A peer-reviewed open-access journal 


ZooKeys 725: 49-69 (2017) 


doi: 10.3897/zookeys.725. 13675 #Zo0o0Ke y S 


http:/ /Z00 keys -pen soft.net Launched to accelerate biodiversity research 


Whitefly predation and extensive mesonotum color 
polymorphism in an Acletoxenus population from 
Singapore (Diptera, Drosophilidae) 


Wong Jinfa', Foo Maosheng’, Hugh T. W. Tan', Rudolf Meier!” 


| Department of Biological Sciences, National University of Singapore, Singapore 117543 2. Lee Kong Chian 
Natural History Museum, National University of Singapore, Singapore 117377 


Corresponding author: Rudolf Meier (meier@nus.edu.sg) 


Academic editor: V. Silva | Received 14 May 2017 | Accepted 12 September 2017 | Published 29 December 2017 
http://zoobank. org/A3484B 14-F925-4CA8-8577-9ABDDACB5715 


Citation: Wong, J, Foo, M, Tan HTW, Meier R (2017) Whitefly predation and extensive mesonotum color 
polymorphism in an Acletoxenus population from Singapore (Diptera, Drosophilidae). ZooKeys 725: 49-69. https:// 
doi.org/10.3897/zookeys.725.13675 


Abstract 

Acletoxenus is a small genus of Drosophilidae with only four described species that are closely associated 
with whiteflies (adults and larvae). Here, the first video recordings of larvae feeding on whiteflies 
(Aleurotrachelus trachoides) are presented. Typical morphological adaptations for predation by schizophoran 
larvae are also described: the larval pseudocephalon lacks a facial mask and the cephaloskeleton is devoid 
of cibarial ridges that could be used for saprophagy via filtration. Despite being a predator, Acletoxenus 
is unlikely to be a good candidate for biological control of whiteflies because the life cycle is fairly long 
(24 days), lab cultures could not be established, and the puparia have high parasitization rates by a 
pteromalid wasp (Pachyneuron leucopiscida). Unfortunately, a confident identification of the Singapore 
Acletoxenus population to species was not possible because species identification and description in the 
genus overemphasize coloration characters of the mesonotum which are shown to be unsuitable because 
the Singapore population has flies with coloration patterns matching three of the four described species. 
Based on morphology and DNA sequences, the population from Singapore is tentatively assigned to 
Acletoxenus indicus or a closely related species. 


Keywords 
Acletoxenus, Diptera, Drosophilidae, predatory maggot, Singapore, whitefly 


Copyright Wong Jinfa 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. 


50 Wong Jinfa et al. / ZooKeys 725: 49-69 (2017) 


Introduction 


Drosophilidae contains >3950 described species in 77 genera and two subfamilies 
(Bachli 2015). The best-known species is Drosophila melanogaster which is typical for 
most in the family in that it has saprophagous larvae. However, the larvae of many oth- 
er drosophilid species utilize a wide variety of substrates and the natural history of the 
family is full of surprising convergence. For example, associations between drosophilid 
larvae and spittlebugs have evolved at least three times (Ihompson and Mohd-Saleh 
1995) and gave rise to a species-rich clade with more than 100 species (Cladochaeta: 
(Wheeler and Patterson 1952, Grimaldi and Nguyen 1999). Many other drosophilid 
species have larvae that prey on eggs, including the species in the Drosophila simulivora 
species group whose aquatic larvae feed on the eggs and larvae of Simuliidae, Chi- 
ronomidae, and Odonata (Aubertin 1937, Tsacas and Disney 1974). Another case 
of surprising convergence is found in Steganinae. Rhinoleucophenga (Steganinae) and 
Acletoxenus have larvae that are predators of Sternorrhyncha (Malloch 1929, Clausen 
and Berry 1932, Ashburner 1981, Parchami-Araghi and Farrokhi 1995, Culik and 
Ventura 2009, Lambkin and Zalucki 2010, Yu et al. 2012). Yet, Rhinoleucophenga and 
Acletoxenus are distantly related; i.e., larval predation of Sternorrhyncha by steganine 
larvae likely evolved twice. 

