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Zookeys 892: 143—160 (2019)

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The morphology of the immature stages of
Squamapion atomarium (Kirby, 1808)
(Coleoptera, Brentidae) and notes on its life cycle

Krzysztof Pawlega', Jacek Letowski', Ewelina Szwaj’, Tomasz Gostawski?

| Department of Zoology and Animal Ecology, University of Life Sciences in Lublin, Akademicka 13, 20-950
Lublin, Poland 2. Braci Wieniawskich 6/59, 20-844 Lublin, Poland 3 Putawskiego 8/51, 91-021 Lédz, Poland

Corresponding author: Krzysztof Pawlega (krzysztof.pawlega@up.lublin. pl)

Academic editor: M. Alonso-Zarazaga | Received 9 May 2019 | Accepted 19 October 2019 | Published 27 November 2019
http:/zoobank. org/F3F32E94-0AB7-49C4-A 108-162690F 122B4

Citation: Pawlega K, Letowski J, Szwaj E, Gostawski T (2019) The morphology of the immature stages of Syuamapion
atomarium (Kirby, 1808) (Coleoptera, Brentidae) and notes on its life cycle. ZooKeys 892: 143-160. https://doi.
org/10.3897/zookeys.892.36027

Abstract

The immature stages (egg, mature larva and pupa) of Squamapion atomarium (Kirby, 1808), as well as
its development cycle and the phenology of its developmental stages, are described for the first time. The
larva and pupa of S. atomarium have typical morphological features of the subfamily Apioninae. Morpho-
logical data on the immature stages were compared with the only fully described Squamapion species, S.
elongatum (Germar, 1817). The larvae of the two species differ in body size and shape, head shape, setae
length, the chaetotaxy of the mouthparts, and individual types of setae on the pronotum and thorax. In
the case of the pupa, there are also differences in body size and in the type of setae and chaetotaxy of the

head, pronotum, metanotum and abdomen.

Keywords
Apioninae, biology, central Europe, egg, host plant, life cycle, morphology, weevil

Introduction

The genus Sguamapion Bokor, 1923 belongs to the tribe Kalcapiini Alonso-Zaraza-
ga, 1990 in the subfamily Apioninae Schénherr 1823 and family Brentidae Billberg
1820. The adult morphology, ecology, distribution and systematics of the Apionidae

Copyright Krzysztof Pawlega 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.

144 Krzysztof Pawlega et al. / ZooKeys 892: 143-160 (2019)

family have been presented in detail by Alonso-Zarazaga (1990, 2011), Petryszak
(2004), Marvaldi and Lanteri (2005), Mokrzycki and Wanat (2005), Alonso-Zaraza-
ga and Wanat (2014) and Alonso-Zarazaga et al. (2017). The immature stages of
representatives of this family have been described by Scherf (1964), Letowski (1991),
Marvaldi (1999, 2003), Gosik et al. (2010), Wang et al. (2013), Oberprieler et al.
(2014), and Letowski et al. (2015). This genus is known from the Palearctic and
Ethiopian regions and is poorly represented in the Oriental region. There are 33
known species in the Palearctic region, 19 in Europe, and only 9 in Poland (Mokr-
zycki and Wanat 2005; Alonso-Zarazaga 2011; Alonso-Zarazaga et al. 2017). These
are herbivorous mono- or oligophagous species feeding on plants from the Lamiaceae
family, with a preference for the genera Salvia L., Thymus L., Thymbra L., Mentha L.,
Origanum L., Prunella L. and Saccocalyx Coss. & Durieu. Their larvae bore tunnels
inside the roots and stems, occasionally causing galls (Alonso-Zarazaga 1990). Adults
have a small body size ranging from 1.10 to 2.70 mm. They are found mainly in dry
and thermophilic environments — in non-forested areas and on the edges of forests
and bushes (Burakowski et al. 1992).

The biology of only one species and the morphology of its immature stages are
known — Squamapion elongatum (Germar, 1817) (Letowski et al. 2015).

This study is a continuation of research on representatives of this genus found
in Poland. The authors describe the morphology of the third larval instar and pupa
as well as issues concerning the development and ecology of Squamapion atomarium
(Kirby, 1808).

According to the literature, this species prefers warm, sandy areas and is usually
found in xerothermic grasslands (Burakowski et al. 1992). Its host plants are Breckland
thyme (Zhymus serpyllum L.) and broad-leaved thyme (7! pulegioides L.). As regards its
biology, S. atomarium feeds on the upper part of the stem of these plants, causing oval
cecidia 2-4 mm long and 2 mm wide (Burakowski et al. 1992).

