Journal of Threatened
Taxa | www.threatenedtaxa.org | 26 November 2023 | 15(11): 24201–24211
ISSN 0974-7907
(Online) | ISSN 0974-7893 (Print)
https://doi.org/10.11609/jott.8429.15.11.24201-24211
#8429 | Received 02 March 2023 | Final received 15 July 2023 | Finally
accepted 30 September 2023
Spatial,
temporal and trophic resource partitioning among the four
egret species (Aves: Pelecaniformes: Ardeidae) in a tropical wetland
ecosystem, India
Faiza Abbasi 1 & Mohd Shahnawaz Khan 2
1 Aligarh Muslim University,
Aligarh, Uttar Pradesh 202001, India.
2 WWF-India, 172-B Lodi Estate,
New Delhi 110003, India.
1 faeza.abbasi@gmail.com, 2 shahnawaz.khan.aligarh@gmail.com
(corresponding author)
Editor: T. Ganesh, Ashoka
Trust for Research in Ecology and the Environment (ATREE), Bengaluru, India. Date of publication: 26 November
2023 (online & print)
Citation: Abbasi, F. & M.S. Khan (2023). Spatial, temporal and
trophic resource partitioning among the four egret
species (Aves: Pelecaniformes: Ardeidae) in a tropical wetland ecosystem,
India. Journal of Threatened Taxa 15(11): 24201–24211. https://doi.org/10.11609/jott.8429.15.11.24201-24211
Copyright: © Abbasi & Khan 2023. Creative Commons Attribution 4.0 International
License. JoTT allows unrestricted use,
reproduction, and distribution of this article in any medium by providing
adequate credit to the author(s) and the source of publication.
Funding: None.
Competing interests: The authors declare no competing interests.
Author details: Faiza Abbasi is an ornithologist and holds the designation of asst. professor and director of the Human Resource Development Centre, UGC, Aligarh
Muslim University. She has also served as the faculty in the Department of
Wildlife Sciences, at Aligarh Muslim University,
Uttar Pradesh. She has also been leading many multi-disciplinary research and
training programmes. Mohd Shahnawaz Khan is an ecologist and works for the World-Wide Fund for Nature
(WWF-India) as the lead- Ganga Dolphin. He has a background in scientific research on birds, turtles, Gharials, and Ganges River Dolphins and
multi-stakeholder engagement in different parts of India.
Author contributions: FA conceived the study, collected data as a part of her PhD programme.
FA and MSK analyzed data and wrote the manuscript.
Acknowledgements: The present research was carried
out by the first author during her Ph.D. programme at the Department of
Wildlife Sciences, Aligarh Muslim University, India. Thanks are due to
professor H.S.A. Yahya, Former Chairman, Department of Widlife Sciences,
Aligarh Muslim University, for his kind supervision.
Abstract: The diversity of micro-habitats
in tropical wetlands allows the coexistence of several species. These sympatric
species interact with each other, either directly or indirectly, to optimally
use the available resources. They achieve this through niche separation or
minimal overlap to avoid competition. India’s wetland ecosystems are home to
various sympatric species, such as the Great Egret Ardea alba (GE),
Median Egret Ardea intermedia (IE), Little Egret Egretta garzetta
(LE) and Cattle Egret Bubulcus ibis (CE). These egret species are
closely related, and as a result, have similar niche requirements, which could
lead to high intra-specific competition. However, there have been few studies
on how these species utilize resources. This study aims to understand the
possible mechanisms that enable the coexistence of these species in a tropical
wetland. We have examined habitat characteristics, feeding behaviour, timings
of seasonal and daily activities, and spacing patterns to evaluate possible
models of species coexistence. We discovered that these four sympatric egret
species have differences in microhabitat selection, activity patterns, both
daily and seasonally, and feeding preferences. The study further indicates that
there is a relationship between the niche dimensions, but it is only partially
dependent on each other.
Keywords: Co-existence of sympatric
species, competition, interspecific interaction, niche separation.
