BACKGROUND: Ecosystem engineering may influence community structure and biodiversity by controlling the availability of resources and/or habitats used by other organisms. Insect herbivores may act as ecosystem engineers but there is still poor understanding of the role of these insects structuring arthropod communities. METHODOLOGY/PRINCIPAL FINDINGS: We evaluated the effect of ecosystem engineering by the stem-borer Oncideres albomarginata chamela on the arthropod community of a tropical dry forest for three consecutive years. The results showed that ecosystem engineering by O. albomarginata chamela had strong positive effects on the colonization, abundance, species richness and composition of the associated arthropod community, and it occurred mainly through the creation of a habitat with high availability of oviposition sites for secondary colonizers. These effects cascade upward to higher trophic levels. Overall, ecosystem engineering by O. albomarginata chamela was responsible for nearly 95% of the abundance of secondary colonizers and 82% of the species richness. CONCLUSIONS/SIGNIFICANCE: Our results suggest that ecosystem engineering by O. albomarginata chamela is a keystone process structuring an arthropod community composed by xylovores, predators and parasitoids. This study is the first to empirically demonstrate the effect of the ecosystem engineering by stem-boring insects on important attributes of arthropod communities. The results of this study have important implications for conservation.
BACKGROUND: Ecosystem engineering may influence community structure and biodiversity by controlling the availability of resources and/or habitats used by other organisms. Insect herbivores may act as ecosystem engineers but there is still poor understanding of the role of these insects structuring arthropod communities. METHODOLOGY/PRINCIPAL FINDINGS: We evaluated the effect of ecosystem engineering by the stem-borer Oncideres albomarginata chamela on the arthropod community of a tropical dry forest for three consecutive years. The results showed that ecosystem engineering by O. albomarginata chamela had strong positive effects on the colonization, abundance, species richness and composition of the associated arthropod community, and it occurred mainly through the creation of a habitat with high availability of oviposition sites for secondary colonizers. These effects cascade upward to higher trophic levels. Overall, ecosystem engineering by O. albomarginata chamela was responsible for nearly 95% of the abundance of secondary colonizers and 82% of the species richness. CONCLUSIONS/SIGNIFICANCE: Our results suggest that ecosystem engineering by O. albomarginata chamela is a keystone process structuring an arthropod community composed by xylovores, predators and parasitoids. This study is the first to empirically demonstrate the effect of the ecosystem engineering by stem-boring insects on important attributes of arthropod communities. The results of this study have important implications for conservation.
One of the central issues in ecology is to understand the mechanisms that structure
ecological communities. Even though direct pairwise interactions (e.g. competition
and predation) play a major role in explaining the structure of many biological
communities (e.g. [1], [2]), other interactions can also be important [3], [4]. One
interaction with important consequences on biological communities and biodiversity
is the relationship between organisms that modify or create new habitats with those
organisms that use these new habitats, a process called “ecosystem
engineering” [5], or habitat modification [6]. Ecosystem engineers are
species that control the availability of resources for other species by causing
physical state changes in biotic or abiotic materials [5]. Because some ecosystem engineers
create habitats where entire communities establish, they are also called
“foundation species” [6] or “keystone
engineers”, when the impact of the ecosystem engineer is higher than its
abundance [7].
Currently, an increasing number of studies have experimentally demonstrated that
some species act as ecosystem engineers (e.g. beavers, salmons, pocket-gophers)
affecting communities and ecosystems (reviewed in [8], [9]).Several insect herbivores manipulate their host-plants to build a variety of
structures, which are secondarily occupied by organisms other than the original
constructor. Hence, these herbivores can act as ecosystem engineers [10]. However, the
role of insects as ecosystem engineers has only been experimentally evaluated for
leaf-rollers [11], [12], gall makers [13] and leaf miners [14], [15]. These studies
indicate that ecosystem engineering by insect herbivores influence overall
abundance, species richness, and composition of arthropod communities by providing
new habitats for other herbivores that are used for shelter (from natural enemies
and adverse microclimates) and for more nutritious food [4], [10]–[15]. Ecosystem engineering effects
can propagate to higher trophic levels, triggering cascades of interactions
including trophic, antagonistic and mutualistic interactions [4], [11], [13].One insect guild comparatively less studied in this regard is represented by
stem-borers, which are insects that develop (for at least part of their life cycle)
in wood, bark or woody stems of plants [16]. Many of them begin their
life cycle as eggs laid under bark by free-living adult females; the larvae feed on
