Behavioral Ecology VoL 9 No. 5: 432-458
Paying to stay or paying to breed? Field
evidence for direct benefits of helping
behavior in a cooperatively breeding fish
Sigal Balshine-Earn, Francis C Neat, Hannah Reid, and Michael Taborsky
Konrad Lorenz Institute for Comparative Ethology (KLTVV), Savoyenstrasse la, A-1160, Vienna,
Austria
T n a variety of taxa, from insects to mammals, individuals
X forgo opportunities to reproduce and help others to breed
(Bourke, 1997; Brown, 1987; Riedman, 1982; Stacey and Koenig, 1990; Taborsky, 1994). This puzzling behavior has stimulated theoretical investigations (Brown and Pimm, 1985; Hamilton, 1964; Jamieson, 1989; Trivers, 1971; Zahavi, 1976) and
two decades of long-term empirical work on animal cooperative breeding (see Emlen, 1991; Solomon and French, 1997;
Stacey and Koenig, 1990, for reviews). Studies of these social
systems have concentrated on two related questions: why do
the helpers remain on the natal territory? and why do they
help?
A number of studies have successfully provided an answer
to the first question by showing that in many cooperative
breeders, helpers are prevented from breeding or dispersing
by particular environmental factors (Komdeur, 1992; PruettJones and Lewis, 1990). However, the question of why helpers
help remains a hotly debated issue (reviewed by Emlen, 1994;
Heinsohn et aL, 1990).
Helping behavior has fitness costs (Heinsohn and Cockburn, 1994), and therefore much effort has been expended
to explain the benefits of helping behavior. Many studies have
sought to understand the selective advantages to helpers in
terms of kin selection (indirect benefits; Hamilton, 1964), but
the existence of unrelated helpers in many cooperatively
breeding species indicates that kin selection cannot be the
only explanation for helping behavior (Brown, 1987; Creel
and Waser, 1994; Reyer, 1980; Rood, 1978,1990). It has therefore been suggested that helpers may also gain direct benefits
Address correspondence to S. Balahine-Earn. E-mail: ttgalOUrw.
oeawjtcju.
Received 30 September 1997; reviled 22 December 1997; accepted
23 December 1997.
O 1998 International Society for Behavioral Ecology
from helping behavior. Helpers may benefit by (1) receiving
reciprocated help in the future (Ligon and Ligon, 1978; Trivers, 1971); (2) gaining protection and feeding benefits in the
established territory (Gaston, 1978; Taborsky, 1984,1985); (3)
gaining parental experience (Brown, 1987; Komdeur, 1996;
Lawton and Guindon, 1981); (4) increasing the probability of
their survival through group augmentation (Taborsky, 1984;
Brown, 1987); and (5) increasing the probability of mate or
territory acquisition (Reyer, 1980; Woolfenden and Fitzpatrick, 1984).
Correlations from field data support several of the hypotheses mentioned above—e.g., kin selection (Brown, 1987; Emlen aad Wrege, 1988; Taborsky, 1984), parental experience
(Rowley and Russell, 1990); territory inheritance (Mech,
1970; Woolfenden and Fitzpatrick, 1978, 1984), and mate acquisition (Clarke, 1984, 1989; Reyer, 1980, 1984, 1986). In
most species, we have yet to determine the relative importance of each influence for explaining the evolution of helping behavior. Furthermore, it is likely that several benefits accumulate and that these may be of different relative importance in different species. Moreover, the potential benefits
gained by helpers may operate together, e.g., when an individual provides help it gains parental experience, assists its
group and creates more relatives. Although each hypothesis
proposes a different mechanism for the evolution of helping
behavior, each predicts similar outcomes (e.g., an active helper that eventually obtains breeding status can be viewed as
evidence for more than one hypothesis). Experiments aimed
at testing specific aspects of helping behavior are the only way
to tease the hypotheses apart and assess the relative merit of
ideas fouod « B immanipiiiateri geld observations (see Taborp
sky, 1984, 1985).
