JHR 57: 103-114 (201 7) yaa JOURNAL OF A peer-reviewed open-access journal
doi: 10.3897/jhr.57.1249| ) Hymenopter a

http://jhr.pensoft.net Theleternaionl Society of Hymenopexriss, RESEARCH

Anthropogenic waste products as preferred nest sites
for Myrmica rubra (L.) (Hymenoptera, Formicidae)

Michat Michlewicz', Piotr Tryjanowski'

| Department of Zoology, Institute of Zoology, Poznan University of Life Sciences, Wojska Polskiego 71C, 60-
625 Poznan, Poland

Corresponding author: Michat Michlewicz (michlewiczmichal@gmail.com)

Academic editor: Petr Klimes | Received 2 March 2017 | Accepted 7 June 2017 | Published 30 June 2017
Attp://zoobank. org/(6A065F2F-A2D0-4B90-9A53-0B4CD5242050

Citation: Michlewicz M, Tryjanowski P (2017) Anthropogenic waste products as preferred nest sites for Myrmica rubra (L.)
(Hymenoptera, Formicidae). Journal of Hymenoptera Research 57: 103-114. https://doi.org/10.3897/jhr.57.12491

Abstract

Sites containing anthropogenic waste products or dumps are currently treated as refugia by a lot of animal
groups, including ants. In this study the population structure of Myrmica rubra (L.) ants was compared
between habitats containing and lacking anthropogenic waste products. The density of colonies and in-
dividual nests, number of queens and of workers both per colony and per nest, and queen size were ana-
lyzed. Twenty plots with waste products and 20 control (natural) plots (paired, each 10x10m in size) were
established and compared. Results show a significant increase in colony and nest density on the plots with
waste compare to the control plots. However, the number of workers, queens and queen size did not differ
significantly between plot types. Overall number, as well as proportion of polycalic colonies was higher
on plots with waste products. These results suggest that when M. rubra has more potential nest site op-
portunities created by human activity, the density of its colonies increases. Moreover, the anthropogenic
waste product are strongly preferred nest sites for this species on the human-disturbed plots, as only them

were used as nest loci there in contrast to control plots.

Keywords

ants, colony structure, human pressure, modified habitat, polydomy, rubbish, nesting habit

Copyright Michail Michlewicz, Piotr Tryjanowski. 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.

104. M. Michlewicz & P Tryjanowski / Journal of Hymenoptera Research 57: 103-114 (2017)

Introduction

Human-origin waste dumps are considered to be potential sources of pollution of wa-
ter, soil and air, and cause the spread of parasites and of invasive animal and plant spe-
cies (Ruzickova et al. 1996). However, for some groups of animals, these waste dumps
act as refugia (Oro et al. 2013, Baranova et al. 2015). Among these animals, important
inhabitants of such sites include ants (Wiezik 2006).

Ants are ecologically very important insects, which have considerable and varied
impacts on ecosystems (Wilson and Hélldobler 2005). They are very widespread, abun-
dant and have a great influence on soil formation (Hélldobler and Wilson 1990, Folgar-
ait 1998, Frouz and Jilkova 2008). Ants also have great adaptive capacity when it comes
to getting food resources. They are rather opportunistic and general predators and can
modify their diet according to available resources (Wilson and Holldobler 2005) and
are also important herbivores (Rico-Gray and Oliveira 2007). Some species become
domestic pests (Klotz et al. 2008), while others play an important role in conservation
biology of other, threatened species of insects, such as butterflies (Buszko 2004).

Although the structure of ant colonies and their response to potential harmful human ac-
tivities has received a lot of attention (e.g. Majer 1983, Krzysztofiak 1991, Petal 1994, Holec
and Frouz 2005), there is no study which would test for the effects of anthropogenic waste
products as potential suitable nest sites on native ant populations to our best knowledge.

Apart from the size of colonies, the ants can react to the environmental factors
such as temperature (Bishop et al. 2016) or latitude (connected with temperature)
(Heinze et al. 2003) also by changing their morphology, including their body size.
Taking this into account, it is good to investigate whether different density and colony
structure may affect ant size.