INTRODUCTION
Tropical wetland ecosystems are
important habitats for migratory birds and also support the avian diversity of
native species (Junk 2006). The great diversity of micro-habitats allows the
coexistence of the species in the wetland (Junk 2006). The species’
coexistence is generally perceived as a consequence of the interspecific
interactions among the sympatric species (Siepielski 2021). The sympatric
species may or may not have direct interaction but the chances of interspecific
interactions in terms of competition for resource utilization (in spatial,
temporal and trophic dimensions) increase in the case of closely related
species (Ye et al. 2021). The Lotka-Volterra approach suggested that the
stable coexistence of competitive species is only possible when intraspecific
competition is stronger than interspecific competition (MacArthur 1967; Gavina
et al. 2018). Further, the behaviour of the species such as pattern of habitat
use, daily activity, foraging and interspecific behaviours also govern the
social spacing and tolerance, to allow biologically similar sympatric species
to coexist (Perri & Randall 1999; Oviedo et al. 2018).
Great Egret Ardea alba (GE),
Median Egret Ardea intermedia (IE), Little Egret Egretta garzetta
(LE), and Cattle Egret Bubulcus ibis (CE) are ubiquitous in the wetland
ecosystems across India. As generalist top predators, the egrets exert a
top-down influence on the structure of lower trophic levels, altering the
abundance and distribution of multiple prey species and, in turn, the effects
of their prey on other species (Huang et al. 2015). Studies focusing on their
habitat and behaviour ecology are critical in understanding their ecological
requirements and their role as top predators in sustaining the richness of life
in wetland ecosystems (Jennings 2017).
Despite the separate studies on
feeding ecology, habitat selection and seasonal or daily behaviour of the
species, a comprehensive understanding of niche partitioning that integrates
the temporal, spatial and trophic dimensions of sympatric egret species is
still lacking (Ye et al. 2021). Hence, the possible mechanism permitting the coexistence
of GE, ME, LE, and CE in a tropical wetland has been studied.
Habitat characteristics, feeding
behaviour, timings of seasonal and daily activities and spacing patterns have
been examined to evaluate possible models of species coexistence. The research
has been carried out to understand the partitioning of niche dimensions based
on niche theory and inter-specific effects as the primary mechanism to
structure the communities (Hairston et al. 1960; Schoener 1982; Kelt et al.
1985; Bardsley & Beebee 1998; Beckerman 2000). It appears that the four
sympatric egret species in the study area are using the resources available to
them in the tropical wetland habitat. However, due to variations in their
microhabitat selection, daily and seasonal activity patterns, and feeding
preferences, it is hypothesized that there exists some form of niche separation
over the spatial, temporal and trophic scales amongst them.
Materials
and Methods
Study Area
Sheikha lake is situated in the
Gangetic Plains (Rodgers & Panwar 1988) between 78.204°–78.234° N &
27.870°–27.839° E at about 17 km from Aligarh district (Uttar Pradesh, India)
and it is a perennial lake spread over 2.50 km2 (Image 1). The
region experiences extreme temperature conditions with a maximum of 47°C during
summers and 0°C during winters. Average annual rainfall ranges from 650–750 mm.
The lake is home to a large number of waterfowl both migratory and resident.
The site has also been designated as IBA (Important Bird Area) as it provides a
good habitat for the birds (Islam & Rahmani 2004).
The Upper Ganga Canal (UGC)
divides the area into two blocks i.e. ‘A’ and ‘B’. The main lake is in Block A
on the western side of the canal. Block B becomes patchy in the dry season and
segregates into several small pools. The permanent waterbody and seasonal
expansion of the water lodging in surrounding areas, diverse weather
conditions, shelter belt trees and agriculture field around the lake and the
canal going through the wetland favour a broad spectrum of living conditions
for diverse life forms. The major tree species on the periphery of the lake are
Terminalia arjuna, Syzygium cumini, Acacia leucocephala,
Acacia nilotica, Holoptelia integrifolia, Ficus religiosa, Dalbergia sissoo,
Azadirachta indica and Prosopis juliflora (Saxena 1999). These trees
provide good roosting and heronry sites for the egrets.