Previously, the main targets of research on cooperative
breeding have been birds and mammal*, which are relatively
difficult to manipulate experimentally. However, the cooperatively breeding cichlid fish Neolamprologus pulcher is small,
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Several hypotheses aim to explain the evolution of helping behavior, but conclusive experimental support for evaluating the
relative importance of individual hypotheses is still larking We report on two field experiments* conducted to test the "territory
inheritance" and "pay-to-stay" hypotheses in the cooperatively breeding cichlid fish Neolamprologus pulcher. The territory inheritance hypothesis was tested by removing one parent, which created breeding vacancies. In 39% of cases, same-sex helpers
took over the breeding spot; in 44% of cases helpers continued helping new breeders, and 17% were evicted by new breeders.
Helpers that were closely sjze matched to the removed breeder had a better chance of gaining the breeding spot Male helpers
tended to continue helping after a takeover more often than females. The pay-to-stay hypothesis was tested by temporarily
removing helpers. Whereas breeders did not respond aggressively to removals, other group members attacked the removed
helpers on their return, and 29% were eventually evicted. The returning helpers assisted more by increasing their rate of
territory maintenance and defense and visiting the brood chamber more frequently. Size and tex of removed helpers did not
explain the observed aggressive reactions of other group members. Thus, our results support both hypotheses: N. pulcher needs
to pay with help to be allowed to remain protected in the family group, and there they may inherit the natal territory. N. pulcher
helpers gain direct benefits from helping behavior. Key words:riehlids,cooperative breeding, helping behavior, Neolamprologus
pulcher, territory inheritance. [Behav Ecol 9:432-438 (1998)]
Balihine-Earn et al. • Benefits of helping in a. cichlid
METHODS
We studied 74 N. pulcher families in 12 colonies in Lake Tanganyika, Zambia. Eleven colonies (7-9 m depth, approximately 175 m from the shore) were located in Kasakalawe Bay (west
of Mpulungu); one (3 m depth, 5 m from the shore) was at
Mutondwe Island (east of Mpulungu). A colony consists of a
group of clustered territories that share common boundaries.
Our study was conducted from 17 December 1996 to 8 April
1997. Observations were made by scuba diving.
Frequencies of all helping behaviors per watch (brood care:
number of visits to and duration in the brood chamber; territory maintenance- digging and carrying; and defense: attacks on neighbors and predators) were recorded. As it was
not possible to observe behavior in the brood chamber, we
measured the duration and frequency of visits to the brood
chamber and ascribed these as brood care (see Coeckelberghs, 1974, for an ethogram of the full set of behaviors
recorded.) We allowed for a 5-min habituation period before
each 15-min focal watch.
Fish were captured by guiding them into transparent plexiglass tubes with hand nets. Fish were measured (standard
length and depth, cm), sexed, and individually marked by fin
clipping and injection of nontoxic acrylic paints (3 colors)
into 1-3 scale pouches in 16 possible locations on the body
(Dierkes, 1996). Fish were then released back into their territory.
Territory Inheritance hypotheaia
Of the 74 famines studied, 18 were selected that contained a
large sexually mature helper about the size of the male (n =
9) or the female breeder (n = 9). The mean size difference
between the 18 selected pairs of helpers and breeders was 0 3 0
cm standard length (SL) ± 0.13 (0.40 cm «« median). Each
of the breeding male, female, and focal helper in these families were observed for 15-min focal watches twice a day for 2
days. Then the breeding male was removed in the nine families with a large male helper and the female breeder removed
in the nine families with a large female helper. The focal helper was observed for another two 15-min focal watches, the first
and second day after the breeder removals, once in the afternoon and once in the morning (a total of four watches). We
recorded all helping behaviors as well as breeding male-female and breeder-helper interactions before and after the
removals. This experiment was conducted 24-31 March and
was timed to coincide with the peak spawning activity that
occurs following the full moon (24 March).
