Biodiversity Data Journal 11: e104316 CO)
doi: 10.3897/BDJ.11.e104316 open access
Taxonomy & Inventories

New record and dietary ecology of a poorly known
frog, Amolops shihaitaoi Wang, Li, Du, Hou & Yu,
2022 (Amphibia, Anura, Ranidae), from Ha Giang
Province, Vietnam

Sonephet Siliyavong?, Ngoc Van Hoang§, Tao Thien Nguyen!, Truong Nguyen™*, Anh Van Pham™“

+ Pakse Teacher Training College, 13 South Road, Champasak, Laos

§ Thai Nguyen University of Education, Thai Nguyen University, Thai Nguyen, Vietnam

| Institute of Genome Research, Vietnam Academy of Science and Technology, Hanoi, Vietnam

¥ Institute of Ecology and Biological Resources, Vietnam Academy of Science and Technology, Hanoi, Vietnam

# Graduate University of Science and Technology, VAST, Hanoi, Vietnam

= Faculty of Environmental Sciences, University of Science, Vietnam National University, Ha Noi,

334 Nguyen Trai Road, Hanoi, Vietnam

« The Center for Biodiversity & Environment Research, Tay Bac University, Son La City, Son La Province, Son La, Vietnam

Corresponding author: Ngoc Van Hoang (ngochv@tnue.edu.vn), Anh Van Pham (phamanh@hus.edu.vn)
Academic editor: Bin Wang
Received: 30 Mar 2023 | Accepted: 05 May 2023 | Published: 11 May 2023

Citation: Siliyavong S, Hoang NV, Nguyen TT, Nguyen T, Pham AV (2023) New record and dietary ecology of a
poorly known frog, Amolops shihaitaoi Wang, Li, Du, Hou & Yu, 2022 (Amphibia, Anura, Ranidae), from Ha
Giang Province, Vietnam. Biodiversity Data Journal 11: e104316. https://doi.org/10.3897/BDJ.11.e104316

Abstract
Background

The Hekou Torrent Frog (Amolops shihaitao/) was recently discovered from southern China
and northern Vietnam in 2022. The knowledge about natural history and feeding ecology of
this species is virtually lacking.

© Siliyavong S et al. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC
BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are
credited.

2 Siliyavong S et al

New information

Based on our recent fieldwork in northern Vietnam, we report a new population of A.
shihaitaoi from Ha Giang Province. In this study, we provide novel data on the diet of A.
shihaitaoi, based on stomach content analyses of 36 individuals (17 males and 19
females). A total of 36 prey categories with 529 items, comprising 515 items of
invertebrates and 14 unidentified items, were found in the stomachs of A. shihaitaoi. The
dominant prey items of the species were Hymenoptera (Formicidae), Orthoptera
(Acrididae), Lepidoptera (Lepidoptera other), Mantodea (Mantidae) and Araneae. The
importance index (Ix) of prey categories ranged from 7.1% to 11.5%. Hymenoptera
(Formicidae) had the highest frequency of prey items, found in 36 stomachs.

Keywords

distribution, new records, morphology, prey items, stomach contents

Introduction

Studying dietary ecology is crucial for understanding natural history, population fluctuations
and the impact of habitat change on frog populations (Ogoanah and Uchedike 2011).
Identifying prey taxa for each species will help clarify the impact of frogs on local
invertebrate fauna and determine which prey species are dietary resources for the frogs
(Nakamura and Tominaga 2021). Some species have highly varied diets, but concentrate
their consumption on a few prey categories (Siqueira et al. 2006, Lima et al. 2010, Pham et
al. 2019), while others have a narrow or specialized diet on certain prey categories (Rddel
and Braun 1999, Hirai and Matsui 2000, Solé et al. 2002, Pham et al. 2022). In addition,
the diet of amphibian species depends on prey availability in the environment (Toft 1980,
Donnelly 1991).

Diet differences between sexes may occur due to differences in energy expenditure and
behaviour (Donnelly 1991, Valderrama-Vernaza et al. 2009) or in response to seasonal
variations in prey availability (Maneyro et al. 2004). However, both males and females are
usually capable of consuming prey of different sizes, so dietary differences between sexes
generally occur in the number of prey consumed (Donnelly 1991, Valderrama-Vernaza et
al. 2009) or in dietary composition (Brasileiro et al. 2010).