The aim of the current study was to (a) compare the density of competing colonies,
as well as individual nest density of Myrmica rubra (L.), a locally common ant species
in Central Europe, between places containing and lacking anthropogenic waste prod-
ucts, (b) test if population structure (size of colonies, number of workers and of queens
per colony and per nest) is different between these two habitats and (c) compare the
size of queens from the two habitats in order to detect any tendencies in gyne size re-
lated to potential different densities.

This was based on hypotheses that 1) the density of colonies on plots containing
anthropogenic waste products is higher, as those product can be used as nest sites and 2)
the structure of colonies in both habitats is different (e.g. number of queens or workers,
and the body size of queens, per colony and per nest is lower on control plots).

Materials and methods

Study species

Myrmica rubra is the most ecologically tolerant of all European Myrmica Latr.
(Czechowski et al. 2012). It is found in a variety of habitats, as long as they are at

Anthropogenic waste products as preferred nest sites for Myrmica rubra... 105

least partially humid. The species is also commonly found in anthropogenic habitats
(Czechowski et al. 2012, Radchenko et al. 2004, Radchenko and Elmes 2010), where
it sometimes uses anthropogenic waste products as nest sites (M. Michlewicz, personal
observation). Myrmica rubra forms colonies which are generally polygynous, some-
times polycalic and consist of up to 10,0000 workers (Czechowski et al. 2012). Klotz
et al. (2008) even reported colonies consisting of 20,000 workers and 600 queens.
The number of nests in polycalic colonies of MZ. rubra can be large and are then called
“super-colonies” (Radchenko and Elmes 2010). Because of this, aggression tests, fol-
lowing Roulston et al. (2003), were carried out to check how many distinct colonies
were present, including possible multi-nest colonies.

Study sites

This study was undertaken in NW Poland in 2014 and 2015. Locations where study
plots were established were divided into two categories: 1) “control” (20 plots) and
2) containing anthropogenic waste products (20 plots). Each plot was, according to
the methods reviewed in Petal and Pisarski (1966), 10x10m in size. Each locality has
one pair of the plots — one control and one plot with waste products, at least 50 me-
tres apart (with a maximum of 57 metres). “Experimental” plots were those consid-
ered suitable for VM. rubra and which contained anthropogenic waste products on the
ground (rubbish, empty bottles, cans, tires, clothing, rubble etc.) covering about 1/5
of the plot area (i.e. 20 m’). Natural plots were generally similarincluding vegetation
and soil structure, but lacked any anthropogenic waste products. All plots were humid
grassland with whole area sparsely, but evenly covered with not very high bushes (up
to ca. 3 metres) of several plant species: Salix sp., Pinus sylvestris L., Sambucus nigra L..,
Prunus serotina (Ehrh.). Herbaceous vegetation consist mostly of grasses [mainly Poa
cf. trivialis L. and Elymus repens (L.)], with some herbs present, like Perasites hybridus
(L.), Urtica dioica L., Chelidonium majus L. and others. Each plot with waste products
was previously known to the first author, with a record of that rubbish has been laying
there for at least three years before this study took place. Localizations, coordinates, al-
titude, date of examination as well as general habitat description of each of 20 localities
is available in the Suppl. material 1.

Sampling techniques

Search was made for all nests of MZ. rubra at each site by the same methods, and in
a similar time for each pair of the plots, to avoid seasonal differences. ‘This species is
relatively easy to identify in the field by an experienced person using a hand lens. In
the field a hand lens with 10x magnification was used. Identification was subsequently
confirmed in the laboratory using a stereomicroscope. Each nest was marked with small
flag on which was written a unique number. Aggression tests were then carried out and
actual colonies were re-marked with numbers if necessary. Aggression tests were carried

106. M. Michlewicz & P Tryjanowski / Journal of Hymenoptera Research 57: 103-114 (2017)

out in the field, using plastic Petri dishes (90 mm in diameter), cleaned with alcohol
after each test. The arenas containing different colonies were marked with different
colors. The assays include 1-1 and 5-5 battles of live worker specimens. Ants presenting
ageressive behavior (biting and/or stinging) were marked as members of different colo-
nies. Each time control test, with members of the same colony, was also carried out, but
no aggressive behavior were observed in these. Whole number of workers from assays
were taken in account when number of workers per colony was estimated. Every colo-
ny/nest was then excavated using a shovel and put on a white sheet (ca. 150x150 cm),
then every ant from the nest was collected using an aspirator and put in a vial (or vials)
containing 75% ethanol. In the laboratory the ants were counted and queens measured.