Pay-to-stay hypothesis
On average families contained five helpers. Out of the 74 families, 17 families were selected because they had two sexually
mature (>3.5 cm) helpers that could be matched for size and
sex. These helpers' mean size was 4.7 cm (3.6-^5.7 cm). Overall, helper number in these particular families ranged from 2
to 13. In each family, one of the two matched helpers was
randomly chosen as die control, the second as the experimentaL The experimental helper was observed for 15 min
before die removal and then removed from its family for 4 6 h. During die removal it was placed in a mesh cage (30 cm
X 20 cm X 20 cm) several meters away from die colony and
out of sight from die odier family members.
Direcdy before returning die experimental helper, die control helper was observed for 15 min. We observed die control
helper to ensure diat any changes in behaviors were a result
of die removal and not simply caused by a numerical change
in die group or a temporal fluctuation in activity patterns. The
experimental helper was then returned and observed again
for 15 min, as was die control helper. The experimental fish
was observed again for 15 min die next day. Therefore, each
experimental family was observed for 75 min in total.
RESUETS
Territory inheritance hypodiesis
Seven out of 18 helpers (39%) took over die vacant breeding
spot and showed behavior typical of breeders. The male removals resulted in diree territory takeovers by male helpers,
whereas six male helpers remained as helpers with new males.
In die families where breeding females were removed, four
female helpers took over die breeding vacancy, two helpers
continued helping for a new female, and three female helpers
were evicted by new females. In all but one group, takeovers
occurred before die next observation period.
In diis one group (mentioned above) initially die female
helper behaved as a breeding female around a secondary shelter, courting and being courted by die breeding male and codefending diis shelter. However, die breeding male also courted a new female in die primary shelter (brood chamber). By
die next day, die ex-helper (injured by die new female)
moved out of die natal territory. Although diis is only a single
example and we did not observe die takeover, it is possible
diat all disappearances followed failed takeover attempts. We
plan to investigate diis idea in future work.
There were no sex differences in die likelihood of a take-
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easily ought, fast growing (range of sexually mature fish 3 3 8 cm), and responds well to experimental manipulations.
Therefore it is an ideal species to test which factors select for
helping behavior and drive its evolution.
N. pulchti; sometimes called NaAamprologus brichardi is an
endemic fish in Lake Tanganyika, Zambia, that inhabits small
territories along the rocky shores from 3 to 45 m depth (Taborsky and Iimberger, 1981). (We believe Neolamprologus
pulcher and N. brichardi are one species and discuss this issue
in detail elsewhere.) Breeders in this species are assisted by
"helpers" in rearing young. Around the full moon, the female
lays batches of eggs within a shelter (or brood chamber), and
the male fertilizes them. The eggs hatch after 3-4 days, but
the larvae remain in the brood chamber for another 8-9 days.
The eggs and larvae are tended in the brood chamber, which
also serves as the principal shelter site for the family group.
Most free-swimming fry emerge around the new moon (personal observations). Besides the breeders, helpers (usually
born in the territory) will contribute by sharing in all duties
of brood care, territory defense, and maintenance. Helpers
defend the territory by attacking potential space competitors
and predators. They maintain die territory by removing particles or snails and by digging sand and debris away from the
breeding shelter. They also join in direct brood care by cleaning and fanning eggs and larvae and defend the free-swimming fry from predators (Taborsky and Limberger, 1981).
In this study we had two principal aims. First, we wanted to
determine whether helpers helped to be in close proximity
when breeding vacancies became available in their own natal
territories. We tested diis "territory inheritance" hypothesis
by removing breeders from territories that contained large
helpers and then monitored whedier these helpers took over
the available breeding slot Second, we sought to establish
whether helpers help in return for being permitted to stay in
their territory, which provides shelter and hence protection
from predators. We tested this "pay-to-stay" hypothesis by manipulating helping effort through temporary removals of specific individuals and then monitoring their behavior and the
behavior of breeders and other group members toward them
before and after the removals.
433
Behavioral Ecology Vol. 9 No. 5
434
b.
"3
54-
8
e
321-
S-2
Before
Breeder Removal
Before
Breeder Removal
After
Breeder Removal
After
Breeder Removal
d.