The genus Amolops Cope, 1865 currently contains 74 predominantly diurnal species that
inhabit forest streams (Patel et al. 2021, Frost 2023). Despite a large number of species,
dietary studies in the genus have only been done on Amolops larutensis (Berry 2009). In
Vietnam, studies on the diet have also been conducted on several amphibian species,
including Quasipaa verrucospinosa in Thua Thien Hue Province (Ngo et al. 2014) and
Microhyla butleri, M. heymonsi and Odorrana chapaensis in Son La Province (Pham et al.
2019, Pham et al. 2022). Those studies demonstrated that these frogs have varied diets,
with the majority being ants, beetles, dipterans and insect larvae.

New record and dietary ecology of a poorly known frog, Amolops shihaitaoi ... 3

The Hekou Torrent Frog (Amolops shihaitao/) was originally described from southern China
(Yunnan and Guangxi Provinces) and northern Vietnam (Vinh Phuc, Cao Bang and Lao
Cai Provinces) by Wang et al. (2022). In this study, we report the first record of Amolops
shihaiaoi from Ha Giang Province and provide the novel data on dietary ecology.

Materials and methods

A field survey was conducted in Lung Vai Village, Phuong Do Commune, within Tay Con
Linh Nature Reserve, Ha Giang Province, northern Vietnam (Fig. 1) by Ngoc Van Hoang
and Sonphet Silyavong in August 2022. Frogs were collected by hand between 8:00 and
23:00 hrs following the guidelines approved by the American Society of Ichthyologists and
Herpetologists for animal care (Beaupre et al. 2004). We used a stomach-flushing
technique to obtain stomach contents without sacrificing them (Griffiths 1986, Leclerc and
Courtois 1993, Sole et al. 2005). Prey items were preserved in 70% ethanol. Frogs were
subsequently released at the collecting site after taking measurements of snout-vent length
(SVL) and mouth width (MVV) with a digital caliper to the nearest 0.01 mm.

110°0'0"E 115°0'0"E
ia = :

20°0'0"N

15°0'0"N

10°0'0"N

105°0'0"E 110°0'0"E 115°0'0"E

Figure 1. | doi |

Map showing the survey sites in Ha Giang Province, northern Vietnam.

4 Siliyavong S et al

For taxonomic identification, four individuals were collected for voucher specimens. After
being photographed in life, these animals were anaesthetized and euthanized in a closed
vessel with a piece of cotton wool containing ethyl acetate (Simmons 2002), fixed in 85%
ethanol and subsequently stored in 70% ethanol. Specimens were subsequently deposited
in the collection of the Thai Nguyen University of Education (TNUE), Thai Nguyen
Province, Vietnam.

Morphological characters

All measurements were taken with a caliper to the nearest 0.1 mm following Wang et al.
(2022) and abbreviations are as follows: SVL: snout-vent length; HL: head length, from tip
of snout to rear of jaws; HW: maximum head width, at the angle of jaws; SL: distance from
anterior corner of eye to tip of snout; ED: eye diameter, from anterior corner to posterior
corner of eye; DNE: distance from anterior corner of eye to posterior edge of nostril; IND:
internarial distance; |OD: minimum distance between upper eyelids; UEW: maximum width
of upper eyelid; TD: maximum tympanum diameter; FHL: forearm and hand length,from
elbow to tip of third finger; TL: tibia length, from knee to heel; FL: foot length, from proximal
end of inner metatarsal tubercle to tip of fourth toe; and TFL: length of foot and tarsus, from
tibiotarsal joint to tip of fourth toe.

Stomach content analysis

Prey items were identified using a microscope (Olympus SZ 700) and taxonomic
identification keys (i.e. Naumann et al. (1991), Thai (2003), Johnson and Triplehorn (2005),
Brusca et al. (2016)). The maximum length (L) and width (W) of each prey item were
measured to the nearest 0.1 mm using either a caliper or a calibrated ocular micrometer
fitted to a microscope. The volume (V) of prey item was calculated using the formula for a
prolate spheroid (1 = 3.14, Magnusson et al. (2003)): V=(41r/3)x(L/2)x(W/2)? (mm?). The
index of relative importance (IRI) was used to determine the importance of each food
category. This index provides a more informed estimation of prey item consumption than
any of the three components alone, using the following formula: IRI = (%F + %N + %V)/3 (
Caldart et al. 2012), where F is the frequency of prey occurrence in stomachs and N is the
total number of prey items concerning all prey items. We used the reciprocal Simpson’s
heterogeneity index 1/D to calculate dietary heterogeneity: D = —}[ni(ni—1)]/([N(N—1)]),
where ni is the number of prey items in the i" taxon category and N is the total number of
prey items (Krebs 1999).