Recently, an Acletoxenus population was discovered in Singapore that was associated 
with whiteflies feeding on chilli plants, Capsicum annuum L. (Solanaceae). The popula- 
tion was studied in greater detail and we present the first video recordings documenting 
larval predation , provide a larval description, and determine the length of the life cycle. 
Lastly, we comment on the inappropriateness of using mesonotum coloration for species 
identification and description in Acletoxenus. The color patterns of the mesonotum are 
shown to be very variable within a single population. Yet, the description and identifica- 
tion of the four currently accepted species rely quite heavily on color pattern and chae- 
totaxy characters (Table 1, Fig. 1). This is partially due to the fact that the type of one of 
the species is female (Acletoxenus indicus Malloch, 1929) so that a comparison of male 
genitalia with the remaining species cannot be carried out. Fortunately, male type mate- 
rial is available for Acletoxenus formosus (Leow, 1864) (see Bachli 1984), Acletoxenus quad- 
ristriatus Duda, 1936, and Acletoxenus meijerei. The latter has syntypes in Berlin (Bachli 
1984: sex not specified) and a male syntype in Amsterdam (Bachli 1987: now Leiden), 
but the location of the latter is currently unknown (Pasquale Cliliberti, pers. comm.). 


Materials and methods 


Acletoxenus recruitment, collection, and identification 


Chili (Capsicum annuum ‘Yang Jiao’) were grown along a building corridor of Block 
S2 of the Kent Ridge campus of the National University of Singapore (1°17'45.01"N, 
103°46'41.08"E). Whiteflies naturally appeared on the chilli plants which in turn attracted 


Whitefly predation and extensive mesonotum color polymorphism in an Acletoxenus... 51 


Table |. Morphological differences between the described species of Acletoxenus. 


Proclinate orbital bristles not notice- 


ably shorter than the anterior reclinate 


Acletoxenus formosus | bristles (Malloch 1929) Mesonotum almost entirely black with yellowish 
(Leow, 1864) Proclinate orbital bristles noticeably tan lateral margins (Malloch 1929, Bock 1982) 
shorter than anterior reclinate bristles 

(Bachli et al. 2004) 

Proclinate orbital bristles noticeably — | Mesonotum with central black vitta and two 
shorter than anterior reclinate bristles | vittas on each side that are interrupted at suture 
(Malloch 1929) and extend sublaterally (Malloch 1929) 
Mesonotum with two broad dark vittas which 
are more or less confluent behind the suture and 


Acletoxenus indicus 


Malloch, 1929 


.., | Proclinate orbital bristles not notice- 
Acletoxenus meijerei 


Duda, 1924 


ably shorter than anterior reclinate 


bristles (Duda 1924, Malloch 1929) do not extend to the hind margin margin (Duda 


1924, Malloch 1929, Bock 1982) 

Mesonotum with four broad dark longitudinal 
Proclinate orbital bristles noticeably _| vittas coalescing or slightly separated, with the 
shorter than the anterior reclinate medial vittas reaching to rear third while the 
bristles (Malloch 1929) lateral ones almost to the posterior dorsocentral 
(Malloch 1929, McEvey 2016) 


Acletoxenus quadris- 


triatus Duda, 1936 


Figure |. Morphology of A Acletoxenus formosus BA. indicus C A. meijerei, and D A. quadristriatus. 


Acletoxenus. Adult flies were captured and either stored in 100% ethanol or flash frozen 
with liquid nitrogen before being stored in a freezer at -80 °C. Three morphotypes were 
identified based on the pigmentation pattern of the mesonotum. These morphotypes 
corresponded to the descriptions and figures (see McEvey 2016) of Acletoxenus formosus, 


52 Wong Jinfa et al. / ZooKeys 725: 49-69 (2017) 


Acletoxenus indicus, and Acletoxenus quadristriatus (Malloch 1929, Duda 1936, Bock 
1982). The relative abundance of the three morphotypes was determined, and Fisher's exact 
probability 2 x 3 test was used to test whether the differences were significant. Samples 
were also sent to Dr. Gerhard Bachli from the Zoological Museum of the University of 


Zurich and Dr. Shane McEvey from the Australian Museum for identification. Samples 
of the whiteflies' fourth instars were sent to Dr. Paul De Barro (CSIRO). 