The lake is surrounded by
agricultural fields and livestock grazing is also common in the area. A small
amount of fishing, fuel wood, fodder extraction and utilization of the Block B
pools for the cultivation of water chestnut Trapa bispinosa by the local
communities, are a few minor anthropogenic disturbances in the area.
Methods
Data Collection
The study was conducted between
August 2000 and March 2004 in Sheikha Lake (Image 1). Field data collection was
conducted three days a week in all study years, which amounts to 140 to 160
days. Therefore, in each season namely spring, summer, monsoon and winter, 45
to 50 days were spent in the field studying the egrets. Observation shifts of
four hours each for focal animal sampling in the morning, noon and afternoon
were done once a week in all seasons.
To cover all possible habitat types
used by the egrets, the trails were identified and monitored on a bi-weekly
basis. Seasonal data on the population, spatial distribution, activity
budgeting and feeding preferences of the four sympatric species of egrets were
collected through repeated sampling during the study period. Data on foraging
and feeding was recorded during the observations of the egrets. Ocular
estimation for prey type identification was done during the feeding attempt,
and prey size was estimated using the bill length method following Bayer
(1985). Established bill lengths were taken from Grimmett et al. (1998).
Spatial dimension of niche
The population of egrets were
estimated using the point count method on the selected trails on a seasonal
basis. Each count took place three days a week in all study years. The birds
flying overhead were not recorded as per the standard point count method (Bibby
et al. 1992). The seven micro-habitats were identified as open water, paddy
field, grassland, lake shore, reed bed, canal bank, and ploughed field. The
habitat characteristics, disturbance factors, and distance from the closest
human habitation were also recorded.
Temporal dimension of niche
Focal animal observations on
activity budgets of egrets in non-roosting hours during the off-breeding
seasons of the year were taken (Altman 1973). Seven major types of activities
such as Preening (PR), Siesta (seizure of all activities during the daytime)
(ST), Resting (intermittent rests during foraging) (RS), Foraging (FR), Chasing
(CH), Display (DS) and Miscellaneous (The short duration activities such as
defecating, scratching the body with feet, tilting the neck and fluttering
their wings) (MS) were recorded.
Observations were made in three
shifts of four hours a day. The morning shift ranged between 0600 h and 1000 h,
the noon shift from 1000 h to 1400 h and the evening shift from 1400 h to 1800
h (Lehner 1979; Yahya 1980; Maheswaran 1998). All observations of activity
patterns were recorded at the lake rather than the nest or roosting sites.
Trophic dimension of niche
The foraging behaviour of the egrets
was identified as walking slowly, standing, foot stirring, chasing prey,
probing & pecking, walking quickly, hopping, and gleaning following Hancock
& Kushlan (1984). These occurrences and time allocation for these
behaviours were recorded during the species-wise focal animal sampling of
general activity budgeting. Following Recher & Recher (1969), Seigfried
(1971), Krebs (1974), Willard (1977), Kushlan (1978), Caldwell (1979), Quinney
& Smith (1980), Hom (1983), Mock et al. (1987) and Forbes (1989),
the prey type and its size was also recorded during the sampling. Each species
was given equal observation time in a particular shift to avoid bias. The total
observation time devoted to all species was 1622 hours in the entire study
period.
Data Analysis
Spatial dimension of niche
The relative abundance of each of
the four species of egrets in different habitats was compared using the
Student’s t-test (independent sample). Chi-square contingency analysis was
performed to test the significance of associations between a species of egret
and the micro-habitat type and different habitat parameters (Seigel 1956;
Fowler & Cohen 1986) using SPSS ver. 7.3 (Norusis 1994). The niche
relationships were analysed using the programme NICHE (Krebs 1989). Estimation
of the micro-habitat niche breadth for all four species was performed by using
the Shannon-Weiner Measure (Colwell & Fuentes 1975; Krebs 1989).
Temporal dimension of niche
The difference in the time
allocation for different activities by the sympatric egret species was assessed
using the One-way ANOVA with Post hoc Tukey Test following Fowler & Cohen
(1986). The seasonal and diurnal variations in the activity patterns of each
sympatric egret species were also analysed using One-way ANOVA with Post hoc
Tukey Test, in SPSS ver. 7.3 (Norusis
1994).