400-,
o
300-1
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8-.
765-
jL 200-
4-
"3
3-
8J
8\&
100 -I
21-
1
0
Before
Breeder Removal
After
Breeder Removal
Before
Breeder Removal
After
Breeder Removal
Figure 1
The frequency of brood-care behaviors performed by focal helper* before and after breeders were removed. The mean frequency of (a)
brood chamber visits, (b) defense, (c) feeding rates, and (d) opposite-sex associations (n — 18 helpers). Bars are standard errors.
over (fisher's Exact test, p = .33), nor of being evicted (Fisher's Exact test, p m .10). However, there was a tendency for
more males to stay on their natal territory as helpers (Fisher's
Exact teat, p = .07).
Ex-helpers who took over behaved as dominant breeders.
Comparison between before and after the breeder removals
revealed that after breeder removal, all focal helpers (both
sexes combined) increased: the number of visits to the brood
chamber (n = 18, z = 2.0, p = .05), rates of defense (n »
18, z " 2.3, p " .03), and associations with the opposite sex
(non-removed) breeder (n - 18, z =» 2.9, p = .004) increased,
but feeding decreased (n = 18, z - 2.3, p = .02). Associations
includefl Courtship displays (parallel swimming, shakes, qwvers, etc) as well as Joint visits to the brood chamber. These
former helpers also received more submissive displays after
the removal (n •» 18, z = 2.7, p - .006; Figure 1).
In general, breeders were larger than helpers. Focal helpers
closest in body size (standard length) to breeder size were
more likely to take over [Kruskal WalHs test, H (corrected for
ties) = 13, p " .02; Figure 2]. Multiple comparisons between
treatments (following the Kruskal Wallis test; Siegel and Castellan, 1988) indicated that takeover helpers were more closely matched in body size to breeders when compared to helpers
that remained as helpers for new breeders or helpers that
were evicted when a nongroup member took over (critical
value = 6.6, |i?ro - ^nJ = 7.1, critical value - 8.7, [R
- 2.8, critical value => 10.6, [ ^ - R^ = 4.3).
Pay-to«tay hypothesis
Breeders' and other group members'responses to the removals
Upon release, helpers typically swam into the center of the
territory and within 1 min were detected by other group
members. We defined detection as any group members who
oriented and approached (within 10 cm) the returned help-
Balshine-Earn et aL • Benefits of helping in a cichlid
rr
10
Table 1
The relative change in »m""lrr and helping behaviors shown to
and by males and females (expressed as frequency of behaviors
arer removal minus irequency t>etore tnie remove
CO
I
f
8
2
I
435
0.8
Fe-
Males
(n-8)
0.6
Breeder aggressicm (bites.
chases, rams, mouth fights and
threat displays)
Other group members
aggression
Defense behaviors
Territory maintenance
behaviors
Time (5) in brood chamber
No. visits to brood chamber
0.4
0.2
0.0
Take OVer
Evicted
Stay as Helper
ers. They were either passively accepted back or were subjected to harassment We examined the reactions of the breeders
and other group members separately. In 3 cases out of 17,
breeders attacked the returned individuals, but the other
breeders ignored the returning helpers. We compared the
number of attacks removed helpers received from breeders
before and after the removals and found no significant difference [Wilcoxon matched-pairs test, n = 17, z (tied) •» 1.2,
p = .24]. We did not detect any initial behavioral differences
between experimental helpers that were ignored and those
that were attacked.
In contrast, nine returning helpers were aggressively attacked (bitten, rammed, and chased) by the other helpers in
their group. We compared number of attacks by other helpers
on the removed helpers before and after the removal and
found that the number of attacks significantly increased [WUcoxon test (all aggressive behaviors pooled), n =» 17, z (tied)
= 2.0, p = .04]. The experimental helpers typically responded
to this aggression with increased subordinate displays, which
usually appease aggression [Wilcoxon test, n = 17,1 (tied) =
3.2, p m .002]. In addition, returned helpers also increased
their rates of help: they performed more defense behaviors
against predators and space competitors [n = 17, z (tied) =
2.5, p •» .01], tended to spend more time maintaining the
territory [n = 17, z (tied) = 1.7, p - .08], visited the brood
chamber more frequently [n • 17, z (tied) =» 2.6, p = .01],
and spent more time in die brood chamber [n = 17, z (tied)
= 23, p - .01; Figure 3].