Material and methods

Insect collection

The research material comprised developmental stages (egg, larvae, and pupa) of S.
atomarium, isolated in the laboratory from field-collected plants described in the lit-
erature as hosts. The choice of study sites was based on faunistic data on the occur-
rence of S. atomarium as well as our own observations of potential habitats in the Lu-
blin region of Poland (Cmoluch 1963, 1971, 1987, 1992; Gosik and Letowski 2003;
Letowski et al. 2003; Letowski 2008). The sites were as follows: 1. Okale near Kazimi-
erz Dolny (51°18'11.0"N, 21°53'58.6"E), 2. Bochotnica (51°20'38"N, 22°00'05"E),
3. Lublin-Gérki Czechowskie (51°15'47"N, 22°32'03"E), 4. Lublin (51°13'11.50"N,
22°32'04.38"E), 5. Trzesni6w near Lublin (51°16'20"N, 22°37'04.10"E), 6. Kolo-
nia Pliszczyn (51°17'38"N, 22°37'38"E), 7. the Stawska Géra Reserve near Chetm

The morphology of the immature stages of Squamapion atomarium 145

(51°22'23"N, 23°24'11"E) and 8. the Zmudz Reserve (51°00'35"N, 23°40'14"E). Im-
mature stages of S. atomarium were found at sites 3, 5 and 8. In the remaining sites, de-
spite the presence of host plants, no specimens were found. ‘The material was collected
from May to August 2016 and 2017. To obtain immature stages of the species, plants
were collected at the sites every 2—3 days. This frequency made it possible to study the
development cycle of the species in its natural conditions. Breeding was also conducted
in the laboratory. Sguamapion atomarium adults were collected individually, directly
from the host plant and from its immediate surroundings.

Breeding

Adult specimens were placed in plastic containers covered with mesh — separately for
LT. serpyllum L. and. T’ pulegioides L. Wet filter paper was placed on the bottom of the
containers to maintain a suitable moisture level, together with thyme. The stems were
searched for signs of oviposition and eggs about every three days. Then immature stages
were grown in Petri dishes in a growth chamber, in the following conditions: daytime
minimum 25 °C, daytime maximum 35 °C, minimum at night 15 °C, maximum at
night 20 °C, humidity (60%), light duration — day 14 h, night 10 h. Immature stages
were also grown in 125 ml plastic containers stored under room conditions (25 °C
with a 14:10 photoperiod). Filter paper soaked in water was placed on the bottom of
the container to maintain moisture, together with thyme stems with galls. The closed
containers were monitored daily for mould. This method produced better results in
terms of larvae survival than the use of the Petri dishes proposed by Scherf (1964). In
order to track development and acquire larval stages, 5 stems were randomly selected,
the galls were cut open, and developmental stages were isolated from them.

Morphological descriptions

The immature stages obtained by the methods described above were preserved in 70%
ethyl alcohol. Two methods were used to prepare microscope slides, as described by
Letowski (1991) and Gosik et al. (2010). To prepare the drawings, we used an OLYM-
PUS SZX12 and DP72 microscope at magnifications from 200x to 400x and a TES-
CAN VEGA3LMU scanning electron microscope (SEM) at magnifications from 500x
to 2000x. The larvae for SEM images were subjected to critical point drying (CPD).
Drawings based on the slides were made using Corel Draw 18.

The terminology of Marvaldi (1999, 2003) and Oberprieler et al. (2014) was used
in the morphological descriptions of the larva and pupa for chaetotaxy, and the ter-
minology of Zacharuk (1985) and Marvaldi (1998) for antennae. The number and
distribution of setae are given for one side. Measurements of the head (following de-
capitation) were made on the head capsule, isolated from the body, with the mandibles
closed. Measurements were made of 10 3 4 A152, and 10 pupae. The larvae were

146 Krzysztof Pawlega et al. / ZooKeys 892: 143-160 (2019)

not separated by gender for the measurements. The mean and standard deviation for
each parameter were calculated using Excel.
An analysis was made of the growth of the heads of individual larval instars based on

Dyar’s law (1890), and the growth rate (GF) was determined based on Bednarz (1953).