DNA barcoding 


Genomic DNA was extracted from whole specimens of using QIAGEN DNeasy 
Blood & Tissue Kits. Polymerase chain reaction (PCR) was used to amplify the 
target mitochondrial cytochrome c oxidase, subunit I (COI) gene using primer pairs 
(Table 2). The PCR mixture (20 pL) contained 2.5 uL of buffer, 2 uL of dNTP, 1 pL 
of each primer of a primer pair, 0.15 pL of Ex Tag and 5 pL of template DNA. The 
program consisted of 40 cycles of amplification (30 sec of denaturation at 94 °C, 30 
sec of annealing at 52 °C and 1 min of extension at 72 °C). The PCR products were 
then purified using BIOLINE SureClean according to the manufacturer's protocol 
before cycle sequenced using BigDye Terminator ver. 3.1 Cycle Sequencing Kit. The 
cycle sequencing mixture (10 wL) contained 2 uL of buffer, 0.5 pL of BigDye, 1.75 wL 
of each primer and 2 pL of template DNA. The program consisted of 1 min of initial 
denaturation at 95 °C, followed by 25 cycles of amplification (30 sec of denaturation 
at 94 °C, 30 sec of annealing at 52 °C and 4 min of extension at 60 °C). An ABI 
3730xl sequencer was used for sequencing. Reference COI sequences for Acletoxenus 
formosus (700 base pairs) and Acletoxenus indicus (1536 base pairs) were downloaded 
from GenBank (accession numbers EF576933, HQ701131). The sequences for the 
different Acletoxenus morphotypes from Singapore were then aligned against the 
reference sequences from GenBank using MAFFT ver. 7 using the default settings 
(Katoh and Standley 2013). Afterwards, MEGAG6 was used to add the new sequences 


for Acletoxenus in order to determine pairwise distances (Tamura et al. 2013) 


Are Acletoxenus predators? 


Behavioral observations of Acletoxenus larvae and adults were made in the field and ex- 
situ. Ihe ex-situ observations were based on individuals that were placed on whitefly 
infested leaves under a dissection microscope. Behavior was video-taped using a Canon 
LEGRIA HF S30 video camera. In addition, the morphology of the larvae and adults 
was studied in order to determine whether the species has features that are known to 
be typical of predatory larvae. For comparative purposes, the larvae of a known sap- 
rophage, Drosophila melanogaster, were also studied. All larvae were killed in hot soapy 
water before dehydration via a graded ethanol series (see Meier 1995, 1996). In order 


Whitefly predation and extensive mesonotum color polymorphism in an Acletoxenus... 53 


Table 2. Primer pairs used in PCR reaction. 


Species Primer name Primer sequence 
LCO1490 5S’-GTCAACAAATCATAAAGATAT TGG-3’ 
Acletoxenus (2 individuals HCO2198 5’-TAAACTTCAGGGTGACCAAAAAATCA-3’ 
from each sex and : : 
morphotype) s2183 5S’-CAACATTTATTTTGATTTTTTGG-3 
43014 5’7-TCCAAT GCACTAATCTGCCATATTA-3’ 
mlCOlintF 5S’-GGWACWGGW TGAACWGTW TAYCCYCC-3’ 
Whitefly prey 
jgHCO2198 5’-TAIA CYTCIGGRTGICCRAARAAYCA-3’ 
LepF 5’-ATTCAACCAATCATAAAGATAT TGG-3’ 
Parasitoid wasp 
LepR 5’-TAAACTTCTGGATGTCCAAAAAATCA-3’ 


to study the cephaloskeleton, the larvae were cut at the mid-section and soaked in 
potassium hydroxide for 15 minutes (light microscopy with Olympus BX51) or three 
days (confocal microscopy: mounted on glass slide with Euparal; imaging with a Zeiss 
LSM 510 META at 20x using 488 nm wavelength with LP505 filter). The confocal 


images were rendered into a three-dimensional model with Amira 5.3.3. 


Life cycle of Acletoxenus 


Field observations were used for determining the length of the life cycle of Acletoxenus 
because attempts to rear the species under laboratory conditions failed. Individual lar- 
vae on chili plant leaves infected with whiteflies were regularly tracked. Upon discovery 
of an Acletoxenus egg, larva, or puparium, its length was measured with Vernier calipers 
and the leaf was labelled. On the following day, all labelled leaves were checked for the 
presence of the same individual as determined by stage and size. If a larva was no longer 
present, the leaves in closest proximity were checked until a larva was located. The larva 
was deemed to be the same individual if its length was the same or slightly longer. All 
larvae that could no longer be located were excluded from determining the duration of 
the larval stage. If there were multiple larvae on a leaf, data were only collected if the 
lengths of the larvae were sufficiently different to distinguish individuals. 

