function.

The muscular tissues sampled (mandibular, foreleg, thoracic, abdominal) have
comparably low levels of endopolyploidy regardless of their body segment (head, tho-
rax, abdomen), likely due to their shared function. Aron et al. (2005) compared mus-
cles of the head and thorax of female bumble bees and found no difference in the
distribution of ploidy levels among thoracic, mandibular, fore-, mid-, and hindleg
muscles, further suggesting a relationship between endopolyploidy and function for
these tissues. Of additional interest is the moderate level of endopolyploidy observed
in the D. australis ovary—a tissue one might expect to have high metabolic demand.
Our results are likely due in part to the presence of both somatic endopolyploid cells
(e.g. nurse cells) and meiocytes (1C, 2C, and 4C) with moderate ploidy levels overall.

Endopolyploidy is thought to be particularly important for organisms to compen-
sate for the metabolic and genetic decrements of their small genome sizes (Nagl 1976,
1978, Galbraith et al. 1991, Barow and Meister 2003), yet patterns of endopolyploidy
in D. australis are comparable to other species examined, including Pogonomyrmex
badius whose genome is over 2x smaller than that of D. australis (P. badius: 262.8 Mb
/ 1C; D. australis: 554.7 Mb / 1C; Tsutsui et al. 2008). Karyotypic analysis of four
Dinoponera species revealed that the genomes in this genus are composed of a large
number of very small chromosomes (e.g. D. australis: 2n = 114 chromosomes; Santos

Endopolyploidy of ant organs 123

et al. 2012), such that the highest ploidy level observed here, 64C, represents 3648
nuclear chromosomes per cell. The discrepancy between the expected and observed
relative rates of endoreduplication given the genome size of D. australis may therefore
suggest that genome organization (i.e. chromosome number and size), in addition to
genome size, influences the rate of endoreduplication.

Endopolyploidy is hypothesized to impact cells through associated nucleotypic
effects, which are not based on the cell’s genotype, and/or genetic effects including
genome or gene pathway up-regulation (Bennett 1972, 1982, Nagl 1976, 1978). En-
doreduplication may thus promote cell differentiation and specialization in two inte-
grated ways: 1) nucleotypic effects, such as increased cell size, can provide the neces-
sary cell volume, improved transportation efficiency, and other beneficial effects that
support cell differentiation generally, while 2) differences among cells in the continu-
ation of endoreduplication beyond this level induce differential gene expression that
supports the cell’s functional fate through specific impacts on metabolism, chemical
production, and/or other processes. Certainly more research is necessary to determine
the impact of the organ-specific endoreduplication reported here. For example, the use
of whole transcriptome sequencing would allow the examination of gene expression
across organs or tissues of interest and help relate endopolyploidy to the functions of
specific gene pathways.

Acknowledgements

We thank Bill Wills for help with colony collection, Fred Larabee for help with colony
maintenance, and Amy Gervais for help with flow cytometry. For permission to collect
and export Dinoponera australis, we thank the Administracién de Parques Nacionales
de Argentina (specifically Parque Nacional Iguazti), Paula Cichero, Karina Schiaffino,
Silvia Fabri, and CIES. The ants were imported under USDA APHIS permit number
P526P-10-01369. This research was supported by grants from the National Science
Foundation (DEB 1020979 to AVS and DEB 1146085 to KNP).

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