Morphological abbreviations
AbI, AbVII, AbVIII, AbDIX, AbX — abdominal segments 1, 7-10, ThI, ThII, ThIII

— thoracic segments 1—3, prns pronotal setae, pda pedal s., ps pedal s., eus eusternal
s., Usts laterosternal s., prs prodorsal s., pds postdorsal s., as alar s., ss spicular s., eps
epipleural s., ds dorsal s., les lateral epicranial s., fs frontal s., des dorsal epicranial s.,
pes posterior epicranial s., at antenna, Se sensorium, sb sensillum basiconicum, ss
sensillum styloconicum, oc ocellus, ene endocarina. lrms labral setae, cls clypeus s.
ams anteromedial s., ads anterolateral s., mes median s., /r labral rods., mds — dorsal
malae s., dms dorsal maxillary s., pfs palpiferal s., sts stipal s., mpxs maxillary palp s.,
mbs malar basiventral s., prms prelabium s., pms postlabium s., /gs ligular s., lbp labial
palpus, as apical setae, Js lateral s., pls posterolateral s., sos suborbital s., 7s rostral s.,
fes femoral s., ur urogomphi.

Results

Description of egg
Fig. 1

Measurements (in mm, NV = 5). Length 0.28 (0.22—0.31), width 0.18 (0.15—0.20).
General. Egg elliptical, shiny, smooth. Chorion soft, delicate (Fig. 1).
Colouration. Pale to dark yellow.

Description of larva

Figs 2-6

Measurements (in mm). First larval instar (L,) — body length 0.46 (0.39—-0.55), width
0.21 (0.19-—0.23). Head width 0.13 (0.12-0.14).

Second larval instar (L,) — body length 0.68 (0.64—0.74). Body widest at abdomi-
nal segment III (0.34). Average pronotum width 0.27 (0.15—0.21). Head width 0.19
(0.17—0.21). Stemmata present.

Mature larva (third instar, L,) — body length 1.36 (1.09-1.72). Body widest at ab-
dominal segment III (0.66, 0.50—0.86). Width of pronotum 0.47 (0.40—0.55). Head
width 0.33 (0.30—0.38).

The morphology of the immature stages of Squamapion atomarium 147

Figure |. Ege of Sguamapion atomarium.

General Ly Cylindrical, C-shaped, pale yellow with no distinct sclerotizations
(Fig. 2). Cuticle microstructure of entire body with many small, sharply pointed cu-
ticular structures. Thoracic and abdominal segments with characteristic, short setae.
Body much narrower after abdominal segment VIII.

Head (Fig. 3). Pale yellow, later dark yellow, slightly hidden in prothorax, longer
than wide, slightly egg-shaped, widest at 2/5 of length. Epicranial suture visible. Endo-
carina (enc) distinct, long, together with epicranial suture extends 3/4 length of head
(Fig. 3). End of frontal suture with distinct stemmata. Antennae (az) without articula-
tions. Sensorium (Se) long, slightly narrowing apically. Antenna with 4 sensillae: 2 sb
(sensillum basiconicum) and 2 ss (sensillum styloconicum) (Fig. 3). Epicranium with 2

148 Krzysztof Pawlega et al. / ZooKeys 892: 143-160 (2019)

. Prodorsum

. postdorsum

0.01mm
——|

sternum .” }-
f:
pleurum

Ab X

a Ab VII
a
Ab IX Ab VIII

1.0 mm

ee

Figure 2. Mature larva (L,) of Sguamapion atomarium, lateral view.

lateral epicranial setae (/es1,2). Les] more than 4 times longer than /es2. Dorsal part of
epicranium with 5 visible dorsal setae (des1—5), des1,3—5 situated more or less along
frontal suture, des2 on extension of line of pes (Fig. 3). Des3 very long, des4 very short
and des1,2,5 short and more or less equidistant. Epicranium with 4 thorn-shaped pos-
terior epicranial setae posterolaterally (pes /—4) —very short and more or less equidistant.
Frons with 4 frontal setae (fs1,3—5) (Fig. 3). Fs1,3 short (shortest of all fs), fs/ situated
by endocarina at about 1/3 length of frons, fs3 situated outermost of all fs, close to fs4.
Setae fs4 long — longest of all fs. Setae fs5 slightly above anterior margin of stemmata.
Mouthparts. Labrum — anterior margin slightly arched. Dorsal side with 3 thorn-
shaped labral setae (/rms), of which /rms2 long and longer than others; /rms, closer
to centre, below mid-height of labrum, /rms2 and /rms3 anterolaterally (Fig. 4a).
Epipharynx anteriorly with 2 anteromedial setae (ams), of which medial ams/ finger-
shaped, outer setae ams2 thorn-shaped (Fig. 4b). Beside ams, 2 als on epipharynx,
arranged more or less diagonally from corner to centre of labrum. A/s/ slightly shorter
than a/s2. Both wider at base and narrowing apically. Mes digitiform and placed an-
tero-medially. Labral rods (/r) present, long, extending well beyond suture (Fig. 4a).
Clypeus kidney-shaped, with slightly concave anterior margin. 1 short seta c/s at lower
margin, between them 1 sensillum (céss) (Fig. 4a). Mandible massive, highly scleroti-
zation, light to dark brown in colour. Two teeth equal in size, curved. Dorsally 1 pair
mandible dorsal setae (mds1,2) and 1 sensillum (Fig. 5). Setae close together, one
above the other, each sensilla peripherally. /ds2 more than twice longer than mds1.