In order to determine adult longevity, adult emergence was documented by col- 
lecting puparia (n= 34) and placing them on moist tissue paper in an enclosed plastic 
container. Emergence was recorded with a Canon LEGRIA HF S30 video camera (see 
above). Newly emerged Acletoxenus were then used to determine the life span of adults 
by maintaining them in Petri dishes in an air-conditioned laboratory at 25 °C. The 
Petri dishes contained a piece of whitefly-infested leaf placed on a moist piece of tissue 
paper and a cotton ball soaked in honey. ‘The leaves were changed every other day and 
the cotton ball weekly to ensure an adequate supply of food. The lifespan of each adult 
was calculated by counting the number of days from emergence to death. 


54 Wong Jinfa et al. / ZooKeys 725: 49-69 (2017) 


Parasitism 


In the last four months of the experiment, the population of Acletoxenus declined and 
many Acletoxenus puparia were black instead of green. Parasitization was suspected and 
a few dark puparia were subsequently placed on wet tissue paper in a plastic container. 
Parasitoids emerged and were killed in 100% ethanol before identifying them using 
taxonomic keys (Mani 1939, Gupta and Poorani 2009). Photographs of the parasitoid 
wasp were also taken with a Nikon EOS-1 camera (Visionary Digital). Only empty 
parasitized puparial cases retained some dark brown pigments, which allowed for de- 
termining of the monthly rate of parasitism based on empty puparia (May—July 2014). 


Results and discussion 


No confident species identification despite a wealth of knowledge 


The flies were confirmed to belong to Acletoxenus by S McEvey (pers. comm.) and G. 
Bachli (pers. comm.). Specimens representing the Singapore Acletoxenus population 
have proclinate orbital setae that are noticeably shorter than the anterior reclinate setae 
(Fig. 3). According to the identification key in Malloch (1929; see couplet 1), only two 
of the four described species of Acletoxenus have this trait (A. indicus; A. quadristria- 
tus), but note that Bachli et al.’s (2004) redescription of A. formosus mentions that this 
species also has noticeably shorter anterior reclinate setae. This means that the bristle 
character observed in the Singapore specimens only excludes A. meijerei. It was hoped 
that species identification would be possible based on the mesonotum coloration pat- 
terns that feature prominently in the taxonomic literature on Acletoxenus. However, 
the Singapore population includes specimens that match the patterns of three of the 
four described species of Acletoxenus (Fig 2): the A. guadristriatus morphotype is only 
present in males while the other two morphotypes are found in both sexes (Fig. 2). 
Gender and morphotypes were significantly co-dependant (Fisher’s exact probability 
test, p-value < 0.01) with the A. formosus morphotype being more common in females. 
An additional character system that is discussed in the literature is the coloration pat- 
terns of the abdomen. However, the dorsocentral black mark on the fourth tergite and 
a much smaller mark of similar shape on the fifth tergite are found in all morphotypes 
(Fig. 2). The coloration patterns on the remaining tergites are also variable in the 
Singapore population and range from broadly blackened tergites (Fig. 2A) to reduced 
spots (Fig. 2B, C). Note that such intraspecific variability has previously been noted 
for A. formosus (Collin 1902, Malloch 1929, Bock 1982) but it is here confirmed for 
yet another Acletoxenus species. 

For two reasons, we are confident that this morphological variability in the Singapore 
population was indeed intraspecific. Firstly, it appears unlikely that more than one 
species was found on the same hallway of a building on NUS campus. Secondly, COI 
barcodes were sequenced for two individuals of each sex and morphotype. When these 


Whitefly predation and extensive mesonotum color polymorphism in an Acletoxenus... 55 


O:4 
2:0 


Figure 2. Mesonotum color patterns A entirely black B with central black vitta that is split and con- 
nected to two other vittas on each side, and C four dark longitudinal stripes; all three morphotypes were 


bred from larvae collected together on the same host plant in Singapore. 


Anterior reclinate orbital seta 


proclinate orbital seta 


1mm 


Figure 3. Acletoxenus sp. proclinate orbital setae noticeably shorter than the anterior reclinate setae. 
sequences were aligned and compared, the average pairwise distance between the 12 


individuals from Singapore was 0.06% which is compatible with intraspecific variability 
and rarely observed between species of Diptera (Meier 2008, Meier et al. 2008). 