No differences in aggressive reactions (breeders and other
helpers) were found between the experimental helpers before
the removals versus the control matched helpers after the removals [breeders' responses: n •= 17, z (tied) =• 1.0, p - .34;
other group members: n = 17, z (tied) = 0.6, p = .58]. As
mentioned above, these control helpers were used to ensure
that any changes in behaviors were not simply caused by a
numerical change in the group or a temporal fluctuation in
activity patterns. For example, the control helpers visited the
brood chamber more frequently than die experimental helpers before the removals [Wilcoxon test, n = 17, 1 (tied) =
P
0.5
0
-0.9
0.40
0
2
0
5
-1.0
-1.2
0.34
0.23
0
20
0
61
9
-0.3
-1.2
-Z5
0.76
0.23
0.02
3
Median values are presented; Mann-Whitney tests were used.
2.0, p = .04]. However, control helpers were sampled later in
die day, and this probably accounts for their higher visitation
rates. In a separate study, we found that, on average, helpers
visited the brood chamber for 65 s per 15 min between 0600
and 1200 h and for 192 s between 1200 and 1800 h [Wilcoxon
signed-ranks test, n = 65, z (tied) - 2.6, p = .01]. No differences were found in die frequency of other helping behaviors
between experimental and controls [territory defense: n =
17, z (tied) = 0.3, p = .78; territory maintenance: n = 17, z
(tied) = 0.5, p = J59;timein brood chamber n = 17, z (tied)
= 0.8, p = .44].
Evictions
One day after die removals, 5 of die 17 removed helpers had
disappeared. They were not seen again on their natal territories or anywhere else. Size and sex did not explain the evictions, but the sample size is small. We observed these families
for nearly 3 months before performing die removal experiments. Unmanipulated helpers were never observed to be
forcibly evicted by breeders or odier group members. Helper
disappearances were infrequently recorded, but these were al-
TableZ
The relative change in aggiesalte and helping behaviors shown to
and by large versus small helpers (expressed as frequency of
behaviors after removal niiniif frequency before the removal)
Small
Large
helpers helpers
(n=10) (n-7) 1 (tied)
Breeder aggression
Other group members
aggression
Defense behaviors
Territory maintenance
behaviors
Time (s) in brood
chamber
No. visits to brood
chamber
p
0.5
0
-0.8
0.42
0
3
0
5
-0.8
-0.8
0.44
0.41
0
0
-0.4
0.72
39
87
-0.8
0.43
5
-0.1
0.92
53
Median values are presented; Mann-Whitney tests were used.
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Figure 2
The median difference in body length in centimeters (standard
length) between the removed breeders and the focal helper in
families where the helper took over (solid bar), was evicted (striped
bar), or stayed on as a helper for a new breeder (open bar).
males
(n-9) z (tied)
436
Behavioral Ecology Vol. 9 No. 5
b.
4 ,
8 ,
7 -
3-
6 -
I
&
5 2 -
4 3 -
1 .
2 1 .
0 -
Before
Helper Removal
Before
Helper Removal
After
Helper Removal
d.
c.
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c
o
&
After
Helper Removal
120
100 .
8 5
80 .
o
6-
60 .
S3
4-
40 .
CQ
20 .
2-
0 .