To estimate prey evenness, we used Shannon’s Index of Evenness. Evenness is
calculated from the equation: J' = H’/Hmax = H‘/InS. Hmax is the maximum diversity that
could occur if all taxa had equal abundance. H’ = Hmax = In§S, S is the total number of prey
taxa and H' is the Shannon-Weiner index of taxon diversity, calculated from the equation:
H' = —) (PixInPi), where Pi is the proportion of total prey items belonging to the taxon for
the total prey items of the sample (Magurran 2004, Munoz-Pedreros and Merino 2014).

New record and dietary ecology of a poorly known frog, Amolops shihaitaoi ... 5

Statistic analyses were performed using SPSS 20.0 software (SPSS Inc. Chicago, Illinois,
USA), with the significance level set to P < 0.05 for all analyses. Data are presented as
mean + standard deviation (SD) unless otherwise noted. We used Kendall’s tau b statistics
to examine the number of prey items and prey volume from frogs of different sexes. We
used one-way analysis of variance (ANOVA) to examine the size of prey items collected
between sexes.

Data resources

For taxonomic identification, four individuals were collected as morphological analysis. In
addition, a total of 40 adult individuals (20 males and 20 females) of A. shihaitaoi were
collected from Ha Giang Province for stomach flushing.

Taxon treatment
Amolops shihaitaoi Wang, Li, Du, Hou & Yu, 2022

. https://amphibiansoftheworld.amnh.org/Amphibia/Anura/Ranidae/Amolops/Amolops-
shihaitaoi

Materials

a. scientificName: Amolops shihaitaor; scientificName!D: Amolops shihaitaoi; class:
Amphibia; order: Anura; family: Ranidae; genus: Amolops; specificEpithet: shihaitaoy,
scientificNameAuthorship: Wang, Li, Du, Hou & Yu, 2022; country: Vietnam; countryCode:
VN; stateProvince: Ha Giang; county: Ha Giang; municipality: Phuong Do; locality: near
Lung Vai Village; verbatimElevation: 850 m; verbatimLatitude: 22°49'50"N;
verbatimLongitude: 104°53'51"E; verbatimCoordinateSystem: WGS84; eventDate:
August 08; eventTime: 2022; eventRemarks: collected by N.V. Hoang and S. Silyavong;
individualCount: 1; sex: male; lifeStage: adult; catalogNumber: LV 53; language: en;
collectionCode: Amphibians; basisOfRecord: PreservedSpecimen; occurrencelD:
F7C18AED-1D84-568E-ACB1-E231A190C353

b. scientificName: Amolops shihaitaol; scientificName!D: Amolops shihaitaoi; class:
Amphibia; order: Anura; family: Ranidae; genus: Amolops; specificEpithet: shihaitaoil;
scientificNameAuthorship: Wang, Li, Du, Hou & Yu, 2023; country: Vietnam; countryCode:
VN; stateProvince: Ha Giang; county: Ha Giang; municipality: Phuong Do; locality: near
Lung Vai Village; verbatimElevation: 850 m; verbatimLatitude: 22°49'50"N;
verbatimLongitude: 104°53'51"E; verbatimCoordinateSystem: WGS84; eventDate:
August 08; eventTime: 2022; eventRemarks: collected by N.V. Hoang and S. Silyavong;
individualCount: 1; sex: male; lifeStage: adult; catalogNumber: LV 57; language: en;
collectionCode: Amphibians; basisOfRecord: PreservedSpecimen; occurrence!D:
19DB3F80-2BF4-506C-9B98-59A11463C6B3

Cc. scientificName: Amolops shihaitaor; scientificName!D: Amolops shihaitaoi; class:
Amphibia; order: Anura; family: Ranidae; genus: Amolops; specificEpithet: shihaitaoy,
scientificNameAuthorship: Wang, Li, Du, Hou & Yu, 2024; country: Vietnam; countryCode:
VN; stateProvince: Ha Giang; county: Ha Giang; municipality: Phuong Do; locality: near
Lung Vai Village; verbatimElevation: 850 m; verbatimLatitude: 22°49'50"N;
verbatimLongitude: 104°53'51"E; verbatimCoordinateSystem: WGS84; eventDate:

Siliyavong S et al

August 08; eventTime: 2022; eventRemarks: collected by N.V. Hoang and S. Silyavong;
individualCount: 1; sex: female; lifeStage: adult; catalogNumber: LV 34; language: en;
collectionCode: Amphibians; basisOfRecord: PreservedSpecimen; occurrencelD:
417C2CA5-B977-522E-A43C-242460636B42

d. scientificName: Amolops shihaitaor; scientificName!D: Amolops shihaitaoi; class:
Amphibia; order: Anura; family: Ranidae; genus: Amolops; specificEpithet: shihaitaor,
scientificNameAuthorship: Wang, Li, Du, Hou & Yu, 2025; country: Vietnam; countryCode:
VN; stateProvince: Ha Giang; county: Ha Giang; municipality: Phuong Do; locality: near
Lung Vai Village; verbatimElevation: 850 m; verbatimLatitude: 22°49'50"N;
verbatimLongitude: 104°53'51"E; verbatimCoordinateSystem: WGS84; eventDate:
August 08; eventTime: 2022; eventRemarks: collected by N.V. Hoang and S. Silyavong;
individualCount: 1; sex: female; lifeStage: adult; catalogNumber: LV 59; language: en;
collectionCode: Amphibians; basisOfRecord: PreservedSpecimen; occurrence!D:
A1C87F5B-3270-5C69-9760-39D16CB01387

Description

Morphological characteristics of the specimens from Ha Giang Province, Vietnam,
agreed with the description of Wang et al. (2022): SVL 33.2-33.6 mm in males (n = 2),
42.2-43.8 mm in females (n = 2); head wider than long; snout short, round; nostril
lateral, wider than interorbital distance and upper eyelid width; tympanum smaller than
half eye diameter; vomerine teeth present; vocal openings absent in males. Forelimb
robust; relative finger lengths | < Il < IV < Ill; fingers free of webbing; tips of fingers
expanded into discs; circummarginal groove on disc of the first finger present; palmar
tubercles two, oval; nuptial pads present in males. Hind-limb long, thigh shorter than
tibia; toes fully webbed, tips of toes expanded into discs; inner metatarsal tubercle
distinct; tarsal fold and tarsal glands absent; tibiotarsal articulation reaching to snout
when limb adpressed along body (see measurements in Table 1). The specimens from
Vietnam slightly differ from the type series from China in having spines on nuptial pads
not clearly distinct in males and this may be due to the difference in sampling time (in
August in Vietnam and in June in China).

Table 1.

Measurements (in mm) of Amolops shihaitaoi collected from Ha Giang Province, Vietnam (M:
male; F: female)

LV 53 LV57 Lv34 Lv59
Sex M M F F
SVL 33.6 33.2 42.2 43.8
HL 11.2 10.8 14.0 14.1
HW 12.9 12.4 15.5 15.8
SL 4.8 44 5.4 5.6
IND 5.0 4.6 5.7 5.8

lOD 2.9 3 3.5 3.6

New record and dietary ecology of a poorly known frog, Amolops shihaitaoi ... 7

LV 53 LV57 LV34 LV59
UEW 3.1 3.2 4.0 3.8
ED 4.8 4.8 5.6 5.9
TD 1.4 1.5 1.4 1.6
DNE 2.1 1.9 2.5 2.6
FHL 18.5 17.6 20.0 20.5
TL 20.5 19.6 23.3 25.1
TFL 27.5 27.3 31.2 32.2
FL 18.2 17.7 21.1 21.8

Skin. Dorsal surface rough and granular with denser small translucent, dorsolateral
folds absent; temporal and loreal region with small white spines; supratympanic fold
present; ventral smooth.

Colouration in life. Dorsal surface olive-brown with dark brown patches and dark
irregular transverse bars on limbs; flanks olive-brown with warts dark or white; ventral
surface white, ventral surface of limbs cream (Fig. 2).

Riper ne

Figure 2. EES]

Adult male (Left) and natural habitat (Right) and of Amolops shihaitaoi in Ha Giang Province,
northern Vietnam.

Distribution

In Vietnam, this species was previously recorded from Lao Cai, Cao Bang and Vinh
Phuc Provinces (Wang et al. 2022). This is the first record of the species in Ha Giang
Province. Elsewhere, this species is known from southern China (Wang et al. 2022).