Trophic dimension of niche
A comparison was made of the
frequency with which each species used a foraging behaviour, food item and prey
size with χ2 for ‘k’ independent samples. Chi-square contingency
analysis was performed to test the significance of associations between a
species and a behaviour, prey item and prey size following Seigel (1956) and
Fowler & Cohen (1986).
Food item and prey size in the
categories of food and foraging behaviour in the categories of behaviour were
considered as one resource type each and resource matrices for all species were
structured following Pianka (1986). Levins’ (1968) diversity index was used to
estimate the extent of behaviour and resource use.
Results
Spatial dimension of niche
The relative abundance measure
indicated the population of the CE was highest (265.6 ± 54.5) followed by ME
(114.6 ± 20.9), GE (12.6 ± 6.7) and LE (4.51 ± 3.5). Chi-square contingency
analysis of the frequency with which each species used the micro-habitat types
revealed that significant associations exist between the species and the
micro-habitat types (Table 1). The CE used a variety of habitat types both
aquatic and terrestrial and dry grassland amongst terrestrial habitat types
while amongst the aquatic types, it preferred reed beds with low height
vegetation growth and irrigated paddy fields (χ2 = 213.6, P
<0.05, df = 288). The LE mostly remained in open sheets of water within the
lake and at the shore (χ2 = 232.7, P <0.05, df = 288). Amongst
its less preferred ventures into the terrestrial area, it remained in short
grasslands. The ME, however, (χ2 = 256.8, P <0.05, df = 288)
showed a high preference for reed beds (χ2 =139.1, P <0.05, df =
288) and made equal use of paddy fields, lake shore and marshes. The GE (χ2
= 297.3, P <0.05, df = 288) seemed to be specializing in open water
feeding making use of the clear sheet of water within the lake and other pools.
The utilization pattern of resources
within these micro-habitat types by the sympatric species of egrets was also
found to be different (Table 2). The CE preferred to remain in shallow reaches
(χ2 = 234.2, P <0.05, df = 288) when feeding in water and treaded
over vegetation, while the LE (χ2 = 477.8, P <0.05, df = 288) and
the ME (χ2 = 285.4, P<0.05, df = 288) mostly stayed in water up
to 30 cm deep. Owing to its longer legs, the GE (χ2 = 274.3,
P<0.05, df = 288) was the only species of the four, that ventured up to 70
cm.
The aquatic vegetation cover was
also differentially used by the four species for foraging. The CE (χ2 =
184.5, P <0.05, df = 288) and the ME (χ2 = 109.6, P <0.05, df
= 288) fed in highly vegetated areas, whereas the LE (χ2 =119.2, P
<0.05, df = 288) and the GE (χ2 = 122.4, P <0.05, df = 288)
fed in scantily vegetated areas. Out of the several categories of available
water stretch in the wetland, there was a differential association of the four
species with various categories. The CE (χ2 = 248.6, P <0.05, df=
288) frequented the wetland with less than 50% open water while the LE (χ2
= 194.7, P <0.05, df = 288) preferred the wetland with only 25% open
water. The ME (χ2 = 233.1, P <0.05, df = 288) frequented the lake
when open water was up to 75% and the GE (χ2 = 242.9, P <0.05, df
= 288) fed in the lake when the open water was more than 50% and even while the
lake was overflowing due to heavy rains.
The CE (χ2 = 274.3, P
<0.05, df = 288) frequented ground vegetation cover only where it was more
than 30%, whereas the LE (χ2 = 146.2, P <0.05, df = 288)
frequented areas with less than 30% ground vegetation. The ME did not exhibit a
significant association with the ground cover but the GE (χ2 =
203.5, P <0.05, df = 288) showed a significant preference for ground
vegetation cover of up to 60%. Significant associations were also found between
the species and their distance to the lake. While the CE (χ2 =
266.4, P <0.05, df = 288) was mostly found feeding away from the lake. The
LE (χ2 =313.5, P <0.05, df = 288) maintained strict proximity to
the lake area. The ME (χ2 = 186.7, P <0.05, df = 288) did venture
away from the lake but remained within a distance of one kilometre. The GE (χ2
= 302.8, P <0.05, df = 288) was found to feed only in the close
vicinity of the lake and its adjoining pools and never beyond one kilometre
distance.
