DOI: 10.13102/sociobiology.v62i3.650Sociobiology 62(3): 396-400 (September, 2015)

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

Mating Behavior of the African Weaver Ant, Oecophylla longinoda (Latreille) (Hymenoptera: 
Formicidae)

Introduction

The African Weaver Ant (AWA), Oecophylla longinoda 
Latreille (Hymenoptera: Formicidae) is a predatory species 
which controls a wide range of insect pests in multiple 
crops (Way and Khoo, 1992; Van Mele, 2008). The specie 
is increasingly being used in biological control programs 
in tropical plantations (Van Mele, 2008). A stable and high 
population level is usually required for effective control 
of insect pests by O. longinoda (Sporleder & Rapp, 1998). 
Introduction of O. longinoda into crop fields requires mapping 
of colonies in natural habitat, subsequent harvesting and 
transplanting. However, the transplantation of colonies into new 
plantations is hampered by the difficulties in finding the single 
maternal queen in colonies comprising up to several hundreds 
of nests (Ouagoussounon et al., 2013; Rwegasira et al., 2015).

Abstract
Mating in most species of ants occur during nuptial flights. In the African weaver ant, 
Oecophylla longinoda Latreille, mating has previously been hypothesized to take place 
within the nest before the nuptial flight but no research data has ever been presented 
to support this. Understanding the mating strategy of O. longinoda is important for its 
successful application in biological control programs. Here we report on the findings 
from studies conducted in Tanzania to determine whether mating occur prior to 
dispersal flight. Winged O. longinoda queens collected at four steps; before taking flight, 
immediately after leaving the nest, up to 12h after leaving the nest and after settling 
naturally following the dispersal flights were examined. Mating in captivity with varied 
number of males and queens was also assessed. Results showed that no eggs hatched 
from any of the 527 winged queens that were collected prior to their dispersal flights 
and no mating attempts in captivity lead to viable offspring. Only eggs produced by 
queens collected after settling naturally (N=65) hatched into larvae. High percentages 
(88.73) of eggs that hatched were laid by queens that shed wings and laid their eggs 
within 3 days after nuptial flights. Findings from the current study suggest that mating 
of O. longinoda queens take place during a nuptial flight and does not take place within 
the nest, as previously suggested. Time from nuptial flights to shedding of wings and 
egg laying translates to hatchability of the eggs.

Sociobiology
An international journal on social insects

WA Nene1, GM Rwegasira1, J Offenberg2, M Mwatawala1, MG Nielsen2

Article History

Edited by
Gilberto M. M. Santos, UEFS, Brazil 
Received                  02 December 2014 
Initial acceptance   21 May 2015 
Final acceptance     11 August 2015 

Keywords 
African weaver ant, mating behavior, 
nuptial flight, Oecophylla longinoda.

Corresponding author
Wilson Angelo Nene
Sokoine University of Agriculture
Department of Crop Science and 
Production
Box 3005, Morogoro, Tanzania 
E-Mail: wilsoninene@gmail.com

Oecophylla spp. queens disperse from their natal colonies 
at the onset and/or during the rainy season (Vanderplank, 1960; 
Offenberg & Wiwatwitaya, 2010; Peng et al., 2013). The 
copulation of unrelated sexual forms during nuptial flights 
(Depa, 2006), provides an opportunity for genetic mixing and 
plays an important role in the life cycle of many ant species 
(Dhami & Booth, 2008). There are mainly two mating systems 
which have been reported in ants namely; male aggregation 
and female calling. Male aggregation (MA) is a system that 
winged males and females meet during nuptial flights. Females 
enter a swarm, which is dominated by males and subsequently 
mate with one or more of these males and return from the 
flight as fertile queens (Kaspariet al., 2001). Female calling 
(FC) is a system that winged females position themselves near 
their natal nests and emit pheromones to attract winged males 
with whom they mate, before they disperse or re-enter their 

RESEARCH ARTICLE - ANTS

1 - Sokoine University of Agriculture, Morogoro, Tanzania 
2 - Aarhus University, Aarhus, Denmark



Sociobiology 62(3): 396-400 (September, 2015) 397

natal colony as fertile queens (Kaspari et al., 2001). In rare 
cases, mating occur within the nest, for instance in Formica 
aquilonia (Yarrow) (Forterius, 2005) and Linepithema 
humile (Myr) (Aron, 2001). In independent founding species, 
including Oecophylla spp., fertilized queens search for nesting 
places and shed their wings after the mating (Hölldobler & 
Wilson, 1978; Dhami & Booth, 2008). Queens then rear their 
first brood by using food reserves stored in the fat body and 
their wing musculature (Keller & Passera, 1989).