Before
Helper Removal
After
Helper Removal
Before
Helper Removal
After
Helper Removal
Figure 3
The mean frequency of helping behavion performed by die experimental helper before and after it was removed (a) defense, (b)
maintenance, (c) time in brood chamber, (d) number of brood chamber visits (n = 17 helper removals). Bars are standard errors.
ways associated with predation (e.g., attacks observed or scars
on the body the day before disappearing) or marking. We
randomly selected 17 unmanipinated families (0 evictions)
and compared the probabilities of evictions with the 17 families in which we temporarily removed helpers. These unmanipulated families were marked and observed for a period of
2-3 months during which family number and composition
were recorded weekly. The rate of eviction was greater than
one would expect by chance in the families where helpers
were removed (Fisher's Exact test, p •» .02). Family size
seemetf to nave no influence on eviction rates: three of five
evictions that followed the removals occurred infamiliesthat
were smaller than the average (mean = 7 individuals; 4, 6,
and 6 individuals, respectively), and two evictions occurred in
families that were larger than the average (10 and 13 individuals).
Sex and six*
Eight of the 17 removed helpers were males and 9 were females. We examined breeder responses, other helpers responses, and helping rates of removed helpers for males and
females separately and found that sex only influenced the
number of brood chamber visits (Table 1). Female helpers
visited the brood chamber relatively more often after the removals than did male helpers.
Although all the experimental helpers in this study were
presumably sexually mature (>3J5 cm SL), we divided helpers
kite twe site groups to chock for size effects: small (3.6-4.9
cm SL individuals, n = 10) and large helpers (5-5.7 cm SL
individuals, n «• 7). We examined breeders responses, other
group member responses, and helping rates in relation to size
and found that body size did not influence these factors (Table 2).
Balihine-Eam ct aL • Benefit* of helping in a richlid
DISCUSSION
Territory
Pay to stay
N. piUcher breeders usually ignored returning helpers, whereas other helpers attacked them, and 5 out of 17 returned
helpers were eventually evicted. Differences in size and sex
between helpers did not account for attacks received. Helpers
responded to aggression with submissive behavior and helped
to a greater extent after returning to their territories.
To explain why helpers attacked removed helpers, we propose diree potential explanations. First, helpers may have
been attacked because they were not recognized. This is extremely unlikely for a number of reasons. (1) There is strong
experimental evidence that N. pulcher has finely tuned visual
recognition capabilities. Parents can discriminate their own
helpers from other helpers of similar size (Hert, 1985). In
addition, N. pulcher rezca appropriately to video playbacks of
familiar versus unfamiliar conspecifics (Balshine-Earn and Lotem, 1998). (2) Recognition of other group members is critically important and likely in a cooperative social species. Selection should favor the ability to distinguish between the acceptable presence of helpers and unwelcome strangers. (3)
Breeders largely ignored helpers, which suggests that removed
helpers were recognized. Strange fish and philandering
neighbors are vigorously attacked by all members of the family
(personal observations). Unlike intruders, who normally flee
from the attack, returned helpers attempted to stay and im-
mediately rejoined in group activities. Therefore we reject this
explanation.
Second, lazy helpers may be attacked as punishment for not
helping. But why should other helpers punish if breeders do
not? The presence of helpers increases fecundity of female
breeders (Taborsky, 1984), so breeders were expected to bear
the cost (both time and energy) of punishment Perhaps
breeders only demand help when it is needed (e.g., in a laboratory experiment, previously expelled helpers were reaccepted when space competitors were introduced; Taborsky,
1985). Other helpers may have punished "lazy" helpers because each helper's presence or efforts may reduce the risks
and workload (and hence increase feeding opportunities) for
other helpers in the family. In another study we were able to
show that feeding rates are higher in larger groups with more
helpers (Balihine-Eam et aL, unpublished)
Third, other helpers may have been aggressive ai a result
of a change in the social status and the dominance hierarchy
being reestablished in die group after the removal. If there is
a queue for die breeding spot, helpers may fight hard to remove anodier helper (potentially in front of them) from the
queue. A breeding queue may explain why it pays to stay and
help. We favor this explanation because it appears to be the
most parsimonious; additional work is required to confirm
diis.
Why did returning helpers help more? Perhaps "help" signals group membership and commitment So helping may reduce the likelihood of attack or eviction. Alternatively, helping
may be a mechanism for establishing or maintaining dominance (Zahavi, 1976).