The morphology of the immature stages of Squamapion atomarium 149

0.025 mm

Figure 3. Squamapion atomarium (L,), — epicranium, dorsal view.

Inner margin of inner teeth serrated. Maxillary stipes elongated, widening apically,
narrowed at mid-length, with 4 distinct, hair-like setae (Fig. 6). In lower part 1 stipal
seta (stps). In the upper part palpiferal setae pfs/ fairly short, placed centrally under
maxillary palpus, pfs2 very long, placed on inner side, basioventral seta (mbs) short.
Maxillary palpus (mp) 2—segmented, distal segment cylindrical, smaller than basal
segment, with 10 nodular cuticular tubercles situated apically. Basal segment with
rod-shaped sensorium, 1 minute maxillary palp seta (mpxs) and 1 pore. Malar part of
maxilla with 7 dorsal maxillary setae (dms1—4, vms1—3) clearly visible, finger-shaped
setae of equal length in comb-like arrangement.

Labium cup-shaped (Fig. 6). Base of prementum rounded. Postmentum with 3
pairs postmental setae (pms1—3), distributed evenly, one over the other, closer to outer
part of postmentum, more or less parallel to its edges. First pair setae (pmsJ) situated
closest to lower margin, shortest of all pms. Above it pms2, very long and longest of
pms, thick, narrowing only at apex. Setae pms3 situated at 2/3 height of labium, similar
in structure to pms2 but half their length. Labium with Y-shaped premental sclerite
situated centrally. 1 pair sensilla at base of arms of this structure. At height of premen-
tal sclerite, dorsally, chitinized inverted comma-shaped labial rods with uneven edges.

150 Krzysztof Pawlega et al. / ZooKeys 892: 143-160 (2019)

4a

4b 10yum

Figure 5. Squamapion atomarium (L,) — mandibulae.

Labium with 1 pair simple palpi (/bp), with 7 palpillae apically, 1 inner seta at base and
1 outer sensillum. In front of palpi 1 pair long premental setae (prms). Behind palpi 2
pairs very short ligular setae (/gs) and 1 pair sensilla (Fig. 6).

The morphology of the immature stages of Squamapion atomarium 151

labium rod

premental sclerite

/dms1-Z, sensorium

Figure 6. Labium and maxillae (L,) of Squamapion atomarium.

Thorax. Thoracic segments with well visible pedal area. Thoracic setae longer than
others. Prothorax with 7 pronotal setae varying in length (prns), 1 pleural seta (ps) and
on pedal area 3 pedal setae (pda) (Fig. 2). Meso- and metathorax each with 1 relatively
long prodorsal seta (prs), 2 postdorsal setae (pds), 3 alar setae (as), 3 spicular setae (ss), 3
pda on pedal area and 1 short eusternal seta (ews). Thoracic spiracle bicameral, located
intersegmentally, between Th.I and Th.II (Fig. 2).

Abdomen. Tergites I-VI with 2 folds and 1 seta (prs) on prodorsum. Postdorsum
with 2 pds and 2 ss of varying size; 1 epipleural seta (eps) slightly below ss. Pleurum with
1 ps. Sternum with 1 laterosternal seta (dts). Tergit VIII with gentle folds and with 1
p7s 1 dorsal seta (ds) and 1 eps. Tergit [X without folds, with 1 dsand 1 ps. Sternum and
pleurum of segments VHI-IX with 1 ps and 1 dts. Segments I-VII with unicameral
spiracles, others without spiracles (Fig. 2).

Description of pupa
Figs 7-10

Measurements (in mm). Body length 1.51 (1.24-1.63), width 0.84 (0.72-0.93)
(Figs 7-10).

152 Krzysztof Pawlega et al. / ZooKeys 892: 143-160 (2019)

" spiracle

1.0 mm

Figures 7-9. Pupa of Sqguamapion atomarium 7 ventral view 8 dorsal view 9 lateral view.

The morphology of the immature stages of Squamapion atomarium 153

Figures 10-15. Sguamapion atomarium \0 pupa II occurrence environment 12 a gall 13 the most com-

mon place to lay eggs at the root collar 14 place for laying eggs 15 larva in prepupal stage for pupation.

Colouration. Colour creamy-white.

