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Zookeys 807: 29-46 (2018)

doi: 10.3897/zookeys.807.28365 RESEARCH ARTICLE #Zookey S

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The morphology of the preimaginal stages of
Rhinusa neta (Germar, 1821) and notes on its biology
(Coleoptera, Curculionidae, Mecinini)

Radostaw Scibior', Jacek Letowski!

| Department of Zoology, Animal Ecology and Wildlife Management, University of Life Sciences in Lublin,
Akademicka 13, 20-950 Lublin, Poland

Corresponding author: Radostaw Scibior (radoslaw.scibior@up.lublin.pl)

Academiceditor: M.. Alonso-Zarazaga | Received 13 July 2018 | Accepted 26 October 2018 | Published 17 December 2018
http://zoobank. org/E55F8E54-EA9A-4F75-9F63-B54E669C2968

Citation: Scibior R, Letowski J (2018) The morphology of the preimaginal stages of Rhinusa neta (Germar, 1821)
and notes on its biology (Coleoptera, Curculionidae, Mecinini). ZooKeys 807: 29-46. https://doi.org/10.3897/
zookeys.807.28365

Abstract

A detailed description of the mature larva and pupa of Rhinusa neta (Germar, 1821) and new diagnostic
features of this species are presented. The development cycle of R. neta in the standard conditions lasts
almost 60 days: an 11-day egg period, a 29-day larval period, and an 18-day pupal period, on average. The
larvae are parasitised by hymenopterans of the superfamily Chalcidoidea. Similarities and differences with

Rhinusa bipustulata and other species of this genus are presented.

Keywords

Egg, host plant, life development, Linaria vulgaris, mature larva, parasitoid, Plantaginaceae, pupa, weevil

Introduction

The taxon Rhinusa attained the rank of the genus based on the classification made by
Caldara (2001). It belongs to the tribe Mecinini and includes 40 species around the
world (Caldara et al. 2014). In Poland, ten species have thus far been recorded (Pet-
ryszak 2004; Mokrzycki and Wanat 2005), of which two, R. hispida (Brullé, 1832) and
R. thapsicola (Germar, 1821), were recognised by Caldara (2013) as synonymous with

Copyright R. Scibior, J. tetowski. 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.

30 R. Scibior & J. Letowski / ZooKeys 807: 29-46 (2018)

R. tetra (Fabricius, 1792). The known host plants of Rhinusa species include plants only
from the families Plantaginaceae and Scrophulariaceae (Caldara et al. 2010; Caldara et
al. 2014; APG 2016). Weevils inhabit mainly warm habitats, such as pastures, sunlit
slopes, sandbars, gravel pits, uncultivated strips between fields, roadsides, etc. (Koch
1992; Burakowski et al. 1997). Till now the data on the morphology and biology of
preimaginal stages (in varying degrees of detail) are available for the following species:
R. asellus (Gravenhorst, 1807), R. antirrhini (Paykull, 1800), R. bipustulata (Rossi,
1792), R. collina (Gyllenhal, 1813), R. Linariae (Panzer, 1795), R. neta, R. pilosa (Gyl-
lenhal, 1838) and R tetra (Emden 1938; Scherf 1964; Anderson 1973; Burakowski et
al. 1997; Gosik 2010a; Gassmann et al. 2014).

Rhinusa neta is a species distributed mainly in southern and central Europe, also
noted in Belgium, the Caucasus, Afghanistan, Kazakhstan, Iran, Algeria, and Morocco
(Burakowski et al. 1997, Caldara 2013). In Poland, it is found in twelve geographical
realms in the lowlands and highlands (mainly in central and eastern Poland), as well as
in some lower locations in the Eastern Sudetes and the Eastern Beskids. It inhabits dry,
warm places in fields and on fallow land, roadsides, gravel pits, moors and rock faces,
as well as in sunny thickets. It develops on Linaria vulgaris (L.) Mill., L. genistifolia (L.)
Mill., L. repens (L.) Mill., L. spuria (L.) Mill., Antirrhinum orontium L. and A. majus
L. (Plantaginaceae). Adults are active on plants from May to August. The larva feeds
inside seed capsules on immature seeds (Smreczynski 1976, Burakowski et al. 1997).
Feeding by the larvae does not cause swelling in the seeds, as in the case of feeding
by the larvae of R. antirrhini. In North America, in laboratory conditions, it has also
fed on species of the genera Chaenorrhinum and Kickxia (Plantaginaceae), but in field
conditions only on L. vulgaris and L. dalmatica (Wilson et al. 2005).

Rhinusa neta was introduced to the United States in 1937 and to Canada in 1957,
and from the late 1950s, it was used in both countries for biological control of two
species of toadflax (L. vulgaris and L. dalmatica). The primary host plant for R. neta
in North America is L. dalmatica and the secondary host plant is L. vulgaris. R. neta is
much less common in these countries and is found in more dispersed populations than
the morphologically very similar R. antirrhini. When both species feed on Linaria at
the same time, seed losses may reach 90% (Wilson et al. 2005).