the wood inside stems and eventually emerge as adults to repeat the cycle [16]. The
stem-boring larvae produce complex systems of cavities that can be secondarily
occupied by other arthropods [10], [17]–[20]. This suggests that the guild of stem-borers includes
several species that can act as ecosystem engineers. However, empirical studies
evaluating the effects of stem engineering on arthropod communities are currently
lacking.Stem-boring insects play important functional roles in forest ecosystems, as they
contribute to nutrient cycling [21]–[23], alteration of tree architecture [23], [24], resource regulation [25], and alteration
of the composition and hydrology of forests [25], [26]. Therefore, the study of
factors structuring their communities has important implications for forest
conservation.Here we present the results of a field experiment designed to evaluate the effect of
ecosystem engineering by the stem-boring beetle, Oncideres albomarginata
chamela (Cerambycidae: Lamiinae), on the arthropod community associated
with detached branches of Spondias purpurea (Anacardiaceae). The
study was carried out for three consecutive years. O. albomarginata
chamela actively manipulates its host plant through a process
consisting of two steps. First, adult females of O. albomarginata
chamela preferentially girdle and detach reproductive branches of
S. purpurea, before the reproductive season of the tree [27], when
reproductive branches have accumulated the maximum concentration of non-structural
carbohydrates [28] and nitrogen [27]. Second, adult females make
incisions and gnaw egg niches along the detached branches for oviposition [27]. Therefore,
O. albomarginata chamela females provide a high quality
environment for offspring development [29]. Incidentally, these females
also provide a suitable environment for secondary colonization [30], particularly for insects that
oviposit opportunistically in cracks and crevices in the bark or cortex of plants
[16], [30].Based on this evidence, we hypothesized that the modification of tree branches by
O. albomarginata chamela plays a key role in the establishment
of a new arthropod community and promotes interactions with positive effects on
arthropod abundance and diversity. To test this hypothesis, we simulated O.
albomarginata chamela physical modification of S.
purpurea branches, and compared the community composition, frequency of
colonization, abundance and species richness of secondary arthropod colonizers
between non-engineered and engineered branches (both artificially and naturally
modified branches).
Methods
Ethics statement
All animals were handled according to relevant national and international
guidelines. Insects were reared at natural conditions at the study site, and
released in situ after the experiment. The animal work was
approved by the authorities of Chamela Biological Station, Universidad Nacional
Autónoma de México (National Autonomous University of Mexico), and
by national authorities of Secretaría de Medio Ambiente y Recursos
Naturales (Secretary of Environment and Natural Resources; SEMARNAT, permission
SGPA/DGVS/05876/10).
Study system
Oncideres albomarginata chamela Chemsak and Gisbert is a
longhorn beetle (Cerambycidae) that detaches branches 2–3 cm in diameter
from the tropical tree Spondias purpurea L. (Anacardiaceae),
and oviposits in them [27]. Alternative but less used host plants of O.
albomarginata chamela include: Comocladia
engleriana Loes (Anacardiaceae), Mangifera indica
L. (Anacardiaceae), Amphipterygium adstringens Schide ex
Schlecht (Rubiaceae), Bursera Jacq. ex L. spp. (Burseraceae),
Ceiba pentandra (L.) Gaertn (Bombacaceae),
Urera (L.) Gaud. sp. (Urticacaceae) and Delonix
regia (Bojer ex Hook) Raf. (Fabaceae) [31]. O. albomarginata
chamela is distributed in Mexico in the states of Jalisco, Nayarit,
Guerrero, Oaxaca, Chiapas and Veracruz [32], but O.
albomarginata Thomson is distributed in México, Central
America (Nicaragua) and South America (British and French Guiana, Venezuela)
[33]. The
body length of O. albomarginata chamela is 17–31 mm and
6.5–12 mm wide [32]. The reproductive period of this species is from
October to February; eggs hatch and larvae develop inside detached branches
until the adults emerge in low densities 6–8 months later. Adult females
of O. albomarginata chamela are the only herbivores at the
study site that detach branches of S. purpurea and immediately
oviposit in them [27], but after a certain period of time other species of
stem-boring beetles (mainly non-girdling species) take advantage of the detached
branches and oviposit in them as well.S. purpurea is a common dioecious tree of the tropical dry
forest of Mexico [28]. The ratio of male and female trees of S.
purpurea in the population at the study site is 1∶1 [27]. This
species can reach 15 m in height and almost 80 cm in diameter at the base;
leaves are compound with 5 to 12 elliptic-acute leaflets from 2 to 4 cm in
length [34].
Flowers are red, sessile, unisexual and dimorphic between males and females
[34].
Trees are deciduous with flowering and fruiting occurring from December to May,
and leaves are maintained from June to November [34].
Study site
The study was conducted in the Chamela-Cuixmala Biosphere Reserve at Chamela
Biological Station, UNAM (19°30′N, 105°03′W) located on the
Pacific coast of Jalisco, Mexico, from December 2006 to January 2010. The
vegetation is tropical dry forest with a mean annual rainfall of 707 mm and a
dry season that extends from November to June [35].