Head. Eyes large, with 1 supraorbital seta (sos) between them. Rostrum long, ex-
tending to end of tarsi of mesolegs, not very wide, with 1 rostral seta (7s) below base of
antennae, shorter than sos. Antennae relatively long, club with conical papillae. Anten-
nae sub-parallel to protibia (Figs 7, 9).

Thorax. Pronotum wider than long; sides with 2 lateral setae — long /sJ and shorter
/s2; 1 apical seta on apex (as), half length of /s/ (Figs 7, 8); lower margin with 2 poste-
rolateral setae (p/s1,2), similar in length to as]. Mesonotum without setae. Metanotum
with 2 setae, slightly shorter than /s/ (Figs 8, 9). Each femur with 1 femoral seta (fes)
on convex base (Figs 8, 9).

Abdomen. Chaetotaxy very sparse. Each segment with 1 short dorsal seta located
close to lateral margin. Each of lateral parts of abdominal segments I—VII with 1 pair

154 Krzysztof Pawlega et al. / ZooKeys 892: 143-160 (2019)

minute lateral setae. Spiracles located between tergites and pleurites, clearly visible on
segments I—VI, on others absent (Fig. 9). Segment [X terminally with 1 pair urogom-
phi (ur) with characteristic ends in form of flattened bifurcation (Fig. 7).

Notes on biology and life cycle
Figs 11-17

Host plant. The life cycle of S. atomarium was described based on field data and laboratory
observations. Thymus serpyllum and T. pulegioides were confirmed as host plants (Fig. 11).
Life cycle. Adults, following overwintering and maturation feeding, begin copula-
tion and egg laying in the first half of May. Increased egg laying was observed at the
end of May, and single eggs were still noted in early June. Adults usually feed in the
evening, by gnawing round holes in the leaf that do not exceed 1 mm in diameter. The
fertilized female gnaws a cavity in the stem and lays one egg in it (Fig. 12). Oviposition
takes place primarily at the root collar, but it was also observed up to the fourth or
fifth node, in both nodes and internodes (Fig. 13). After laying the egg the female does

not seal the site with any secretion. ‘The first instar larva (L,) hatches on average 4 days

16

Figure 16. Life cycle of Sguamapion atomarium.

The morphology of the immature stages of Squamapion atomarium 155

Figure | 7. Larva ofa chalcidoid endoparasitoid found inside the mature larva (L,) of Squamapion atomarium.

after the egg is laid and moults after 10—12 days. The L, instar was observed as early as
mid-May, but these were isolated specimens. Maximum emergence was observed from
the second third of May. L, larvae were found until mid-June. The second larval instar
(L,) appeared at the end of May. The activity of L, larvae causes distinct galls about
1.32 mm long and about 0.75 mm wide. Furthermore, L, gnaws out an opening for
oviposition on the opposite side of the groove, but does not gnaw through the skin.
The second larval instar lasts on average 10 days, and then the larva moults again. I,
larvae appeared as early as the last third of June and were noted until mid-July. The
average duration of this stage is about 11 days. This stage continues feeding and the gall
grows, reaching on average about ca 2.31 in length and ca 1.70 mm in width (Fig. 14).
The third larval instar enlarges the opening in the stem. Then pupation takes place
(Fig. 15). The pupal stage lasts 2-3 days on average. The first pupae appeared at the end
of June. Finally, at a maximum 40 days after the egg is laid, adult individuals appear.
An increase in the emergence of adults took place from mid-July. The entire life cycle
of S. atomarium is presented in the diagram in Figure 16.

Parasitoids. In the second half of July, endoparasitic hymenopterans of the super-
family Chalcidoidea were very active, which is manifested by the high level of parasitism
of L, larvae. On average 7 of 10 third-instar larvae exhibited symptoms of parasite infec-
tion: dark red discolouration on the thoracic tergites and pleurites and swelling of the ab-

156 Krzysztof Pawlega et al. / ZooKeys 892: 143-160 (2019)

dominal segments caused by the growth of the intruder larvae (Fig. 17). The mature larva
of the parasitoid usually occupied the space from the second or third thoracic segment to
the eighth abdominal segment. The adult larva of the parasite is ca 0.75 mm long and ca
0.56 mm wide. The body of the pupa of the parasitoid is black with a metallic sheen and
well chitinized. The parasites brought about the death of L, of S. atomarium.

Head growth of larval instars and growth factor (GF)
Figs 18, 19

Deviations of the mean dimensions of the heads of individual larval stages from the
theoretical dimensions are shown in Figures 18, 19. Analysis of the ratios of the head
sizes of larval instars does not clearly result in a single growth factor. GF between L,

and L, is 1.43 and between L, and Ee itis: 1.75:

0,5

0,25 ==@= actual averages

—— theoretical averages

L1 L2 L3

Figure 18. Mean real and average theoretical head lengths of Sqguamapion atomarium larval stages.