Our study is die second to date to experimentally test the
pay-to-stay hypothesis in the field. Mulder and Langmore
(1993) removed superb fairy wren helpers and found that
only the dominant male attacked these helpers, and then only
during egg incubation and chick-feeding stages. Our experiment was conducted from 15 to 24 March 1997 following new
moon (when fry usually emerge), a period when fry defense
should be essential. Unfortunately, only 3 of our 17 families
contained newly emerged fry. In one such family the temporarily removed helper was eventually evicted. The sample of
families with fry was too small to examine die aggressive response in relation to die importance of helper contributions.
However, Mulder and Langmore's study and ours illustrate
diat die reasons for tolerating helpers may vary across species
and populations (Qutton-Brock 8c Parker, 1995).
In conclusion, although the costs of family life have been
measured in die laboratory and die field (Grantner and Taborsky, in press; Heinsohn and Cockbura, 1994; Taborsky,
1984; Taborsky and Grantner, in press), attempts to experimentally measure die potential benefits of helping under natural conditions are rare. We designed this study to separate
and evaluate die relative importance of two likely factors selecting for helping behavior in N. pulcher. We found evidence
for bodi pay-to-stay and territory inheritance hypodieses, and
more experiments will be needed to evaluate die relative importance of each. Large helpers can inherit dieir natal territories, and they seem to help to remain in the safety of die
group and territory. N. pulcher probably must help while it
waits to inherit a breeding spot
S3.-E. was supported by a Royal Society Research European Exchange
Fellowship and M.T. by a Fondi nir F&rderung der wissauchaftHchen
Fonchung grant (P10916-BIO). We thank the Austrian Academy of
Sciences for funding. We thank David Earn, Aitrid Grantner, Eva Skubic, and Martine Maanforuseful comments on the manuscript; Bridget Applcby, Nick Davies, Tim Clutton-Brock, Gabriella Lichtenstein,
Anna Iindholm, and Araon Lotem for discussion; Lenard Mwape,
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After removal of breeders, helpers either took over (S9% of
cases), remained on as helpers with a new breeder (44%), or
were evicted from their natal territories (17%). Male helpers
were never evicted and were more likely to remain and help.
Takeovers were more likely when the body size difference between helper and breeder was small, Helpers that did not take
over the breeding vacancy may not have been large enough
to compete with other potential breeders in the area.
In our experiment, we created breeding vacancies in the
helper's own natal territories (as did Taborsky, 1984). Thus
we were testing the hypothesis that helpers remain on natal
territories to increase their chances of inheritance. In the first
such experiment conducted on cooperatively breeding birds,
Pruettjones and Lewis (1990) created 33 breeding vacancies
for superb fairy wrens by removing male neighbors. All but
two potential breeders dispersed into the created vacancies,
but only when the territory contained a female. Pruettjones
and Lewis designed their experiment to determine why helpers stay. Young, male superb fairy wrens may take over neighboring territories, and they seem to delay dispersal in response to a limited number of mates and secondarily to habitat limitation. Conversely, our experiment was designed to
investigate why helpers help. Our results showed that helpers
(both sexes) might help because they may gain fitness benefits
by inheriting the breeding spot (both a mate and a territory).
In Zambia (southern shore of Lake Tanganyika) helpers
frequently took over (7/17 cases). In contrast to our results,
in the northern part of the lake (Burundi), Taborsky (1984)
found that helpers never inherited the natal territory when
breeding vacancies were experimentally created (0/10 cases),
although helper disappearances were observed after breeder
removals (Taborsky, 1982,1984). The significant difference in
takeover rates was probably a result of the environmental and
demographic differences between north and south populations. In the north, the habitat was saturated (shelters are
scarce) and fish live in large feeding aggregations after leaving
their natal territories (Taborsky, 1984). In the south shelters
abound, and feeding aggregations were never observed.
437
438
the Zambtan Ministry of Agriculture, Food and Fisheries, Ruben Shapola, and David Ngundu for their assistance and technical support.
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Behavioral Ecology Vol. 9 No. 5