Mating strategy of O. longinoda has never been 
established. Understanding the mating strategy of O. 
longinoda is an important prerequisite for their successful use 
in integrated pest management (IPM), particularly in collection 
of mated queens to stock ant nurseries (Ouagoussounon et 
al., 2013; Peng et al., 2013). Way (1954) collected alate and 
dealated queens of O. longinoda in the field, during the ants’ 
mating seasons in Tanzania which laid eggs that subsequently 
hatched into viable offspring. However, it was not known how 
and when mating occurred. Vanderplank (1960) hypothesized 
that mating by O. longinoda takes place within the nest, 
before dispersal of the queens. In a latter case, males liberated 
from their natal nests, disperse and enter into the nests of 
other colonies, where mating with alate queens takes place. 
Reported facts about sexuals of the closely related Asian 
green tree ant, Oecophylla smaragdina, unveiled that mating 
occurs during nuptial flights (Peng et al., 2013). Similar case 
would be true to O. lonignoda but evidence based on data was 
required to disprove Vanderplank’s hypothesis. 

The current study aimed at examining the mating 
strategies of O. longinoda by testing the fertility of queens 
at different dispersal stages (pre-dispersing, dispersing, post-
dispersing and natural settling).

Materials and Methods

The study area

Field Experiments were conducted from 2012 to 
2014 at Naliendele Agricultural Research Institute (NARI) in 
Mtwara region, southern Tanzania (40º09´ 57.05” E, 10º 21´ 
22.49” S). The region has a unimodal rainfall lasting from 
November/December to April/May and the mean annual 
rainfall ranges from 810 to 1090 mm. The mean maximum 
and minimum temperatures are 27 ºC and 23 ºC respectively.

Collection of queens at different stages of dispersal 

Winged queens were caught during different stages of 
their dispersal from their natal nests. Four different stages of 
nuptial flights were considered; i) pre-dispersal, ii) dispersal, 
iii) post-dispersal and iv) after naturally settling. In the first 
stage, alate queens were caught before dispersal, either from 
surface of the nests or from vegetation in the immediate 
neighborhood of nests. In the second stage, queens were 

collected immediately after they took off from their nests. 
The queens were trapped with mosquito nets that covered 
cashew trees in the field as well as plastic sheets that covered 
potted mango and cashew seedlings. In the third stage, queens 
that attempted to disperse from four colonies established on 
cashew seedlings were collected from the roof of the screen 
house, twelve hours after each dispersal flight. In the fourth 
stage, queens were collected by using artificial nests, after 
settling naturally as described by Peng et al. (2013). In this 
technique, a total of 1000 artificial nests were constructed on 
10 citrus trees. 

Testing for fertility of queens collected at different stages of 
dispersal

Each collected queen was kept in a match box 
(53x36x17mm) placed on tables in a screen house and 
protected from other ants as described by Way (1954). Queens 
were provided with distilled water soaked in a cotton wool 
every day.  A 20% sucrose solution was also provided after 
the first workers emerged. Rearing continued for 60 days 
after the queens were collected.  Number of queens that shed 
wings, numbers of queens that laid eggs, and queens whose 
eggs hatched and developed into larvae, pupa and imago were 
recorded. The mortality of queens after 60 days of development 
was calculated and compared between the tested groups. 

Testing for fertility of queens in captivity

Queens and males were collected from nest surfaces 
and nearby vegetation just before mating. A queen was paired 
with 0, 1, 2, 3, 4, or 5 males in a matchbox during the first 
mating season (December 2012 to April 2013). The same 
combinations of males were paired with two queens in a 
matchbox, except in the second season (December 2013 to 
April 2014). Each combination was made of two different 
kinship relations; i.e with queens and males originating from 
the same or different colonies and replicated three times. 
Queens and males were maintained for 60 days as in the queen 
fertility tests at varied stages of dispersal described above.  The 
number of queens that shed their wings, numbers of queens 
that laid eggs, and queens whose eggs hatched and developed 
into larvae, pupa, imago workers or workers were recorded.