Measurements

Queen measurements were taken using Zeiss AxioCam MRc 60 N-C 2/3” 0.63x camera
fitted with Zeiss SteREO Lumar.V12 stereomicroscope and AxioVision rel. 4.8 software.
Measurements were taken on the base of photographs using the given software. Mesosoma
length (ML) was measured as a surrogate of body size, as it is strongly correlated with
queen size (Steiner et al. 2006). General aim of taking measurements was to detect any
tendencies in queen size, potentially related to the different nest densities. Sixty queens
from control and 60 from plots with waste products were measured, selected randomly
from the whole number of queens collected from all nests.

Statistical analysis

The results were analyzed using PASW° Statistics 18 and RStudio version 3.2.3 software
(R Core Team 2015). First, Shapiro-Wilk normality test was used to check normality of
distributions of the variables, and because some of them have non-normal distribution
a non-parametric Wilcoxon signed-rank test (comparing the effects among the paired
plots) and Mann-Whitney U-test (comparing the queen size) were used. Chi-square
test was used to compare proportion of polycalic colonies among the two plot kinds.

Results

Colony and nests densities

Total number of 166 colonies (47 on control and 119 on experimental plots) consist-
ing of a total number of 196 nests (53 on control and 143 on experimental plots)
was found. Statistical analysis using a Wilcoxon signed-rank test found a significant
differences between both the number of colonies (Fig. 1A; W = 16, P < 0.00001) and
nests (Fig. 1B; W = 13.5, P < 0.00001) between control and plots with waste products.

Anthropogenic waste products as preferred nest sites for Myrmica rubra... 107

Number of colonies
Number of nests

6

|

A =e B

control with waste products control with waste products

20
L

15

10

10

Number of queens per colony
Number of queens per nest

ea ae SOL all = _ Dp

control with waste products control with waste products

2500
2500

2000

2000

1500
1500

1000

1000

Number of workers per colony

500

Number of workers per nest

'

'
H
' ! '
Hl ' i t
1 Hi i 1
H ! 1 i
i : i i
:
' \ ' '
' t '
ae
a 4 2. +}

control with waste products control with waste products

Figure |. Variation of measured nest parameters between control plots and plots with waste products
in Myrmica rubra. A colony density (P < 0.0001) B nest density (P < 0.0001) C number of queens per
colony (P = 0.06) D number of queens per nest (P = 0.26) E number of workers per colony (P=0.32)
F number of workers per nest (P = 0.06). Numbers are given as median per plot (per 100 m?), whiskers

of the boxplot represent the range of minimum and maximum values.

108 MM. Michlewicz & P Tryjanowski / Journal of Hymenoptera Research 57: 103-114 (2017)

Overall, 26 polycalic colonies was found (5 on control and 21 on experimental plots),
and chi-square test found significant difference in proportion of polycalic colonies
among the two plot kinds (x7 = 4.6493, P = 0.03). Minimum number of nests in those
colonies was two, while the maximum was four (one time, on plot with waste prod-
ucts). The mean number of colonies per plot (100 m’) on control areas was 2.35+0.23
(and the mean number of nests 2.65+0.29) and on plots with waste products 5.95+0.4
for colonies and 7.25+0.44 for nests.