The aim of present paper is to describe development stages (mature larva L, and
pupa) of Rhinusa neta and collect a new diagnostic features of this species. Some data
about biology are also presented.

Materials and methods
Collection in the field
Samples with flowering and fruiting Linaria vulgaris plants were collected from June

to August in 2014-2016 in the following locations in the Lublin Upland (south-
eastern Poland): Garbéw (51°22'15.91"N, 22°21'25.82"E), unplowed strip between

The morphology of the preimaginal stages of Rhinusa neta oa

fields; Lublin (51°13'39.15"N, 22°38'31.43"E), lawn next to the street; Lublin
(51°14'42.21"N, 22°32'12.93"E), ruderal vegetation next to tennis courts (UMCS
campus); Niebrzeg6w (Bondw) (51°30'48.28"N, 21°57'03.43"E), meadow; and
Miecmierz (51°18'22.50"N, 21°54'15.80"E), unplowed strip between fields. Adults
were collected from plants using a sweep net in series of 100 sweeps each time, at in-
tervals of 3-7 days, from May to August on sunny, windless days, during the hours (10
am to 4 pm) where they are most active. To obtain preimaginal stages, the aboveground
parts of Linaria vulgaris were collected for further detailed analysis in the laboratory.
In total, ca. 520 specimens of the host plant were collected in the field and examined.
The development stages (eggs, larvae, and pupae) were isolated from plants by making
delicate cuts in the developing infructescence and extracting them from its interior.
Some of the eggs and larvae (ten of both stages) were used for further breeding in the
insectarium, and others were used for measurements (also ten) and microscope slides.

Breeding

Developmental stages (L,) isolated from the generative parts were transferred to Petri
dishes on an ongoing basis. Further breeding was carried out in accordance with rec-
ommendations by Scherf (1964) and Letowski (1991). The Petri dishes were placed in
an incubation chamber under the following conditions: temperature 25 °C during the
day and 20 °C at night, humidity 40% during the day (16 h) and 50% at night (8 h).
The humidity inside the Petri dishes was higher, 65-80%.

Graphics

Preparation of microscope slides of preimaginal stages and graphics. Larvae and pupae
were treated with lactic acid C,H,O, (80%). Smaller morphological structures (mouth-
parts) were first immersed in a cold KOH solution (5%) before being transferred to
lactic acid. Developmental stages were analysed and documented using an OLYMPUS
BX61 microscope at magnifications from 200x to 400x. All graphics for the study were
prepared using CorelDraw X8 software. Metric data are means from ten measurements.
Drawings of the morphological structures of the larva and pupa were based on micro-
scope slides prepared according to Letowski (1991), Gosik (2010a), and Gosik et al.
(2010). The nomenclature of larval (L,) and pupal chaetotaxy was based mainly on the
work of Marvaldi (2003), Oberprieler et al. (2014) and in the case unnamed structures
the also on the work of Skuhrovec and Volovnik (2015). The morphology of the egg,
L, and pupa and the developmental cycle from egg to adult were described as well. The
biological material is stored in ethyl alcohol C,H,OH (70%) at the Department of Zo-
ology, Animal Ecology and Wildlife Management, University of Life Sciences in Lublin.

Setae of the thorax and abdomen of the larva (L,) and pupa are described for one
side only.

32 R. Scibior & J. Letowski / ZooKeys 807: 29-46 (2018)

Results

Rhinusa neta (Germar, 1821)

Description of egg. Measurements (in mm). Egg length 0.47—0.51 (mean 0.49), width
0.25—0.29 (mean 0.27).

General. Oval, slightly oblate.

Colouration. Light yellow, smooth surface.

Description of mature larva. (Figure 1, Table 1) Measurements (in mm). Body
length: 4.40—4.50 mm (mean 4.46). The widest part of the body (Ab. I) 1.73—1.8 (mean
1.76). Epicranium: length 0.54—0.59 (mean 0.57), width 0.58—0.63 (mean 0.61).

General. Body massive, strongly curved.

Colouration. Head yellow-brown, body light yellow, covered with black, numer-
ous setae.

Vestiture. Cuticle with strongly chitinised spots in several places on dorsal side.
Asperities of body integument present on the surface of all thoracic segments and first
abdominal segment covering area occupied by a group of setae prns and pds. Analogous
structure presents only on the surface of the first pedal lobe.

Head capsule (Figure 2): Head slightly oval. Endocarina (enc) long, nearly 4/5 of
frons length. One stemma (s¢) located at end of frontal suture at height of /s5. Frons
with three distinct setae: longest (f55) at base of antennae, fs1,4 located in the upper
and lower part of frons near endocarina, and two small sensillae (unnumbered) close
to fs4, which may be highly reduced setae fs2 and fs3. Dorsum of epicranium with five
setae (desI—5); des3,5 longest and des1,2,4 of intermediate length. Posterior epicra-
nium with four small setae (pes/—4) arranged in arc not far behind des2. On anterior
epicranium two long setae /es/—2 protrude from sides and visible vcs. Antennae (at)
with conical sensorium and two very small spinose sensillae.