Developmental times of initial stages of weaver ants

Queens were collected using artificial nests placed on 
citrus trees at Moma (040018´ 25.1” E, 100 39´ 71.7” S, 34 m 
asl) and Sogea (040014´ 71.4” E, 100 37´ 79.1” S, 142 m asl) 
sites in Mtwara from January to April 2015. Founding queens 
were reared in matchboxes placed on cages in the shade 
house. Number of queens that shed wings (n=103) as well as 
number of queens that laid eggs (n=103) within 3, 6 and above 
six days from nuptial flights were recorded. Also recording 



WA Nene, GM Rwegasira, J Offenberg, M Mwatawala, MG Nielsen – African Weaver Ant Mating Behavior398

was done on number of queens with hatched eggs from 10th 
to 14th and beyond 14th days after nuptial flights (n=69). The 
temperature during rearing period ranged between 28 and 29 
0C. Queens were provided with distilled water ad libitum.

Data analysis

Collected data were analysed using JMP 10.0 software 
(SAS, 1995). Chi Square was used to test dependency of wing 
shedding, egg laying, egg hatching and queens’ survival, on 
different stage of queen dispersal. The dependency of wing 
shedding, egg laying and egg hatching, on days from nuptial 
flights were also analysed by Chi Square test. 

Results

Fertility status and survival of collected queens

All collected queens produced eggs, regardless of 
stage of collection. Egg production was not dependent on 
stage of collection in both the first (X2=7.418, p=0.06) and 
second (X2=5.88, p=0.12) season. Only queens that settled 
naturally after dispersal flights produced viable eggs (Fig 1). 
The proportion of queens that produced eggs was higher than 
the proportion that shed their wings (Fig 1).  The proportion 
of queens that shed their wings varied between 60.6 and 100%. 
Shedding of wings was significantly dependent on stage of queen 
collection in both first (χ2=24.83; p<0.0001) and second season 
(χ2= 28.60; p<0.0001). The highest proportion of queens that 
shed wings were those collected after settling naturally. 

Results on survival of queens collected at the different 
stages of dispersal are presented in Fig 2. In all cases, survival 
was above 88 %, except for queens that settled naturally after 
dispersal (73.7% to 94.1). Survival of queens was significantly 
dependent on stage of collection in the first season (χ2=8.2, 
p=0.043) but not in the second season (χ2=0.80, p=0.85). 
Queens collected pre-dispersal to 12 hours after dispersal 

had higher survival rates while those collected after settling 
naturally had lowest survival rate. 

Mating in the captivity

None of the males that were introduced to alate queens 
in match boxes survived, regardless of the combination. Males 
died within approximately two days after they were placed in 
the boxes of alate queens. Dead males were removed from 
the rearing chamber (match boxes). Many of the test queens 
(N=83) kept in captivity shed off their wings and initiated egg 
laying but none of them (N=90) produced viable eggs. 

Developmental times of eggs and wing shedding

All the collected queens (experiment conducted from 
January to April 2015) laid eggs and shed their wings. 
However, only eggs from 71 queens were hatched out of 
103, making eggs hatching successful by 68. 93 %. Wing 
shedding was significantly dependent on time from nuptial 
flights (Table 1). More queens shed their wings within 3 days 
after nuptial flights. Similarly, egg laying was significantly 
dependent on time from nuptial flights (Table 1).  More 
queens (68.93%) laid eggs within 3 days after flights. A 
high percentage of eggs that hatched (88.73) were laid by 
queens that shed their wings and laid eggs within 3 days 
after nuptial flights (χ2=21, p=<0.0001, n=71).  Only 11.27% 
of eggs that hatched were laid by queens between 4th and 6 
days after nuptial flights.  Egg hatching was also dependent 
on days from nuptial flights (Table 2). A significantly high 
number of queens had their eggs hatched from day 11 to 13 
after nuptial flights. No hatching was recorded in eggs laid 6 
days after nuptial flights.

Fig 2. Survival rates of queens caught at different stages of dispersal 
from their natal nests in 60 days of rearing. 

Fig 1. Reproductive success of queens collected at different 
dispersal stages. 



Sociobiology 62(3): 396-400 (September, 2015) 399

Discussion

In this study only the queens that dispersed and 
subsequently settled naturally were able to produce viable 
offspring. These queens had an opportunity to fly to heights 
beyond 10 meters (the size of a shade house). This observation 
suggests that mating took place after their dispersal from the 
nest and that a certain flying height was needed before mating 
occurred. This correlates well with the Australian species, 
O. smaragdina that mate at some greater heights in the air 
and not inside their nests (M.G. Nielsen et al., unpublished 
data). Mating at great heights is not a unique character to 
Oecophylla species. Other ant species are known to fly high 
before mating. For instance, Solenopsis invicta has been 
reported to reach at height of 60-100 m during their mating 
flights (Dhamb & Booth, 2008). 