56 Wong Jinfa et al. / ZooKeys 725: 49-69 (2017) 


When the sequences were compared with those in Genbank, the best uncorrected 
pairwise match was 1.69% (Srivathsan and Meier 2012) and the matching sequence 
belonged to a specimen from China that was identified as Acletoxenus indicus (Accession 
number: HQ701131.1). The match to a sequence for A. formosus (Accession number 
EF576933.1) was much poorer (11.14%) and is consistent with being interspecific 
(Meier et al. 2008). No sequences are known for Acletoxenus quadristriatus which is 
only known from Thursday island and was described after A. indicus. Overall, there is 
no described feature that distinguishes the Singapore population from A. guadristriatus 
or A. indicus but the latter is hypothesized to have a wide distribution that is compatible 
with the occurrence of the species in Singapore; i.e., based on overall evidence, we 
believe that the Singapore population either belongs to A. indicus or represents a closely 
related species because a barcode distance of 1.69% is reasonably common within but 
also between species given that COI is not directly involved in speciation and only 
measures time of divergence (Kwong et al. 2012). If A. indicus is indeed polymorphic 
and widespread, it raises the possibility that_A. quadristriatus could be a junior synonym 
of A. indicus. However, this issue can only be addressed by detailed study of all types. 
A stumbling block will be the fact that A. indicus was described based on a female; i.e., 
one would have to find a species-specific character in a female that can distinguish this 
species from all others. 

Overall, it is frustrating that despite having obtained considerable amounts of mor- 
phological and molecular data, the specimens could not be identified confidently to 
species. In the case of Acletoxenus, it was the widespread use of color pattern characters 
and a species description based on a female that caused this problem. But identification 
problems are so common that they play a major role in the decline of natural history 
research (Tewksbury et al. 2014). Many observations on insects and other animals are 
made but they are difficult to communicate because the species involved cannot be 
identified even if a voucher is collected. This problem is particularly severe in the trop- 
ics where the species diversity is high (e.g., Basset et al. 2012), most species are unde- 
scribed (e.g., Riedel et al. 2010), and many old descriptions are so superficial that they 
cannot be used for species identification (Meier 2017). Arguably, the best way forward 
will be higher quality (re)descriptions (Tan et al. 2010, Ang et al. 2013b, Rohner et al. 
2014), digital reference collections including types and specimens identified by taxo- 
nomic experts (Ang et al. 2013a), and DNA barcodes (Hebert et al. 2003). ‘The latter 
are becoming sufhciently cost-effective (Wong et al. 2014, Meier et al 2016) that they 
can become widely available. They can be used to obtain approximate species identifi- 
cations once more of the fauna is barcoded (Kwong et al. 2012). This can now happen 
rapidly through low-cost “NGS barcoding” (Meier et al. 2016). Hopefully biologists 
will start collecting vouchers associated with interesting natural history observations 
that can be published in journals such as the Biodiversity Data Journal (Smith et al. 
2013). The natural history observations can be included in such publications where the 
video evidence can be embedded in the publication (e.g., Ang et al. 2013b). 


Whitefly predation and extensive mesonotum color polymorphism in an Acletoxenus... 57 


Are Acletoxenus Predators? 


The first video evidence that the larvae are indeed predators of whiteflies is presented 
here (Movie 1). The larvae move on infected leaves by raising and swinging their 
anterior end (“pseudocephalons”) from side to side (Movie 2). If no prey is touched, 
the mouth hooks are used to anchor the anterior end of the larva. After anchoring, 
the abdominal segments move forward via contraction (Movie 3). However, if prey is 
touched, the larva uses its mouth hooks to stab a whitefly puparium whose content 
is then imbibed (Fig. 4A, Movie 2). When a whitefly puparium is empty and gets 
dislodged from the leaf, it is often glued to the body of the Acletoxenus larva using a 
mucus secreted by the larva (Clausen and Berry 1932, Ashburner 1981). Similarly, 
whitefly eggs and wax are often found glued to the larva. Overall, the larvae move 
little and slowly (see Movie 3) and Clausen and Berry (1932) even stated that Acle- 
toxenus indicus larvae are largely inactive and never leave the leaf upon which they 
were born. However, this is not the case for the Acletoxenus population in Singapore. 
Larvae did move to other leaves in order to locate prey, albeit at a very slow speed. All 
movements (forward or backward) were via peristaltic contractions of the abdominal 
segments (Movie 3). 


Movie |. Acletoxenus cf. indicus: larval predation behavior. 