Colony structure and size

Number of queens

In total, 1479 queens were sampled (359 from control and 1120 from plots with waste
products). No “microgyne” forms were found in any nest (i.e. recognized by eye). The
difference between number of queens on control and “experimental” plots both per
colony (Fig. 1C) and per nest (Fig. 1D) was statistically insignificant (W = 2269.5, P
= 0.06 and W = 3438.5, P = 0.26, respectively), although there was a tendency of a
higher queen numbers recorded in the plots with waste products. Mean queen number
per colony was 7.6+0.6 (control) and 9.4+0.47 (plot with waste products), and per
nest was 6.8+0.53 (control) and 7.7+40.39 (plot with waste products).

Number of workers

The difference between number of workers both per colony (Fig. 1E) and nest (Fig. 1F)
on both plot types was statistically insignificant (W = 3076, P = 0.32 and W = 2269.5,
P = 0.06), although the numbers were higher on average in the control plots this
time. Mean number of workers per colony on control plots with waste products was
1024.3485.27 and 937.54+51.35, respectively. Values for nest were 908.3+76.67 (con-
trol) and 769.14+44.82 (plots with waste products).

Queen measurements

The difference in size (based on mesosoma lenght) between queens from control (n =
60) and experimental (n = 60) plots was not statistically significant (Mann-Whitney
U-test, Z = — 0.19, P = 0.8493) (Fig. 2). Mean size of ML of measured queens was
2.02+0.01 mm on control and 2.05+0.01 mm on plots with waste products.

Nest sites

Interestingly, on plots with waste products only these microhabitats were used as nest
sites by ants. These include: empty bottles (both plastic and glass) and cans, jars, tires,
clothing, bricks with holes, old carpets, plastic carrier bags, other pieces of metal or
plastic, often partially covered with wet soil. On control plots M. rubra nests were
always found in clumps of grass and/or under rocks or pieces of wood, but those mi-
crohabitats were not occupied by the species in plots with the waste.

Anthropogenic waste products as preferred nest sites for Myrmica rubra... 109

oie

2.1

2.0

1.9

Queen size (ML)

1.8

17

control with waste products

Figure 2. Variation in median queen size (mesosoma length in mm) between control plots and plots
with waste products in Myrmica rubra. Difference is statistically insignificant. Whiskers of the boxplot

represents the range of minimum and maximum values.

Discussion

Previous studies show that in suitable humid grassland ecosystems the density of
rubra nests is limited more by the number of appropriate nest sites than by the avail-
ability of food resources. When one nest site is, for some reason, abandoned by one
colony, it is quickly recolonized by another of (in most cases) the same Myrmica species
(Radchenko and Elmes 2010).

Concerning densities of M. rubra, only grassland habitats with no substantial vol-
ume of waste products have been studied before (e.g. Parapura and Pisarski 1971, Petal
1980, Seppaé and Walin 1996, Radchenko and Elmes 2010 and references therein,
Huszar et al. 2014). Our effort is, to our knowledge, hence the first comparing nest
and colonies densities, as well as workers and queens numbers (and size of the lat-
ter), on plots with and without anthropogenic waste product in order to investigate,
whether those pieces of rubbish may be used by ants as nest sites and affect their
populations. We showed, that anthropogenic waste products (listed in Results) can act
as preferred nest loci. On plots with high level of anthropogenic waste products, only
those are used as nest sites. However, increase of food resources (especially a higher
quantity of small invertebrates there) may also probably affect the establishment and
survival of the ant colonies in habitats with anthropogenic waste products (M. Michle-
wicz, personal observation), although we did not measure these parameters in our

110 MM. Michlewicz & P Tryjanowski / Journal of Hymenoptera Research 57: 103-114 (2017)

plots. Among studied variables, only number of colonies and number of nests on both
plot types showed significant differences. Previous studies, also conducted in Poland
(Czechowski et al. 2012 and references therein) showed, that densities of M. rubra
nests vary greatly depending on habitat type. Therefore, it is crucial to properly choose
both “experimental” and control plot within the same habitat and time to control, also
for microenvironmental and seasonal characteristics, as done in this study.