Experimental design
In order to evaluate the effect of ecosystem engineering by O.
albomarginata chamela on the arthropod community, during December
2006 to January 2008, we conducted a field experiment consisting of three
treatments (N ≈ 50 branches/treatment): O.
albomarginata chamela engineered and colonized-branches (OE),
artificially simulated engineered branches (SE), and non-engineered branches
(NE). For treatment OE, we collected branches of S. purpurea
naturally detached and colonized by O. albomarginata chamela on
December 2006. This treatment was used as control to provide baseline data on
the arthropod community associated with S. purpurea branches,
and to analyze the effects of the ecosystem engineer presence. For treatment SE,
branches exhibiting similar characteristics (reproductive branches from
2–3 cm in diameter) to those detached and colonized by O.
albomarginata chamela were artificially cut off from S.
purpurea trees. We artificially simulated the structural
modification of branches made by adult females of O. albomarginata
chamela, by making numerous incisions with scissors (every 5 mm) on
the bark of these branches. Treatment NE consisted of simply artificially
detached reproductive branches of 2–3 cm in diameter of S.
purpurea with no manipulation. We called this treatment
“non-engineered branches” because mechanical factors, such as wind,
water stress, mechanical branch damage, among others, detach a great proportion
of branches and twigs from trees in the study site. Specifically, broken
branches (2–20 cm in circumference) constitute the most important
component (43%) of the forest total above-ground dead phytomass in
Chamela tropical dry forest [36]. Thus, broken branches can represent non-engineered
but available habitats. All branches were marked, and they were left hanging on
the source-tree for 45 days (December 2006 to February 2007) to allow the
colonization of secondary opportunistic species. Our preliminary analysis
indicated that 30–45 days (during that period of the year) is when most
insect borers colonize S. purpurea detached branches. The
gender of each source-tree was registered. To control for the size of the
branches used for each treatment, we measured the diameter at the point of
branch cutting with an electronic caliper (Mytutoyo Inc). To control for adult
female host selection, we cut off two branches for treatments NE and SE from the
same tree where O. albomarginata chamela had previously
detached and colonized branches. Additionally, the treatments were conducted in
the same host plants to control for any related chemical attractive signals
emitted by the same tree, as well as to control for any other factors associated
with the nutritional value of host trees. Therefore, the branches of the three
treatments had the same probability to be located by secondary colonizers. After
45 days, all branches were enclosed in mesh bags (<0.5 mm mesh size) to
prevent further colonization and escape of the established fauna. Branches
collected in mesh bags were placed in an open room at the study site, and
maintained at local environmental conditions. Emerging arthropods from each
branch were recorded monthly from March 2007 to January 2008, and released. We
measured the total length of 20–40 adults of each insect species to
estimate the size of the secondary colonizers. The exact same experiment was
repeated for two more years: December 2007 to January 2009, and December 2008 to
January 2010. Taxonomic identification of species that emerged was carried out
by the beetle specialist Dr. Felipe A. Noguera and using available taxonomic
literature [37]–[39].
Data analysis
First, we compared the diameter (at the point of branch cutting) of detached
branches to determine differences in sizes between treatments, through one way
Analysis of Variance (ANOVA) using PROC ANOVA [40]. Our results indicated that
branch diameter did not differ significantly between treatments (2007: F2,
154 = 1.564, P = 0.213;
2008: F2, 155 = 1.068,
P = 0.346; 2009: F2,
178 = 0.263, P = 0.769). In a
previous study, Uribe-Mú and Quesada [27] found that branch gender
had no effect on O. albomarginata chamela larval performance.
Therefore we expected that branch gender had no effect on the number of
secondary colonizers emerging from S. purpurea branches. This
was confirmed when we analyzed the variation associated with branch gender
through a Generalized Linear Model using a GENMOD procedure [40], in which the
number of secondary colonizers that emerged from S. purpurea
branches was used as the response variable, and tree gender as the independent
variable. We used a Poisson distribution with a logarithmic link function for
the analysis and corrected for overdispersion of data. Tree gender had no
significant effect (2007: χ2 = 0.37,
P = 0.5428; 2008:
χ2 = 1.42, P = 0.2327;
2009: χ2 = 2.09,
P = 0.1479) and was not included in further analyses.Non-metric multidimensional scaling (NMDS) was used as an ordination procedure to
determine differences in community composition among OE, SE and NE branches. The
NMDS analysis was based on ranked Bray-Curtis dissimilarity distances [41]. Differences
in community composition between treatments were tested using an analysis of
similarity (ANOSIM), which uses 1000 random reassignments of species to groups
and determines whether the group assignments were significantly different from
those generated by chance. NMDS and ANOSIM analyses were performed with the
software PRIMER 5.2.9 for windows (PRIMER-Ltd, Plymouth, U.K.). Multiple
comparisons in ANOSIM were made using a sequential Bonferroni correction [42].To evaluate the effect of O. albomarginata chamela on the
frequency of colonization of S. purpurea branches by secondary
colonizers, each species was quantified as being present or absent. Data were
analyzed using a Generalized Linear Mixed Model that implements a generalization
of the standard linear model allowing the incorporation of random effects [43]. We used
the GLIMMIX procedure in SAS statistical software with a binomial distribution,
and a logit link function specified for the dependent variable [40]. Branch
condition (colonized vs. non-colonized) was the response
variable. Treatment, year and their interaction were included as fixed
variables, while tree identity and its interaction with treatment as random
effects. We used a Least Square Means (LSMeans) test for a
posteriori comparisons [40].Secondary xylovores showed two general traits in size and developmental time.