0,45

—= actual averages

=f theoretical averages

L1 L2 L3

Figure 19. Mean real and average theoretical head widths of Sguamapion atomarium larval stages.

The morphology of the immature stages of Squamapion atomarium 157

Discussion

Among species of the genus Sguamapion, only S. elongatum (Germar, 1817) has previ-
ously been described, and the existing data on S. atomarium concern only its habitat and
host plants, with an equal role ascribed to 7’ serpyllum and T. pulegioides (Burakowski
et al. 1992; Letowski et al. 2015). The present study has shown that the preferred plant
species is broad-leaved thyme (T' pulegioides), on which more galls were observed. ‘This
is most likely linked to the environment inhabited by S. atomarium, where this species
of thyme is more common. Another new observation is the site of oviposition and galls.
According to Burakowski et al. (1992), the larva feeds on the upper part of the stem. In
the present study, the eggs were usually laid in the lower part of the stem.

The morphology of the L, larva and pupa of S. atomarium does not differ from
the typical characters of the subfamily Apioninae (Alonso-Zarazaga and Wanat 2014).
These features are the strongly convex and C-shaped body, colour, subglobose head,
coronal suture and endocarinal line, clearly visible stemmata close to the frontal su-
ture; numbers of des, /es and fs; transverse and trapeziform clypeus with one pair of c/s
and one pair of css; chaetotaxy of the labrum and epipharynx; mandible chaetotaxy;
morphology and chaetotaxy of the maxilla and labium; thoracic segments with a pro-
dorsum and postdorsum; very small prodorsum of the pronotum; morphology and
chaetotaxy of the pro-, meso- and metanotum, except the number of as, with three
pairs in S. atomarium; mesothoracic spiracles on the membrane between the pro- and
mesothorax; and the abdominal morphology and chaetotaxy, except for the presence
of dsts on the 8" abdominal segment in S. atomarium.

Thus the immature stages of the species are generally very similar in their mor-
phology to those described by Letowski (1991) for Synapion ebeninum (Kirby, 1808),
Stenopterapion intermedium (Eppelsheim, 1875) and Metatrichapion reflexum (Gyllen-
hal, 1833), by Gosik et al. (2010) for Diplapion confluens (Kirby, 1808), or by Wang
et al. (2013) for Pseudaspidapion botanicum Alonso-Zarazaga & Wang, 2011. Squa-
mapion atomarium was also confirmed to possess an apomorphic trait of Apioninae
emphasized by Marvaldi (2003), namely a lack of spiracles beginning in the eighth
abdominal segment. ‘There are differences in body size and in the number and distribu-
tion of setae (see Letowski et al. 2015).

In the comparative analysis of the egg and L, larva of S. atomarium and S. elonga-
tum, the two species are distinguished by differences in the size of both the egg and the
L, larvae — in S. atomarium they are about half the size as in S. elongatum (Letowski
et al. 2015). Similar differences are found in the width of the epicranium of the two
species, the shape of the head, and some features of their chaetotaxy. The differences
are presented in Table 1.

The case of the pupa is similar. There are clearly visible differences between species in
body size and chaetotaxy. The body of the pupa of S. atomarium is shorter than that of
S. elongatum (1.5—2.0 times) and has far fewer abdominal setae (Table 2). There are also
minor differences in body colour. Similar proportions of body length are found in adults.

The study and descriptions of additional species of the genus Sqguamapion will
make it possible to distinguish and describe its generic characters.

158 Krzysztof Pawlega et al. / ZooKeys 892: 143-160 (2019)

Table |. Character comparison between L, Sguamapion atomarium and Squamapion elongatum.

Trait Species
Squamapion atomarium Squamapion elongatum
Body mm (length/width) ca 1.36/ca 0.66 ca 2.78/ca 1.24
Setae shorter, with pointed ends longer
Head slightly egg-shaped oval
Antennae 4 sensilla 2 sensilla

Number of setae on |basal 1 seta, 1 sensillum 1 seta, 2 sensilla

maxillary palpus segment
distal 1 short sensillum
segment
Labrum/epipharynx 3 pairs(ams1—3)
als 2 pairs 3 pairs
lr large, widening towards outer margin of epipharynx narrow
Labium with pms 3 pairs(pms1—3) 2 pairs(pms1 and pms3)
Number of conical papillae dms 4 5