58 Wong Jinfa et al. / ZooKeys 725: 49-69 (2017) 


[>| 


Movie 2. Acletoxenus cf. indicus: larval feeding behavior and camouflage. 


Figure 4. Acletoxenus cf. indicus larvae A feeding on whitefly B have a green colored body, and C are 


usually covered in whitefly wax and instars D SEM Lateral view, and E SEM of pseudocephalon with 


strongly reduced facial mask. 


As discussed in Courtney et al. (2000), most predatory cyclorrhaphan larvae have 
strongly reduced facial masks that often lack the cirri and oral ridges that are present 
in saprophagous Cyclorrhapha larvae for rasping and directing bacteria into the mouth 


Whitefly predation and extensive mesonotum color polymorphism in an Acletoxenus... 59 


Movie 3. Acletoxenus cf. indicus: larval movements. 


opening (Dowding 1967, Roberts 1971). This is also the case for saprophagous ephy- 
droid larvae (Ferrar 1987, Kirk-Spriggs et al. 2002, Wipfler et al. 2013). The pseudo- 
cephalon of Acletoxenus fits the pattern of a predatory cyclorrhaphan larva. The preoral 
cavity on the ventral side of the pseudocephalon has few oral ridges flanking the mouth 
and lacks a well-developed facial mask (absence of cirri; Fig. 4E). The cephaloskeleton 
of Acletoxenus is furthermore semi-translucent and less sclerotized than that of Dros- 
ophila melanogaster and lacks a pharyngeal filter (Fig. 5) while it was clearly visible for 
D. melanogaster larvae (Fig. 6). Additional adaptations for being a diurnal predator are 
found on the remaining larval body segments. The larvae are so weakly sclerotized that 
the internal fat body is visible. It turns from cream-colored in early instars to green- 
ish in third instars (3-4 mm long, 1mm wide; Fig. 4) and thus provides camouflage 
on leaves (Movie 1 and 2). Camouflage is also the most likely explanation for why 
the larva collects and glues whitefly wax, egg and puparium onto its body (Fig. 3C; 
Clausen and Berry 1932, Ashburner 1981). Because pupation of schizophoran flies 
takes place within the last larval skin, this camouflage extends to the pupal stage of 
Acletoxenus (Fig. 10; ca. 3.3 mm long, 1.3 mm wide) (Fig. 10); the pupal integument 
remains translucent and reveals the green color of the fat body and later the red eyes of 
the developing adult (Fig. 10C). The puparia are glued via a flattened ventral surface to 
leaf surfaces (Clausen and Berry 1932) and the ability to adhere to surfaces is retained 


60 Wong Jinfa et al. / ZooKeys 725: 49-69 (2017) 


100 um 


Figure 5. Acletoxenus cf. indicus larval cephaloskeleton A lateral view with light microscope B ventral 


view close-up with light microscope C ventral view with light microscope, and D ventral view with confo- 


cal microscope, showing a lack of pharyngeal filter. 


even when the puparia are dislodged and placed on moist tissue. The adults emerge by 
breaking open the distinct lid at the anterior end and leave behind a translucent empty 
puparium (Clausen and Berry 1932). 

In contrast to the larvae that have obvious adaptations for predation, the adults 
are apparently not predatory. This conclusion is mostly based on observations, but the 
adults also lack obvious morphological adaptations for predation. For example, the 
adults have a typical schizophoran proboscis (Colless and McAlpine 1991) with two 
sponge-like labellar lobes (Fig. 7). Each labellar lobe has six pseudotrachea with likely 
capillary function (Fig. 7) (Elzinga and Broce 1986). 

Prey: Acletoxenus larvae belonging to the Singapore population preyed on 
Aleurotrachelus trachoides (Back, 1912) (Fig. 8A) which has fourth instars with den- 
tate margin and a large, setose lingual that expands apically and protrudes beyond 
the vasiform orifice. These features were used for a preliminary identification but 
the identity of the prey was also confirmed by D Barro (pers. comm.) and DNA 
barcodes (99% match to sequence for Aleurotrachelus trachoides; accession num- 
ber KF059957) (Hodges and Evans 2005, Walker 2008). Note that Aleurotrachelus 
trachoides, is a major cosmopolitan pest of commercial plants (Hodges and Evans 


2005, Malumphy 2005, Martin 2005, Forest Health 2013 highlights 2014). Thus, 


Whitefly predation and extensive mesonotum color polymorphism in an Acletoxenus... 61 


100 pm 


Figure 6. Drosophila melanogaster larval cephaloskeleton A lateral view with light microscope B ventral 
view close-up with light microscope C ventral view with light microscope, and D ventral view with confocal 


microscope, showing a pharyngeal filter. 