Analysis of the niche breadth (Table
1) shows that the CE and the ME use a wide spectrum of
habitat types hence they have a larger niche breadth. While the GE has a lesser diversity of habitat types used and a
smaller niche breadth followed by the LE.
The degree of habitat niche overlap
between the four sympatric species of egrets (Table 2) indicates that the
maximum overlap exists between the LE and the GE. The CE has
very little overlap with any of the species for all habitat parameters, in
fact, no overlap exists between the CE and the other three species in the case
of vegetation cover. The ME shows moderate habitat
overlap with LE and GE. However, niche overlap inference cannot be made with
regard to tree height and canopy cover, because the Chi-square contingency
analysis used to derive Morisita’s Index of niche overlap revealed that there
was no significant correlation between the species and these habitat
parameters.
Temporal dimension of niche
All species of egrets were found to
be variably utilizing the diurnal period throughout different seasons (Figure
1). In general, a significantly high proportion of their time was spent on
foraging activity followed by preening and resting (Figure 1). Since the
display behaviour was only recorded during the summers, therefore, its seasonal
comparison was not possible.
The post hoc analysis of diurnal
activity pattern suggested that preening time differs between all species
except between LE and GE. Only CE & ME and LE
& ME differ in foraging activity. Resting time differs between CE-ME, CE-LE
and CE-GE while siesta and time devoted to miscellaneous activities differ
amongst all species. Differences were also found between the display and
chasing activity of CE-LE, LE-ME and ME-GE (Figure 2).
The post hoc analysis of significant
seasonal variability in the activity pattern showed that during winters all
species except LE-GE differ in the preening activity. The ME
and CE, LE and GE differ in their foraging time. For the resting
activity CE-LE, CE-GE and LE-ME differed significantly
while for the rest of the activities in the time budget, only ME-GE showed a
significant difference regarding the siesta activity (Figure 2). In the summer
season, the preening activity pattern was different between all pairs of
species except LE-GE. The time spent on foraging was also different between all
pairs of species except CE-GE and ME-GE. Resting and
miscellaneous activity patterns were different in all species pairs except
LE-GE. The CE-LE, CE-ME and ME-GE differed
significantly in their display behaviour whereas CE-ME, CE-LE and CE-GE adopted
differential time budgets for chasing (Figure 2).
In monsoon, all pairs of species
except the CE-LE and CE-GE were different in preening activity pattern. Time
spent on foraging was significantly different between all pairs of species
except CE-LE. In time allocation to the resting, siesta and miscellaneous types
of activities, half of the pairs of species differed significantly (CE-GE,
ME-LE and LE-GE) and the remaining half performed without any significant
differences (CE-LE, CE-ME and ME-GE). The chasing time
was found significantly different between the pair CE-LE, CE-ME
and CE-GE (Figure 2).
Trophic dimension of niche
The Chi-square contingency analysis
of the frequency suggested that associations between the species and the
behaviour types are highly significant. CE used a variety of feeding behaviours
such as walking slowly, standing and walking quickly most often (χ2 =32.7,
P <0.05, df = 21) and LE used walking quickly and foot stirring most often
(χ2 =33.4, P <0.05, df = 21). The behaviour of foot stirring was
unique to the LE. The ME used walking slowly most often but gleaning, probing
and pecking and standing were also used with an equal thrust (χ2=37.9,
P <0.05, df = 21). The GE almost specialized in using the walking
slowly and standing behaviour (χ2 =34.3, P <0.05, df = 21) with
minuscule use of probing and pecking and chasing.