Number of setae prs on pronotum 7 )
Number of setae pda 3 2
2 3

Number of setae ss

Table 2. Character comparison between the pupa of Sguamapion atomarium and Squamapion elon-

gatum.
Trait Species
Squamapion atomarium Squamapion elongatum
Body mm (length/width) ca 1.51/ca 0.84 ca 2.67/ca 0.94
Colour creamy-white whitish-grey
Head setae 1 pair sos, 1 pair rs 1 pair vs, 1 seta rs
Pronotum 1 pair as (asl), 2 pairs bs (ds1,2) 2 pairs as (as1,2), 1 pair ds
Metanotum 2 pairs of setae 3 pairs of setae
lateral part only 1 pair of setae of I-VII abdominal segments absent
AbI-III: 7 pairs,
Abdomen AbIV-VI: 5 pairs,
dorsal part absent AbVIL 3 = iis,
AbVIII: 1 pair
Urogomphi flattened bifurcation, straight crescent-shaped, narrow

Analysis of the growth rate and the ratio of actual and theoretical average head
sizes produced some discrepancies that may have been influenced by the fact that the
individuals were not divided by sex or collection site, and thus may have represented
different populations.

Acknowledgements

The authors would like to thank Professor Bernard Staniec and Jarostaw Pawelec of
the Maria-Curie Sktodowska University in Lublin for allowing us to take photos us-
ing scanning electron microscopy and the CPD procedure. The authors would like to
thank the English native Sara Wild — for the correction of the manuscript.

The morphology of the immature stages of Squamapion atomarium 159

References

Alonso-Zarazaga MA (1990) Revision of the supraspecific taxa in the Palaearctic Apionidae
Schoenherr, 1823 (Coleoptera, Curculionoidea) (2. Subfamily Apioninae Schoenherr,
1823: Introduction, keys and descriptions. Graellsia 46: 19-156.

Alonso-Zarazaga MA (2011) Apionidae. In: Lobl I, Smetana A (Eds) Catalogue of Palaearctic
Coleoptera (Vol. 7). Stenstrup, Apollo Books, 373 pp.

Alonso-Zarazaga MA, Wanat M (2014) Apioninae Schoenherr, 1823. In: Leschen RAB, Beu-
tel RG (Eds) Handbook of Zoology/ Handbuch der Zoologie, Band 4: Arthropoda, 2.
Halfte: Insecta, Coleoptera, Beetles (Vol. 3). Morphology and Systematics (Phytophaga).
De Gruyter, Berlin, Boston, 395-415.

Alonso-Zarazaga MA, Barrios H, Borovec R, Bouchard P, Caldara R, Colonnelli E, Giiltekin L,
Hlava P, Korotyaev B, Lyal CHC, Machado A, Meregalli M, Pierotti H, Ren L, Sanchez-
Ruiz M, Sforzi A, Silfverberg H, Skuhrovec J, Tryzna M, Velazquez de Castro AJ, Yunakov
NN (2017) Cooperative catalogue of Palaearctic Coleoptera Curculionoidea. Monografias
electrénicas S.E.A. (Vol. 8), 729 pp.

Bednarz S (1953) Wzrost glowy larw Tettigonia viridissima (Saltatoria, Tettiginiidae) a hipoteza
Dyara. Polskie Pismo Entomologiczne, Warszawa, T. XXIII, 14: 191-203.

Burakowski B, Mroczkowski M, Stefariska J (1992) Katalog Fauny Polski. Cz. XXIII, T. 18.
Chrzaszcze — Coleoptera. Ryjkowcowate précz ryjkowcéw — Curculionioidea précz Curcu-
lionidae. Wydawnictwo Muzeum i Instytut Zoologii PAN, Warszawa, 324 pp.

Cmoluch Z (1963) Badania nad fauna ryjkowcéw (Coleoptera, Curculionidae) roslinnych
zespotéw kserotermicznych poludniowo-wschodniej czesci Wyzyny Lubelskiej. Annales
Universitatis Mariae Curie-Sklodowska, sectio C 17(1): 1-75.

Cmoluch Z (1971) Studien iiber Riisselkafer (Coleoptera, Curculionidae) xerothermer Pflanze-
nassoziationen der Lubliner Hochebene. Acta Zoologica Cracoviensia 16: 29-216.

Cmoluch Z (1987) Ryjkowce (Coleoptera, Curculionidae) roslinnych zbiorowisk kseroter-
micznych Biatej Géry kolo Tomaszowa Lubelskiego. Annales Universitatis Mariae Curie-
Sktodowska, sectio C 39: 187-197.

Cmoluch Z (1992) Riisselkafer (Coleoptera, Curculionidae) von Polesie Lubelskie. Annales
Universitatis Mariae Curie-Sklodowska, sectio C, 44 — 1989: 1-64.