1mm 


Figure 7. Acletoxenus cf. indicus adult A lateral view B SEM with proboscis folded in, and C SEM showing 
a typical extended schizophoran proboscis. 


62 Wong Jinfa et al. / ZooKeys 725: 49-69 (2017) 


Figure 8. A Fourth instar of Aleurotrachelus trachoides, the prey of Acletoxenus cf. indicus and B adult 
Pachyneuron leucopiscida, the parasite of Acletoxenus cf. indicus. 


Figure 9. Acletoxenus sp. egg (left) found next to whitefly first instars (right). 


Acletoxenus cf. indicus could be considered a potential biological control agent for 
white flies given that the larvae consume 30 to 40 whitefly puparia during develop- 
ment (Pelov and Trenchev 1973). However, past attempts at using Acletoxenus for 


Whitefly predation and extensive mesonotum color polymorphism in an Acletoxenus... 63 


Table 3. Monthly parasitism rates. 


Nid Number of parasitized | Number of non-parasitized | Percentage of Parasitized 
puparium found puparium found Puparium 
May 2014 18 21 46.2% 
June 2014 16 13 55.2% 
July 2014 4 10 28.6% 


[> 


Movie 4. Pachyneuron leucopiscida emerging from parasitized Acletoxenus cf. indicus pupa. 


this purpose have failed (Clausen and Berry 1932, Vayssiére 1953) and although the 
reasons were never fully resolved, it has been suggested that extensive parasitism by 
Hymenoptera could be a contributing factor (Clausen and Berry 1932, Mentzelos 
1967, Pelov and Trenchev 1973). This explanation is partially supported by our 
data. A high parasitization rate was observed (mean = 43.3%; Table 3) that was 
caused by a pteromalid wasp (Fig. 8B; Movie 4). This wasp was identified as Pach- 
yneuron leucopiscida Mani, 1939. The same species had previously been recorded 
as a parasitoid of Acletoxenus indicus (Gupta & Poorani, 2009). The highest rate of 
parasitism in the Singapore population was in June while July saw a decrease in both 
the number of Acletoxenus that successfully emerged and the rate of parasitism. As 
the parasitism rates increased, the population of Acletoxenus cf. indicus declined and 
it crashed by August. 


64 Wong Jinfa et al. / ZooKeys 725: 49-69 (2017) 


Figure 10. Acletoxenus cf. indicus puparium A with green body, is usually B covered in whitefly wax and 


instars, and C translucent integument revealing red eyes of the developing adult at later stages. 


Life cycle of Acletoxenus cf. indicus 


Acletoxenus cf. indicus mean development time in Singapore was 24 days (Table 4). This 
is similar to the life cycle duration of European Acletoxenus formosus whose development 
time varies from 12 (Frauenfeld 1868) to 27 days (Pelov and Trenchev 1973). The mean 
lifespan of the adult flies was 12 days (Table 4). The Singapore population of Acletoxenus 
cf. indicus oviposits in the morning and afternoon and early instars of whiteflies are 
the initial prey while Clausen and Berry’s (1932) described oviposition by Acletoxenus 
indicus during midday. In Singapore, the eggs were laid singly and the number of eggs 
oviposited on one leaf varied from one to four. All eggs were white and firmly attached 
to the abaxial surface of the leaves (Clausen and Berry 1932; Fig. 9). The eggs are ap- 
proximately 0.45 mm in length and 0.2 mm in width with somewhat indistinct reticu- 
late markings; The eggs of the Singapore population are thus slightly bigger compared 
to the eggs of Acletoxenus indicus in Clausen and Berry (1932; 0.4 mm length). 


Table 4. Time spent in each life cycle stage of Acletoxenus cf. indicus. 


Stage Standard deviation 
Egg SYD) fl 
Larva 12.4 28 
Puparium 8.6 2.4 


Adult 4.8 


Acknowledgements 


We thank Mr. Ng Soon Hwee and Dr. Diego Pitta de Araujo who provided us advice 
and help with the microscopy work. ‘The project was supported by a MOE tier 2 grant 
(R-154-000-A22-112). 


Whitefly predation and extensive mesonotum color polymorphism in an Acletoxenus... 65 


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