These are key life-history traits in insects related to fitness, habitat
selection, oviposition strategies, and response to natural enemies [44]. Therefore,
we used them to define two putative life forms: a) species with small body size
and short developmental time (life form I); and b) species with large body size
and longer developmental time (life form II). Natural enemies were analyzed
separately. A Generalized Linear Mixed Model was used to evaluate the effect of
O. albomarginata chamela on the abundance of the secondary
colonizers (SAS, GLIMMIX procedure) [40]. This model used: (i) the
number of adult secondary colonizers that emerged from branches as the response
variable, (ii) treatment, year and their interaction as fixed variables, and
(iii) plant identity and its interaction with treatment as random effects. We
used a Poisson distribution with a logarithmic link function in the analysis.
The degrees of freedom of F-tests for the fixed effects were adjusted using the
Satterthwaite method. To control for overdispersion, we applied a Poisson error
distribution to the model. We used LSMeans tests for a
posteriori comparisons [40].To determine the impact of ecosystem engineers on species richness of
engineered-habitats, we used a Generalized Linear Mixed Model (SAS, GLIMMIX
procedure) [40].
We used the same model applied for the abundance analysis, but in this case the
number of species that emerged from S. purpurea branches was
the response variable. An increased number of species is expected as a random
consequence of larger pools of individuals [45]. Therefore, to examine
whether treatment differences in the species richness of secondary colonizers
were driven by differences in the abundance of secondary colonizers, we
constructed rarefaction curves for each treatment. We used cumulative species
per branch including all branches sampled during the three study years (EcoSim
7.0, 10,000 iterations) [46].
Results
Effect of habitat engineering on community composition
In total, 28,301 secondary colonizers emerged from 478 detached branches of
S. purpurea in three consecutive years of study. These
included at least 25 species from eight families (Table 1), of which Bostrichidae (Coleoptera)
was the most abundant, comprising 76% (±10 SD) of the overall
natural arthropod community (Table 1), and Cerambycidae was the most diverse (9 spp.; Table 1). The natural
arthropod community consisted of xylovore and predatory beetles, and parasitic
wasps (Table 1). In
addition to secondary colonizers that use S. purpurea branches
for oviposition and offspring development, other “inquiline” species
(which eventually arrived to S. purpurea branches, but did not
oviposit in them) were recorded. These species included: termites, ants,
pseudoscorpions, spiders, crickets and silverfish. However, given that
inquilines emerged in very low numbers and were not present every year, we did
not consider them in further analyses.
Table 1
Secondary colonizers that emerged from Spondias
purpurea branches detached and colonized by
Oncideres albomarginata chamela.
Family
Abundance (%)
Species
Size (mm)
XYLOVORE BEETLES
Bostrichidae
75.76 (±9.8)
Amphicerus (LeConte) sp. ‡
11.13 (±1.43)
Bostrychopsis (Lesne) sp. †
3.58 (±0.23)
Dendrobiella (Casey) sp. *†
5.49 (±0.25)
Melalgus (Dejean) sp. ‡
11.56 (±1.42)
Micrapate (Casey) sp. †
3.56 (±0.18)
Prostephanus truncatus (Horn)
†
3.40 (±0.22)
Xylobiops (Casey) sp. †
3.71 (±0.24)
Curculionidae
4.10 (±3.1)
Hypothenemus (Weswoot) spp. †
1.59 (±0.27)
(Scolytinae)
Pityophthorus (Eichhoff) sp. †
2.00 (±0.25)
Lyctidae
7.07 (±3.7)
Lyctus (Fabricius) sp. †
3.11 (±0.38)
Buprestidae
1.45 (±1.2)
Acmaeodera (Eschscholtz) sp. †
6.27 (±0.54)
Agrilus (Curtis) sp. †
4.43 (±0.35)
Cerambycidae
3.25 (±2.6)
Ataxia alpha (Chemsak and
Noguera)*§
14.30 (±1.44)
Estoloides chamelae (Chemsak and
Noguera)*‡§
12.47 (±1.17)
Eutrichillus comus (Bartes) ‡
8.08 (±0.47)
Lagocheirus obsoletus (Thomson)
‡
13.52 (±1.53)
Lissonotus flavocinctus
(Dupont)*‡§
13.53 (±2.63)
Poliaenus hesperus (Chemsak and
Noguera) ‡
8.69 (±0.60)
Sphaenothecus maccartyi (Chemsak
and Noguera) ‡§
14.61 (±1.46)
Sphaenothecus trilineatus (Dupont)
‡
21.42 (±1.52)
Trachyderes mandibularis
(Serville)*‡§
21.97 (±0.79)
NATURAL ENEMIES
Predator beteles
Histeridae
7.58 (±3.2)
Teretriosoma nigrescens (Lewis)
†
2.26 (±0.16)
Cleridae
0.30 (±0.2)
Enoclerus quadrisignatus (Say.)