Dyar HG (1890) The number of molts of lepidopterous larvae. Psyche 5: 420-422. https://doi.
org/10.1155/1890/23871

Gosik R, Letowski J (2003) Ryjkowcowate (Curculionoidea: Rhinomaceridae, Attelabidae, Ap-
ionidae, Curculionidae) uzytku ekologicznego ,,Biala Gora’. Parki Narodowe i Rezerwaty
Przyrody 21(2): 247-266.

Gosik R, Letowski J, Kozak E (2010) Morphology of the mature larva and pupa of Diplapion con-
fluens (Kirby, 1808) (Coleoptera: Apionidae). Polish Journal of Entomology 79: 211-221.

Letowski J (1991) Morfologia i biologia trzech gatunkdéw z rodzaju Apion Herbst (Apionidae,
Coleoptera) uszkadzajacych sparcete siewna (Onobrychis viciaefolia Scop.). Wydawnictwo
Uniwesytetu Marii Curie-Sktodowkiej, 95 pp.

Letowski J (2008) The weevils (Curculionoidea) of calcacerous habitats of the vicinity of Chetm.
Teka Komisji Ochrony i Ksztaltowania Srodowiska Przyrodniczego OL PAN 5: 5-125.

160 Krzysztof Pawlega et al. / ZooKeys 892: 143-160 (2019)

Letowski J, Gosik R, Czarniawski W, Budzyriska E (2003) Materiaty do znajomosci ryjkow-
cowatych (Curculionoidea, Coleoptera) Kazimierskiego Parku Krajobrazowego. Parki Naro-
dowe i Rezerwaty Przyrody 22(2): 227-245.

Letowski J, Pawlega K, Scibior R, Rojek K (2015) The morphology of the preimaginal stages
of Sguamapion elongatum (Germar, 1817) (Coleoptera, Curculionoidea, Apionidae) and
notes on its biology. ZooKeys 519: 101-115. https://doi.org/10.3897/zookeys.519.9134

Marvaldi AE (1998) Larvae of Entiminae (Coleoptera: Curculionidae): tribal diagnoses and
phylogenetic key, with a proposal about natural groups within Entimini. Entomologica
Scandinavica 29: 89-98. https://doi.org/10.1163/187631298X00212

Marvaldi AE (1999) Morfologia larval en Curculionidae (Insecta: Coleoptera). Acta Zooldégica
Lilloana 45(1): 7—24.

Marvaldi AE (2003) Key to larvae of the South American subfamilies of weevils (Coleop-
tera: Curculionoidea). Revista Chilena de Historia Natural 76: 603-612. https://doi.
org/10.4067/S0716-078X2003000400005

Marvaldi AE, Lanteri AA (2005) Key to higher taxa of South American weevils based on adult
characters (Coleoptera, Curculionoidea). Revista Chilena de Historia Natural 78: 65-87.
https://doi.org/10.4067/S0716-078X2005000100006

Mokrzycki T, Wanat M (2005) A new checklist of the weevils of Poland (Coleoptera: Curculio-
noidea). Genus 16(1): 69-117.

Oberprieler RG, Anderson RS, Marvaldi AE (2014) Curculionoidea Latreille, 1802: Introduc-
tion, Phylogeny. In: Leschen RAB, Beutel RG (Eds) Handbook of Zoology (Vol. 3), Walter
de Gruyter GmbH, Berlin, Boston, 285-300.

Petryszak B (2004) Curculionoidea. In: Bogdanowicz W, Chudzicka E, Pilipiuk I, Skibiniska
E (Eds) Fauna of Poland. Characteristics and Checklist of Species. Museum i Instytut Zo-
ologii PAN (Vol. I). Warszawa, 509 pp.

Scherf H (1964) Die Entwicklungsstadien der mitteleuropaischen Curculioniden (Morpholo-
gie, Bionomie, Okologie). Verlag Waldemar Kramer, Frankfurt am Main, 335 pp.

Wanat M (1997) New and little known Sguamapion species (Coleoptera: Apionidae) from
western Palaearctic. Annales Zoologici 47(1/2): 285-295.

Wang Z, Alonso-Zarazaga MA, Zhou D, Zhang R (2013) A description of preimaginal stages of
Pseudaspidapion botanicum Alonso-Zarazaga & Wang, 2011 (Apionidae, Curculionoidea).
ZooKeys 260: 49-59. https://doi.org/10.3897/zookeys.260.4450

Zacharuk RY (1985) Antennae and sensilla. In: Kerkut GA and Gilbert LI (Eds) Comparative
Insects Physiology, Pergamon Press, Oxford, Chemistry and Pharmacology 6: 1-69.