The current study has shed light on the myth that 
surrounded the collected alate Oecophylla queens that produced 
viable offspring (Way, 1954; Lokkers, 1990) without clear 
understanding of the dispersal stage at which the queens were 
collected. It also brings to an end the speculation (Vanderplank, 
1960) that mating by O. longinoda on Zanzibar took place 
inside their nests before dispersal. Since Vanderplank’s alate 
queens were reportedly collected from the nest surface and that 
the queens subsequently produced viable offsprings with imago 
workers. Queens were collected after nuptial flights, and were 
most probably founding queens. Centrally to that, the difference 
between Vanderplank’s and the present study might be hard to 
explain unless behavioral variation among populations exists. 
If the behavior observed by Vanderplank (1960) holds true, it 
would be a rare strategy only used by few species and not even 
by the sister species, O. smaragdina (Peeters & Molet, 2010). 

In the present study, many of the infertile queens shed 
their wings and laid eggs. Thus, wing shedding and egg-
laying cannot be used as indicators of fertility or viability 
among O. longinoda queens. It is surprising that queens shed 
their wings while still unmated as they would need them 
in subsequent attempts to locate potential mating partners. 
Furthers studies would be needed to unveil triggers for wing 
shedding in queens which occurred regardless of mating or 
fertilization of the queen’s eggs.

Queens that were allowed to settle naturally had lower 
survival rates exhaustion due to higher energy expenditure. 
As these queens had been on a mating flight and subsequently 
fed their developing larvae with food derived from their body 
reserves. They used more energy than queens that did not 
participate in mating flights. This higher energy consumption 
led to a slightly lower survival (King’ori, 2012).

All the founding queens laid eggs and shed their wings 
but only eggs from 71 queens (68.93%) were hatched. Thus, 
mating for viable offsprings may sometimes be unsuccessful. 
We hypothesized that hatching of the laid eggs is affected 
by the environmental conditions that prevailed in rearing 
units particularly the temperature. Further research might 
be needed to confirm this supposition. Time from nuptial 
flights to egg laying and shedding wing was associated with 
eggs hatching. Early laid eggs hatched successfully unlike 
late laid ones. No eggs hatched from any queen that started 
laying eggs beyond 6th day after the flight.  High percentage 
(88.73%) of queens with hatched eggs laid eggs within 
three days following nuptial flights.  This means that, eggs 
hatching can be predicted by more than 88 % within three 
days rearing.  

Variation in time taken to egg hatching was also 
noted. More egg hatches were observed in the 11th, 12 and 
13th days, with the highest on the 13th day. These results 
contrast with Vanderplank (1960) who reported that, time 
from nuptial flights to egg hatching is the same for all new 
queens reared at the same temperature.  He reported that 
eggs from 24 queens reared at 28 ºC took 6 and half days to 
hatch where as at 33 ºC took only 4 days. 

We therefore conclude that mating is most likely to 
take place after queens disperse. This is further supported 
by the fact that attempts to mate queens in artificial nests 
was unsuccessful, and that several hundred attempts to mate 
Australian and Thai O. smaragdina sexuals in artificial 
enclosures have been, equally, unsuccessful (Morgens G. 
Nielsen, Personal communication).

Eggs hatch day
Number of 
queens hatched

% queens 
hatched

     Statistics

Day 10 2 2.9

Day 11 11 15.94

Day 12 16 23.18 χ
2=60.07, df, 

5, p=<0.0001

Day 13 32 46.38

Day 14 4 5.8

Above 14 4 5.8

Total 69 100

Table 2:  Time taken to hatching of eggs into larvae. 

Duration (days) 1-3 days 4-6 days >6 days Statistic N

% Shedding wings 78.64 (81) 8.74 (9) 12.62 (13) χ2=52.12, df, 2, p=<0.0001 103

% Laying eggs 68.93 (71) 13.59 (14) 17.48 (18) χ2=67.79, df, 2, p=<0.0001 103

Table 1. Time taken for initiation of wing shedding and egg laying in founding O. longinoda queens. 



WA Nene, GM Rwegasira, J Offenberg, M Mwatawala, MG Nielsen – African Weaver Ant Mating Behavior400

Acknowledgements

This study was funded by DANIDA through Project 
DFC 10-025 AU. We thank Prof. Renkang Peng, for his 
technical guidance during experimental design. Messrs. 
Hasan Libubulu and Frank Thadeo are acknowledged for their 
assistance in data collection. We thank Naliendele Agricultural 
Research Institute for providing the fields and screen houses 
for the experiments as well as working facilities. 

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