‡
10.40 (±0.64)
Parasitic waps
Hymenoptera
0.48 (±0.06)
ND §
ND
*Not recorded in 2007;
Life form I;
Life form II;
Not recorded in non-engineered branches (NE); ND
= not determined. Abundance values are means
across the three years (±SD).
*Not recorded in 2007;Life form I;Life form II;Not recorded in non-engineered branches (NE); ND
= not determined. Abundance values are means
across the three years (±SD).Secondary xylovores of life form I (Table 1) began to emerge one month after
branches were enclosed in mesh bags, with a maximum emergence peak recorded in
May. Secondary xylovores of life form II and natural enemies (Table 1) emerged throughout
the year, but their maximum emergence peaks were observed in September and July,
respectively. O. albomarginata chamela, the species with the
greatest size (23.58 mm ±2.24), was the last species to emerge (September
to December). These emergence patterns were consistent across years.There were significant differences in the composition of the community of
secondary colonizers between treatments (R = 0.425,
n = 478, P<0.01; Figure 1). However, the strongest differences
in community composition were between non-engineered (NE) and engineered (OE and
SE) branches (NE vs. OE: R = 0.691, P<0.01; NE
vs. SE: R = 0.574, P<0.01; SE vs.
OE: R = 0.098, P<0.01).
Figure 1
Arthropod community composition in detached Spondias
purpurea branches.
OE = O. albomarginata
chamela-engineered branches; SE =
simulated-engineered branches; and NE =
non-engineered branches. Each point is a two-dimensional (axis 1 and
axis 2) representation of the arthropod community composition on an
individual branch based on global non-metric multidimensional scaling
(NMDS) analysis (stress = 0.19).
Arthropod community composition in detached Spondias
purpurea branches.
OE = O. albomarginata
chamela-engineered branches; SE =
simulated-engineered branches; and NE =
non-engineered branches. Each point is a two-dimensional (axis 1 and
axis 2) representation of the arthropod community composition on an
individual branch based on global non-metric multidimensional scaling
(NMDS) analysis (stress = 0.19).
Effect of habitat engineering on branch colonization frequency by secondary
colonizers
Data analyses were performed separately by families, with the exception of
Bostrichidae, which were analyzed in two species groups because they exhibit two
different life forms (I and II; Table 1). The results indicated a highly significant effect of
treatment for all families, with the exception of Cleridae; a significant effect
of year for all families except for Buprestidae and Hymenoptera; and a
significant interaction between treatment and year for Bostrichidae life form
II, Lyctidae, Buprestidae and Histeridae (Table 2). All secondary colonizers
significantly colonized engineered branches (treatments OE and SE) more
frequently than non-engineered branches (NE; Figure 2), with the exception of Buprestidae
for which significant differences were found only between O.
albomarginata chamela-colonized branches (OE) and non-engineered
branches (NE) in 2007 and 2008 (Figure 2). The comparison between OE and SE treatments showed
variation across years and groups of secondary colonizers (Figure 2), but in general there were no
significant effects related to the presence of O. albomarginata
chamela.
Table 2
Effect of habitat engineering on branch colonization frequency by
secondary colonizers.
Family
Treatment
Year
Treatment x Year
df
F
P
df
F
P
df
F
P
Bostrichidae (Life form I)
2, 307
21.81
<0.0001
2, 307
5.72
0.0036
4, 307
0.47
0.7609
Bostrichidae (Life form II)
2, 259
22.21
<0.0001
2, 259
10.37
<0.0001
4,259
0.1584
<0.0001
Curculionidae (Scolytinae)
2, 307
32.52
<0.0001
2, 307
16.14
<0.0001
4, 307
1.94
0.1040
Lyctidae
2, 307
101.31
<0.0001
2, 307
17.82
<0.0001
4, 307
4.05
0.0032
Buprestidae
2, 307
23.72
<0.0001
2, 307
0.15
0.8619
4, 307
3.30
0.0114
Cerambycidae
2, 259
53.70
<0.0001
2, 259
46.94
<0.0001
4, 259
1.21
0.3078
Histeridae
2, 307
60.73
<0.0001
2, 307
19.55
<0.0001
4, 307
6.48
<0.0001
Cleridae
1, 153
2.73
0.1003
2, 153
9.11
0.0002
2, 153
1.44
0.2408
Hymenoptera
1, 153
16.73
<0.0001
2, 153
1.16
0.3150
2, 153
0.55
0.5762
Data analyses were performed through a generalized linear model with
a binomial distribution and a logit link function using a GLIMMIX
procedure in SAS.