Ecology

Specimens of A. shihaitaoi were found on the cliff of waterfalls and large rocks in the
streams between 20:00 and 23:00 h. The surrounding habitat was evergreen forest of
large hardwood and shrub (Fig. 2).

Siliyavong S et al

Diet

A total of 40 adult individuals (20 males and 20 females) of A. shihaitaoi were collected
from Ha Giang Province for stomach flushing, of which three frogs (or 7.5%) had empty
stomachs. We identified 529 prey items, including 515 items of animals and 14
unidentified items. Males had 190 prey items, while females had 339 prey items.

The number of prey items per individual ranged 2—40 items (average 14.69 + 9.19
items). The number of prey items in males ranged 2—40 (average 11.18 + 8.41 items),
while in females, it ranged 4—35 (average 17.84 + 8.90 items) (Kendall’s tau b: tau =
0.355, P = 0.004) (Table 2).

Table 2.

Summary (Total, Mean, SD and range) of the prey item number (N), width (VW), length (L) and
volume (V) data for males and females (in mm for W and L; in mm? for V).

Prey item

Male (n = 190) Female (n = 339)
WwW 0.40—10.00 1.60 + 1.69 0.40—7.00 1.66 + 1.19
L 1.00—30.00 4.48 + 3.30 1.00—40.00 5.95 + 4.24
V_total 10.71-688.21 140.57 + 210.38 36.85—-848.06 334.16 + 248.55
V_minimum 0.13-1.83 0.62 + 0.5 0.21-4.71 1.03 + 1.26
V_maximum 2.88-392.5 53.2 + 94.03 18.84-564.15 145.84 + 146.43
V_mean 1.32-98.32 14.46 + 24.7 1.67-74.42 21.98 + 17.46
N 2.00—40.00 11.18 + 8.41 4.00-—35.00 17.84 + 8.90

Mean prey item length was 5.43 + 3.99 mm (ranging from 1.00 to 40.00 mm) and mean
prey item width was 1.64 + 1.39 mm (ranging from 1.00 to 40.00 mm) in both sexes.

Mean prey item length in males was 4.48 + 3.30 mm (ranging from 1.00 to 30.00 mm)
and ranged from 1.00 to 40.00 mm in females (average 5.95 + 4.24 mm); those were
significantly different from each other (F1 52g = 1.449, P = 0.018) as well as mean prey
item width in males being 1.60 + 1.69 mm (ranging from 0.4 to 10.00 mm) and ranging
from 0.40 to 7.00 mm in females (average 1.66 + 1.19 mm); those were significantly
different from each other (F4 413 = 2.018, P= 0.001).

The average volume per individual was 242.73 + 248.19 mm? (ranging from 10.71 to
848.06 mm’). In which, the average volume per male individual was 140.57 + 210.38
mm? (ranging from 10.71 to 688.21 mm’) and 334.16 + 248.55 mm? (ranging from
36.85 to 848.06 mm?) in female; those were significantly different from each other (tau
= 0.472, P< 0.01) (Table 2).

There was not a positive correlation between the frog SVL and the minimum prey
volume (tau = 0.47, P = 0.672) (Fig. 3 A), while there were correlations between the

New record and dietary ecology of a poorly known frog, Amolops shihaitaoi ... 9

frog SVL and the maximum prey item volume (tau = 0.356, P < 0.01), mean prey item
volume (tau = 0.354, P = 0.01) and the total prey volume (tau = 0.351, P < 0.01) (Fig. 3
B-D).

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Figure 3. EES

Relationships between the frog SVL and the minimum (A), maximum (B) and the mean (C)
prey item volume and the total prey volume (D). Dots: Males; Open triangles: Females; Vmin =
minimum prey item volume (mm?); Vmax = maximum prey item volume (mm°); Vmean =
mean prey item volume (mm?); Vtotal = the total prey volume (mm?).

We identified 35 different categories of prey and other unidentified subjects in the
stomachs of A. shihaitaoi with insects being the main food component, including 11
orders and other invertebrate groups, namely Opiliones, Araneae, Crustacea and
Diplopoda (Table 3).

Table 3.

Dietary composition (%) of Amolops shihaitaoi with regards to frequency of occurrence,
numeric proportion, volume proportion and overall importance index of each prey category (n =
529 prey items).