A total of 7,826 observations on the
foraging behaviour of the different egret species were possible during the
study period (Figure 3). The chi-square suggested a significant association between
species and preferred prey items. CE preyed mostly upon terrestrial insects and
small vertebrates such as amphibians, molluscs and crustaceans (χ2 =
44.5, P <0.05, df = 30), the LE was most significantly associated with small
fish but also include crustaceans, amphibians and aquatic insects (χ2
=48.9, P <0.05, df = 30) in its diet, the ME most often fed upon small fish
but larger fish and aquatic insects too formed a considerable portion of the
diet (χ2 = 46.2, P <0.05, df = 30), whereas the GE almost exclusively
fed upon large sized (more than 8 cm) fish (χ2 = 43.8, P <0.05,
df = 30). The rest of the dietary items were also consumed by the GE but in
smaller quantities (Figure 4).
A clear preference of prey size has
been indicated by the egret species (Figure 5). CE subsisted on smaller prey of
less than 6 cm (χ2 =22.8, P <0.05, df = 12), prey eaten by LE
ranged from 2 cm to 8 cm (χ2 =27.1, P <0.05, df = 12); similarly,
the ME too preyed upon intermediate size fish and crustaceans less than 8 cm in
size (χ2 =25.2, P <0.05, df = 12) but the GE maximized on fish
larger than 8 cm (χ2 =24.7, P <0.05, df = 12) (Figure 5).
However, since they fed on small fish as well, some of their prey was less than
6 cm.
The measurement of niche breadth
(Table 3) indicates that CE and ME use almost the same
diversity of foraging behaviours and the LE and GE use a very small variety of
behaviours – practically only walking quickly and foot stirring, and walking
slowly and standing. The CE and LE showed equal
diversity in the choice of food items and the ME and GE showed a lower
diversity than the former two. Regarding prey size, the LE showed a very high
diversity followed by the ME, and the GE and CE
exhibited a comparatively lower diversity.
Analysis of resource overlap amongst
the four sympatric egrets (Table 4) reveals high overlap between CE and GE regarding behaviour, moderate overlap with prey
type but very little overlap in prey size. GE and ME
showed a high overlap in foraging behaviour and considerable overlap in prey size and
prey type. ME and LE exhibited almost total overlap in prey type but little
overlap in foraging behaviour. GE and LE coexist with very little overlap in
foraging behaviour and considerable overlap in prey type and prey size. LE and
CE have a high overlap in prey type and prey size and a moderate overlap in
foraging behaviour. CE and ME have high degrees of overlap in all categories.
Discussion
The study demonstrated
significant differences in habitat use, diurnal time utilization and feeding
habits among the four species of egrets at Sheikha lake. Thus, they segregated
in the use of the temporal, spatial and trophic niche dimensions, resulting in
reduced interspecific competition.
Given the lack of interspecific
territoriality and aggression, this suite of ardeid assemblage exhibits a
pattern of spatial segregation that relies on slight differences in
micro-habitat utilization with a varying overlap in various spatial niche
dimensions (Table 1 & 2). A positive correlation has been found between
Shannon-Weiner’s niche breadth of the egret species and their local abundances
(Table 1). CE and ME were using both the terrestrial as well as water-based
micro-habitats hence their niche breadths are wider so do their population
abundance. Whereas the GE and LE are more wetland-oriented species therefore
narrower niche breadth and lower local abundance. These results are in line
with the ecological phenomenon proposed by Hanski (1982) that the species
occupying most sites (i.e., wider habitat-based niche) also have higher local
abundances within those sites and vice versa.
The egret species were found to
be variably utilizing the daytime throughout different seasons and shifts of
the day (Figure 1). In general, a significantly high proportion of their time
was spent on foraging activity followed by preening and resting (Figure 1). The
results are the first example of diurnal temporal partitioning in the four
major egret species of tropical wetlands. Such partitioning is likely to be
driven by a combination of physiological and morphological constraints of each
species and behavioural mechanisms, including a species’ potential for
behavioural plasticity (Lear et al. 2021). Due to varied body sizes there use
to be a hierarchy in the Egret species in which the bigger body sizes have the
advantage to get the most suitable place for hunting. Hence the egrets make
opportunistic adjustments in their activity patterns in response to the
sympatric species exploiting the same habitat. Perhaps to avoid interspecific
conflict the egrets use temporal niche partitioning as a mechanism for
co-existence in the overlapped portion of microhabitats (Ye et al. 2019), which
could also maximize their fitness (Sanz-Aguilar et al. 2015).