Figure 2
Branch colonization frequency by secondary colonizers.
Non-engineered branches are represented by white bars (NE);
simulated-engineered branches by gray bars (SE); and O.
albomarginata chamela- engineered branches by black bars
(OE). Values are the percentage of branches colonized. Different letters
indicate significant differences (P<0.05) between the frequencies of
branch colonization of the treatments.
Branch colonization frequency by secondary colonizers.
Non-engineered branches are represented by white bars (NE);
simulated-engineered branches by gray bars (SE); and O.
albomarginata chamela- engineered branches by black bars
(OE). Values are the percentage of branches colonized. Different letters
indicate significant differences (P<0.05) between the frequencies of
branch colonization of the treatments.Data analyses were performed through a generalized linear model with
a binomial distribution and a logit link function using a GLIMMIX
procedure in SAS.
Effect of habitat engineering on the abundance of secondary
colonizers
There was a highly significant effect of treatment, year and the interaction
between treatment and year on the abundance of all groups of secondary
colonizers: life form I xylovores (F2,
319 = 366.04, P<0.0001; F2,
319 = 74.44, P<0.0001; F4,
475 = 6.17, P<0.0001); life form II xylovores
(F2, 475 = 31.34, P<0.0001; F2,
421 = 28.54, P<0.0001; F4,
475 = 3.21, P = 0.0129); and
natural enemies (F2, 465 = 127.51, P<0.0001;
F2, 406 = 30.23, P<0.0001; F4,
475 = 5.03, P = 0.0006). The
three groups of secondary colonizers showed the following pattern of abundance:
OE>SE>NE, where engineered vs. non-engineered branches
(OE and SE vs. NE) showed significant differences for the three
groups of secondary colonizers (Figure 3). However, the OE vs. SE comparison only
showed a significant difference for life form I xylovores in 2007 and 2008, for
life form II xylovores in 2008 and 2009, and for natural enemies for 2007 (Figure 3). The abundance of
all secondary colonizers in non-engineered branches (NE) was 95% (2007),
93% (2008) and 96% (2009) lower than the abundance of secondary
colonizers in O. albomarginata chamela-colonized branches (OE)
(Figure 3).
Figure 3
Abundance of secondary colonizers that emerged from Spondias
purpurea detached branches.
Bars indicate LSMeans (±SE) of the number of secondary colonizers
that emerged per S. purpurea branch in the three
studied years. White bars indicate non-engineered branches (NE); gray
bars indicate simulated-engineered branches (SE); and black bars
indicate O. albomarginata chamela-colonized branches
(OE). Different letters indicate significant differences between
treatments (P<0.05).
Abundance of secondary colonizers that emerged from Spondias
purpurea detached branches.
Bars indicate LSMeans (±SE) of the number of secondary colonizers
that emerged per S. purpurea branch in the three
studied years. White bars indicate non-engineered branches (NE); gray
bars indicate simulated-engineered branches (SE); and black bars
indicate O. albomarginata chamela-colonized branches
(OE). Different letters indicate significant differences between
treatments (P<0.05).
Effect of habitat engineering on the species richness of secondary
colonizers
There was a strong effect of treatment (F2,
478 = 367.7, P<0.0001), year (F2,
478 = 45.77, P<0.0001), habitat engineering (NE
vs. SE and NE vs. OE; Figure 4) and the presence of the ecosystem
engineer (OE vs. SE; Figure 4) on the species richness of
secondary colonizers that emerged from S. purpurea branches,
with no significant interaction between treatment and year (F4,
478 = 0.64, P = 0.6310). The
results showed the OE>SE>NE pattern of species richness, consistent across
years (Figure 4). NE
branches showed 85% (2007), 80% (2008), and 82% (2009)
fewer species than OE branches (Figure 4). Rarefaction curves showed that the observed differences
in cumulative species richness persisted even when samples were rarefied to
similar abundances of individuals (Figure 5).
Figure 4
Species richness of secondary colonizers that emerged from
Spondias purpurea branches.
LSMeans (±SE) of the number of species per S.
purpurea branch in the three studied years; white bars
indicate non-engineered branches (NE); gray bars indicate
simulated-engineered branches (SE); and black bars indicate O.
albomarginata chamela-engineered branches (OE). Different
letters indicate significant differences between treatments
(P<0.05).