Prey category Frequency Numeric proportion Volume proportion Importance index
Opiliones 0.69 2.84 0.36 1.30
Araneae 8.33 9.45 6.15 7.98

Crustacea 1.39 0.38 1.46 1.08

10

Prey category
Diplopoda
Blattodea
Blaberidae
Blattidae
Coleoptera
Brentidae
Byrrhidae
Tenebrionidae
Coleoptera other
Dermaptera
Forficulidae
Diptera
Anthomyiidae
Mycetophilidae
Ephemeroptera
Baetidae
Leptophlebiidae
Hemiptera
Aleyrodidae
Cercopidae
Hemiptera other
Hymenoptera
Braconidae

Formicidae

Hymenoptera other

Lepidoptera
Geometridae
Gracillariidae
Hepialidae
Noctuidae
Lepidoptera other
Mantodea

Mantidae

Frequency

2.08

1.39

3.47

2.08
0.69
1.39

4.86

0.69

1.39

0.69

0.69

2.08

0.69
0.69

1.39

0.69
14.58

1.39

1.39
2.08
1.39
0.69

15.28

4.17

Siliyavong S et al

Numeric proportion

1.32

0.95

3.59

1.51

0.76

0.38

2.84

2.84

0.38

0.57

0.57

2.46

9.64

Volume proportion

0.92

1.00

7.52

0.56

0.71

0.04

9.67

0.32

0.23

0.07

0.35

3.48

7.55

Importance index

1.44

4.86

1.39
0.72
0.60

5.79

1.28

0.66

0.44

0.54

2.67

0.83
0.46

1.59

0.46
11.52

0.96

1.07
2.67
3.24
0.66

8.53

7.12

New record and dietary ecology of a poorly known frog, Amolops shihaitaoi ... 11

Prey category Frequency Numeric proportion Volume proportion Importance index
Orthoptera

Acrididae 11.11 13.42 8.59 11.04
Gryllotalpidae 0.69 4.35 8.03 4.36

Gryllidae 0.69 3.59 4.83 3.04

Tetrigidae 2.08 3.21 1.92 2.40
Tettigoniidae 0.69 1.32 2.05 1.36

Orthoptera other 0.69 0.19 2.17 1.02

Trichoptera
Leptoceridae 1.39 0.57 0.11 0.69

Unidentified 6.25 2.65 6.47 5.12

The most commonly consumed prey items were Formicidae (15.12%), followed by
Acrididae (13.42%), Mantidae (9.64%), Araneae (9.45%) and other Lepidoptera
(8.70%). While the most frequently foraged prey group was Lepidoptera other
(15.28%), followed by Formicidae (14.58%), Acrididae (11.11%), Araneae (8.33%) and
Mantidae (4.17%). In the comparisons by the IRI, Formicidae (11.5%), Acrididae
(11.0%), other Lepidoptera (8.5%), Araneae (8.0%) and Mantidae (7.1%) were
identified as the most important prey groups (Table 3).

The total dietary breadth of A. shihaitaoi from Vietnam was 13.22 (Simpson’s index of
diversity) and Shannon’s evenness was 0.82. Adult females (19 prey categories)
consumed more diverse prey than adult males (16 prey categories). The diversity index
of prey categories of adult males (11.11 with an evenness index of 0.41) was also lower
than that of adult females (11.48 with an evenness index of 0.61) (Table 4).

Table 4.

Simpson’s Index of Diversity and Shannon’s Evenness between sexes in the diet of Amolops
shihaitaoi from Ha Giang Province, Vietnam.

Sex Simpson’s index 1/D Shannon’s evenness E
Males 11.11 0.41
Females 11.48 0.61
Total dietary 13.22 0.82

There was an overlap of more than 65% in the diet of males and females. The trophic
spectrum of males consisted of 24 prey categories, the most important groups (with IRI
> 6) being Araneae, Lepidoptera, Blattidae, Hepialidae, Formicidae and Acrididae,
while the trophic spectrum of females comprised 26 prey categories, with Formicidae,
Acrididae, Mantidae, Gryllotalpidae and Coleoptera being the most important prey
categories.