The Egrets are visual predators
that use the sit-and-wait technique (Kushlan & Hancock 2005). They are
predominantly small fish and insect eaters. The dependency on the smaller prey
is reasonable as they are usually r-selected species and suffice the energy
requirements of the species (Britto & Bugoni 2015). Furthermore, during breeding, the egrets may
select insects to deliver to chicks because they are unable to swallow large
fish and other prey (Martinez-Vilalta & Motis 1992). They are therefore
called a biocontrol agent for insects, especially the CE as more than 60% of
CE’s diet comprise items less than size of 4cm (Seedikkoya et al. 2007). The
size of consumed prey varies among the species and it is in accordance with
their own body sizes, i.e., bigger egrets feed on big-size prey. 69.3% diet of
CE (smallest of the studied egrets) comprised of prey size 2–4 cm. Similar to
this, prey between the sizes of 2 and 8 cm made up 86.4% and 87.5% of the diets
of LE and ME, respectively. Whereas the GE (largest of the studied egrets) fed
on 83% of prey species that were between 8–10cm and above.
The study indicates that there is
a relationship between the niche dimensions, but it is only partially dependent
on each other. Little overlap existed in food selected by the four species but very different foraging behaviours are adopted.
Considering the interplay of habitat selection and the feeding technique
adopted, the nature of foraging niche differentiation is multi-faceted and may
vary from region to region.
Our results are
in agreement with the niche partition hypothesis, whereby
morphologically, ecologically and closely related sympatric species segregate
in at least one of the niche dimensions to allow coexistence (Ye et al.
2021).
Table 1. The percentage utilization of nine
microhabitats by the four sympatric species of egrets and their micro-habitat
niche breadth.
|
|
Habitat Type |
*Proportion of individuals
(Relative abundance) |
|||
|
CE |
LE |
ME |
GE |
||
|
1 |
Marsh |
6 |
14 |
9 |
10 |
|
2 |
Ploughed field |
27 |
4 |
8 |
0 |
|
3 |
Pool |
0 |
6 |
0 |
23 |
|
4 |
Open water |
0 |
31 |
11 |
42 |
|
5 |
Paddy field |
7 |
13 |
12 |
7 |
|
6 |
Dry grassland |
34 |
7 |
12 |
0 |
|
7 |
Lakeshore |
0 |
22 |
8 |
18 |
|
8 |
Reed bed |
21 |
0 |
36 |
0 |
|
9 |
Canal bank |
5 |
3 |
4 |
0 |
|
Shannon-Weiner’s niche breadth
index H’ |
325.05 |
301.96 |
313.29 |
305.48 |
|
Table 2. Habitat niche overlap (Morisita’s
measure of niche overlap) amongst the four sympatric species of egrets.
|
Species pairs |
C (Morisita’s measure of niche
overlap) |
|||||||
|
Overall Habitat niche overlap |
Aquatic habitat |
Terrestrial habitat |
||||||
|
Water depth |
Water stretches |
Vegetation cover |
Tree height |
Canopy cover |
Ground cover |
Distance from lake |
||
|
CE-LE |
0.030 |
0.108 |
0.170 |
0.000 |
0.214 |
0.422 |
0.240 |
0.085 |
|
CE-ME |
0.016 |
0.675 |
0.682 |
0.000 |
0.237 |
0.464 |
0.425 |
0.115 |
|
CE-GE |
0.011 |
0.054 |
0.076 |
0.000 |
0.319 |
0.568 |
0.384 |
0.100 |
|
ME-LE |
0.062 |
0.411 |
0.129 |
0.235 |
0.280 |
0.411 |
0.506 |
0.794 |
|
ME-GE |
0.024 |
0.260 |
0.057 |
0.212 |
0.422 |
0.556 |
0.634 |
0.864 |
|
LE-GE |
0.045 |
0.274 |
0.028 |
0.979 |
0.363 |
0.492 |
0.957 |
0.948 |
For figures
- - click here for full PDF
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