Figure 5
Rarefaction curves plotting the number of species of secondary
colonizers vs. the number of individuals sampled in
detached Spondias purpurea branches.
NE = non-engineered branches; SE
= simulated-engineered branches; and OE
= O. albomarginata chamela-
engineered branches. Bars represent 95% confidence intervals
obtained from 10 000 re-sampling iterations. Bars that overlap the mean
for alternate treatments indicate that treatments were not significantly
different (P>0.05).
Species richness of secondary colonizers that emerged from
Spondias purpurea branches.
LSMeans (±SE) of the number of species per S.
purpurea branch in the three studied years; white bars
indicate non-engineered branches (NE); gray bars indicate
simulated-engineered branches (SE); and black bars indicate O.
albomarginata chamela-engineered branches (OE). Different
letters indicate significant differences between treatments
(P<0.05).
Rarefaction curves plotting the number of species of secondary
colonizers vs. the number of individuals sampled in
detached Spondias purpurea branches.
NE = non-engineered branches; SE
= simulated-engineered branches; and OE
= O. albomarginata chamela-
engineered branches. Bars represent 95% confidence intervals
obtained from 10 000 re-sampling iterations. Bars that overlap the mean
for alternate treatments indicate that treatments were not significantly
different (P>0.05).
Discussion
Several insect herbivores can create new habitats and alter habitat resource
availability for other organisms, by modifying the structural and/or nutritional
properties of plant tissues [4], [10], [14], [15]
.
O. albomarginata chamela actively manipulates its host plant by:
(i) girdling and detaching branches, and (ii) gnawing eggs niches and incisions into
the bark or stems [27]. These modifications were key factors for the
establishment and development of an arthropod community composed by xylovores
(Bostrichidae, Scolytinae, Buprestidae, Lyctidae and Cerambycidae) and natural
enemies (Histeridae, Cleridae and Hymenoptera).
Benefits of stem-boring engineering to secondary colonizers
The reported benefits of insect ecosystem engineering to secondary colonizers
include: shelter from harsh abiotic factors, avoidance of natural enemies, and
modification of resource quality [4], [10], [47]. However, the importance of
each benefit differs among insect guilds. For example: leaf rolls and leaf mines
are colonized for shelter rather than for the food they contain [11], [15], whereas
galls provide shelter, protection from natural enemies and high quality food
resources [10].The main benefits of the stem-boring engineering by O. albomarginata
chamela to secondary colonizers were related to the creation of a
habitat with high availability of oviposition sites, because branches without
incisions (non-engineered) were poorly colonized. Moreover,
artificially-engineered branches were colonized by a similar arthropod community
that colonized branches naturally detached by O. albomarginata
chamela. This confirms that incisions made by O.
albomarginata chamela adult females along the detached S.
purpurea branches are used by other arthropod species as
oviposition sites. Availability of oviposition sites offers three benefits to
secondary colonizers because they can: (i) save costs of searching for suitable
oviposition sites; (ii) diminish the “excavation costs” of the
initial stem penetration [10]; and (iii) reduce exophytic predation during the
oviposition period (sensu
[48]).Additionally, the presence of O. albomarginata chamela had a
significant impact on the abundance of xylovore species in some years
(31–50%), as well as on species richness of the arthropod community
in the removed S. purpurea branches (15%). The increase
of nutrient availability by deposition of faecal pellets is one of the potential
benefits of the ecosystem engineer to secondary colonizers [5], [10], [49]. O. albomarginata
chamela larvae digest cellulose [50], transforming complex
structural carbohydrates into simple sugars, which can be eliminated with faecal
pellets. Thus, it is possible that this insect supplies partially digested food
to secondary colonizers. However, future studies are needed to confirm this
hypothesis.
Effects of stem-boring engineering on arthropod community
Our study demonstrated that ecosystem engineering by O. albomarginata
chamela had strong positive effects on its associated arthropod
community. The abundance and species richness of xylovore insects were higher in
engineered branches than in non-engineered branches, possibly due to greater
quantity and quality of habitat and food resources provided by engineered
branches [51].
This is consistent with previous studies reporting that higher colonization and
performance, following the improvement of resource quality, increase the
abundance and species richness of insect herbivores [52]–[54]. Another
mechanism that promotes high species richness, is the increase of the abundance
of rare resources or combinations of resources that are required by specialist
species [51],
[54],
[55].
Five cerambycid species were restricted to engineered branches in the three
studied years (Table 1).
These species were among the larger xylovore colonizers (Life form II; Table 1). Larger insect
species produce larger eggs [44], indicating that they require larger egg-niches.