To our knowledge, highest density of MZ. rubra in Poland was reported in the
Carpathian alder forest in Pieniny National Park and equals 100 nests per 100 m?
(Czechowska 1976). Some other studies also report rather high densities, e.g. 26.0
(Parapura and Pisarski 1971), 20.5 + 19.3 (Babik et al. 2009) and 20.0 (Czechows-
ki 1985). Although, some studies did not show such high densities, e.g. 1.040.31
(mean+SD) (Rzeszowski et al. 2013), 6.0 (Czechowski et al. 1990), 0.05, 3.0 and 14.0
(Petal 1980) (all given in number of nests per 100 m7’). Despite the fact that our results
from plots with waste products (mean 7.25+0.44 nests/100 m”) are not as high as some
literature data, this density significantly varies from results from control plots (mean
2.65+0.29 nests/100 m7’). Notably, the “control-experimental” plot pairs were chosen
in the very similar habitats (see Suppl. material 1), but only waste products were used
as nest sites in the latter plots. This is a strong evidence that the increased nest and
colony densities observed here were caused by the human-deposited waste, and that /.
rubra ants prefer these waste products as nest sites, whenever available.

As some studies document, number of queens both per colony and per nest, as well
as number of workers can also widely differ in Myrmica ants. Seppa and Walin (1996)
report colonies consisting of mean number of 7.56 queens and 961-828 workers.
Elmes (1980) reports mean number of 15.89 queens per colony and Elmes and Petal
(1990) write about overall number of workers per colony between 1,000 and 2,000.
Our results on both worker and queen numbers fit those ranges. However, differences
in those numbers between both plot types were insignificant. This might indicate, that
living in higher densities makes M/. rubra ants more tolerant to other colonies of the
same species, but those colonies does not have to be necessary smaller (both in respect
the number of workers and queens). This is in agreement with our observation of also
more polycalic colonies to be established on the plots with waste products, as those
colonies act behaviorally and ecologically as a single nest.

Differences in queen size between the two plot types were not statistically sig-
nificant. Similar results were found by Huszar et al. (2014). This shows that living
at higher density probably does not necessarily lead to changes in gyne morphology.
Moreover, no “microgyne” form queens were found during the study process. How-
ever, although the queen size did not differ, there was slight tendency (insignificant) to
a higher number of queens but lower number of workers per nest in the plots contain-
ing waste, which is in agreement with strategy of the ants to invest more to sexuals and
to establishment of the new nest satellites, where enough “empty” nest sites is available
(Oster and Wilson 1978, Poitrineau et al. 2009).

Some research showed, that where M. rubra forms polycalic nest systems, the num-
ber of other species of ants is significantly lower (Sepp4 and Pamilo 1995, Seppa and

Anthropogenic waste products as preferred nest sites for Myrmica rubra... 111

Walin 1996, Huszar et al. 2014). Future studies are needed to test if similar results
will be found on habitats where M. rubra live in higher density because of presence of
anthropogenic waste products and consider also the effects of its population increase
on the other ant species. Such further insight is needed given the ongoing damage of
the natural environments by humans, which can influence, however, positively some
insect populations, as demonstrated here for the case of M. rubra and waste products.

Acknowledgements

PT was supported by the NCN grant N N304 294240. Queen measurements were
made at the Division of Apidology, Institute of Zoology, Poznari University of Life
Sciences with the kind help of Dr Aleksandra Langowska. Our sincere thanks go to
Professor Tim Sparks from Coventry University, England, for language check and
other comments. We also thank to the reviewers Dr Pavel Pech (Department of Biol-
ogy, University of Hradec Kralové, Czech Republic), Professor Wojciech Czechowski
(Museum and Institute of Zoology, Polish Academy of Sciences, Poland), and to editor
Dr Petr Klimes (Institute of Entomology, Biology Centre of the Czech Academy of
Sciences, Czech Republic) for valuable and critical comments on the previous version
of the manuscript.

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114. M. Michlewicz & P Tryjanowski / Journal of Hymenoptera Research 57: 103-114 (2017)

Supplementary material |

Study sites

Authors: Michat Michlewicz, Piotr Tryjanowski

Data type: species data

Explanation note: General description of study localities, including the dates of inves-
tigation.

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/jhr.57.1249 1.suppl1