12

Siliyavong S et al

Byrrhidae, Tenebrionidae, Forficulidae, Anthomyiidae, Mycetophilidae, Baetidae,
Braconidae, Noctuidae and Leptoceridae were found exclusively in the diet of males,
whereas Opiliones, Crustacea, Diplopoda, other Hymenoptera, Gryllotalpidae,
Gryllidae, Tetrigidae, Aleyrodidae, Cercopidae, Tettigoniidae and Orthoptera were
found only in the diet of females. Despite these differences, Formicidae and Acrididae
were identified as the most important prey categories for both males and females (Fig.
4).

16.00
14.00
* Male a Female
12.00

10.00

8.00 4

Ix

6.00
4.00
2.00

0.00 —

i) re)

me) 4 ~ me. . vr eR A) F C
oe Rome o« S «e of Sy oP rE Sof «> <= = » Kyra Se

Figure 4. EE

Importance indices (Ix) for prey categories consumed by males (cross) vs. females (black) of
Amolops shihaitaoi in Vietnam. For: Formicidae, Acr: Acrididae, Lep: Lepidoptera other, Ara:
Araneae, Uni: Unidentified, Bla: Blattidae, Hep: Hepialidae, Man: Mantidae, Col: Coleoptera
other, Gra: Gracillariidae, Lept: Leptophlebiidae, Blab: Blaberidae, Bre: Brentidae, Hem:
Hemiptera other, Geo: Geometridae, Gry: Gryllotalpidae, Gryl: Gryllidae, Tetr: Tetrigidae, Tet:
Tettigoniidae, Opi: Opiliones, Ort: Orthoptera other, Hym: Hymenoptera other, Ale:
Aleyrodidae, Cer: Cercopidae, Cru: Crustacea, Dip: Diplopoda, Byr: Byrrhidae, Ten:
Tenebrionidae, Forf: Forficulidae, Ant: Anthomyiidae, Myc: Mycetophilidae, Bae: Baetidae,
Brac: Braconidae, Noc: Noctuidae, Lepto: Leptoceridae.

Discussion

Most studies show that insects are the main diet of frogs, which is also the most diverse
prey group (Werner et al. 1995, Hothem et al. 2009, Brito et al. 2013, Ngo et al. 2014,
Pham et al. 2019, Pham et al. 2022). Anurans are often feeding on spiders, beetles,
grasshoppers, cockroaches, termites and ants (e.g. Biavati et al. (2004), Laufer (2004),
Caldart et al. (2012), Pham et al. (2019), Pham et al. (2022)).

Our results showed that A. shihaitaoi preys on a wide variety of insects, similar to other
studies on the diet of frogs from Vietnam (Ngo et al. 2014, Pham et al. 2019, Pham et al.
2022). The most common prey items of A. shihaitaoi were beetles, chalk wings, crickets,
grasshoppers, ants and other groups, these being similar to the diet of many frogs (Ngo et

New record and dietary ecology of a poorly known frog, Amolops shihaitaoi ... 13

al. 2014, Pham et al. 2019, Pham et al. 2022). These are terrestrial prey, which is in line
with their general habitat use (Pham et al. 2019). Besides prey categorized as insects, A.
shihaitaoi also consumed other invertebrates, viz. spiders, earwigs and crabs.

We also found differences in the dietary composition between males and females of A.
shihaitaoi. While 26 prey catergories were recorded in females, only 24 were recorded in
the males. These differences may be related to behavioural differences, as females do not
defend calling sites or engage in agonistic interactions, allowing them to feed more
frequently (Brasileiro et al. 2010, Caldart et al. 2012). Despite a varied diet, A. shihaitaoi
had a narrow niche breadth with a few categories comprising most of the diet (frequency),
including Lepidoptera (20.83%), Hymenoptera (16.67%), Orthoptera (15.97%) and
Coleoptera (9.72%) (Table 2). Our estimation of prey availability suggested that food
resources for A. shihaitaoi were abundant in the studied streams, allowing the co-existence
of both adult males and females, despite their high dietary overlap of > 65% between
males and females.

As females have a larger body size than males, they are more likely to consume larger
prey items than males (Le et al. 2020). In this study, we found also the prey volume of A.
shihaitaoi in females was greater than that in males. This is consistent with the scale-
efficiency hypothesis (Forsman 1996).

Acknowledgements

We are grateful to the directorates of Tay Con Linh Nature Reserve for support of our
fieldwork and issuing relevant permits. We thank Ly Van Hong (Ha Giang) for their
assistance in the field. This research is supported by the Ministry of Education and Training
(Grant No. B2021-TNA-20).

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