Species of the genus Oncideres gnaw large egg niches (4–5
mm in width) in which oviposit [17], whereas cerambycid species that do not have the
ability to gnaw egg niches, wander over the hosts probing the bark with the
ovipositor for cracks and crevices in which they oviposit [30]. Therefore, it is possible
that the size of egg niches gnawed by O. albomarginata chamela
females allow these species to oviposit in them. These findings suggest that the
increased species richness in engineered branches can be a consequence of the
greater abundance of specific egg niches required by specialist species.The increase in abundance and number of secondary xylovores, which represent
potential prey and hosts for natural enemies, in turn may influence the
abundance and species richness of natural enemies and result in bottom-up
effects [3],
[4]. In
this study, the overall abundance and species richness of natural enemies was
higher in engineered branches than in non-engineered branches. Specifically,
only one (Histeridae: Teretriosoma nigrescens) of the three
natural enemies was consistently recorded in non-engineered branches (Figure 2). T.
nigrescens preys upon some bostrichid beetles [56], which were the main
species that colonized non-engineered branches. However, there were five
cerambycid species that did not colonize non-engineered branches. Parasitic
wasps are reported as one of the main natural enemies of cerambycid beetles
[57]. Thus,
the absence of colonization of parasitic wasps in non-engineered branches could
be related to the reduced colonization by cerambycid beetles.Our results confirm the notion that changes in the composition of the xylovore
community cascade upward to higher trophic levels through bottom-up effects.
Implications of stem-boring ecosystem engineering for biodiversity
On average, ecosystem engineering by O. albomarginata chamela
was responsible for nearly 95% of the abundance of secondary colonizers
and 82% of the species richness. These results are consistent with the
positive effects on arthropod diversity reported for other insect ecosystem
engineers [11]–[13], [15]. However, ecosystem engineering by O.
albomarginata chamela had greater effects on species richness than
leaf-roller caterpillars (14–84%) [11], [12], gall-makers (32%)
[13], and
leaf-miners [15], possibly because ecosystem engineering by this
species allowed the establishment of an entire arthropod community, and
regulated the structure of this community. Therefore, based on Painés
“keystone” concept [58], ecosystem engineering by O. albomarginata
chamela can be considered a keystone process
(sensu
[7]).There are two explanations for this keystone process: the existence of a highly
structured community, and the degree of specialization (i.e. interaction
strength) between the secondary colonizers and the engineered habitat [58]. The
arthropod community associated with branches engineered by O.
albomarginata chamela is a highly structured community, because it
consists of organisms with different life history traits and trophic positions.
In addition, our study suggests that the xylovore community associated with
S. purpurea branches might be specialists in branches
girdled and detached by O. albomarginata chamela. Furthermore,
the known host plants for the Cerambycidae and Scolytinae species emerging from
S. purpurea branches completely correspond to the alternate
host plants of O. albomarginata chamela, and to the host plants
of other girdling-beetles in the study site, such as Oncideresrubra and Taricanus zaragozai
[32], [59]. Some of
these cerambycid species, as well as most species of Bostrichidae and
Buprestidae in the S. purpurea branches, also use branches
girdled by other beetle species in different tropical and subtropical regions
[17], [18], [20], [60].
Conclusions
The importance of interactions mediated by insects in shaping herbivore
communities is becoming widely recognized [4]. However most studies have
focused on herbivore-induced changes to plant chemical composition (reviewed in
[4]) and
only few to plant-structural modifications made by insect engineers (reviewed in
[10]).
This study provides evidence that interactions mediated by ecosystem engineering
may be a common factor enhancing species richness and structuring communities of
borer insects. Therefore, our findings have important implications for
conservation, because through the understanding of the mechanisms underlying
ecosystem engineering it is possible to develop effective strategies of
ecosystem management [61].
Authors: James E Byers; Kim Cuddington; Clive G Jones; Theresa S Talley; Alan Hastings; John G Lambrinos; Jeffrey A Crooks; William G Wilson Journal: Trends Ecol Evol Date: 2006-06-30 Impact factor: 17.712
Authors: Alan Hastings; James E Byers; Jeffrey A Crooks; Kim Cuddington; Clive G Jones; John G Lambrinos; Theresa S Talley; William G Wilson Journal: Ecol Lett Date: 2007-02 Impact factor: 9.492
Authors: Pedro Daleo; Eugenia Fanjul; Agustina Mendez Casariego; Brian R Silliman; Mark D Bertness; Oscar Iribarne Journal: Ecol Lett Date: 2007-10 Impact factor: 9.492
Authors: Luiz Eduardo Macedo-Reis; Samuel Matos Antunes de Novais; Graziela França Monteiro; Carlos Alberto Hector Flechtmann; Maurício Lopes de Faria; Frederico de Siqueira Neves Journal: J Insect Sci Date: 2016-06-07 Impact factor: 1.857
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