Clypeus with two setae of equal length (c/s1, 2) at base with one sensilla between them.

Mouthparts (Figs 3-5): Dorsal side of labrum (Figure 3a) ca. 0.09 mm wide with
three pairs setae (/ms1—3). Longest /ms1, setae /ms2, 3 of similar length, only slightly
shorter than /rms1. Anterior margin of epipharynx arched, with three thick setae lat-
erally (a/s1—3), two setae (ams1—2) on anterior margin, and one seta (mes) medially,
between well-formed, arcuate labral rods (/r) (Figure 3b). Mandibles (Figure 4) mas-
sive, red-brown, with two large teeth and one small tooth on inner side; medially on
mandible three short setae (7dsJ—3) in one line. Maxillae (Figure 5) yellowish. Palpifer
with one long, medially located seta sts1, two apically placed setae of equal length
sts3—4 (or pfs 1-2) and one small sts2 (or mds) below molar part. Maxillary palpus with
two segments; basal segment with one very short seta (mxps) and two sensillae, distal
segment cylindrical with accessory process on dorsal side and ten conical papillae. Mala
with six setae of unequal length (dms1—6), arranged in one line, comb-like, and sepa-
rate group of three setae (vmsJ—3) situated apically. Labium: postmentum with three
setae of unequal length (pms1—3) — longest pms2 and shortest pms3. Prementum with

The morphology of the preimaginal stages of Rhinusa neta ao

Table |. Differences of the mature larva (L,) of Rhinusa neta and R. bipustulata based on the publications
of Scherf 1964, Anderson 1973, Gosik 2010a, and on personal research.

Rhinusa neta Rhinusa bipustulata

Frontal suture of V-shaped Y-shaped

epicranium

Endocarina reaches 4/5 of frons reaches 1/2 of frons

Setae of head des —5, pes—4 des — 4, pes—5

Stammata (ocelli) well visible, larger poorly visible, smaller
Antennae basal membranous area with 2 sensillae basal membranous area with 7 sensillae
Labrum, clypeus clypeus with 2 c/s and 1 sensilla clypeus with 3 c/s and no sensilla
Mandible mds — 3 mds — 2

Maxillae basal segment with 1 setae and 2 sensilla, distal basal segment with 1 seta and 1 sensillum, distal

segment with group of 10 short cuticular apical
processes and 1 sensilla,

segment with group of 4 long cuticular apical
processes and 1 sensilla,

Labial complex prelabium oval, with 2 processes in basal part, igs
2 pair in 2 rows, labial palps one-segmented with 5
conical cuticular apical processes (4 short, 1 long)

prelabium heart-shaped, with 1 process in basal part,
ligs 2 pair in 1 row, labial palps one-segmented with 5
conical cuticular apical processes (5 short)

Thorax (one side) prothorax: prvs on strongly sclerotised shield
Abdomen (one side) 8 unicameral spiracles located in middle of segments
I-VIII, segments I-VII with 1 prs, 3 dpls, segment
VIII with 1 dls, 3 dpls

prothorax: prns not on strongly sclerotised shield
8 unicameral spiracles located at anterior margin of
segments I-VIII, segments I—-VII with 2 prs, 1 dpbs,
segment VIII — 1 prs, 1 dpks

Ab. Ill Ab. Il

2.0mm

Figure |. Mature larva (L,), lateral view.

two distinct teeth on basal part, three setae (prms1 and /gs1—2) and three sensillae. Seta
prms1 very long, more than three times longer than /gs2. One pair /gsJ on apex and
with them slightly larger pair /gs2 placed closer together. Labial palpus 1-segmented,
with four shorter and one longer papilla located apically.

34 R. Scibior & J. Egtowski / ZooKeys 807: 29-46 (2018)

les,

0.5mm

Figure 2. Mature larva (L,), epicranium, dorsal view: at — antenna, cls — clypeal seta, des — dorsal epicra-

nial seta, enc — endocarina, es — epicranial suture, fs — frontal seta., es — lateral epicranial seta, /ms — labral

seta, st — stemmata, pes — posterior epicranial seta, vcs — ventral cranial seta.

Thorax (Figure 6). Pronotal shields sclerotised, meso- and metanotum each with
two folds: pro- and postdorsum. Spiracle unicameral, situated at intersegmental sep-
tum near pedal lobe. Prothorax with twelve setae: pronotum with seven (long prns1—6
and one short prs), epipleurum distinct with three setae of similar length (dp/s1—2 and
one vpls). Sternum outside pedal lobe with two setae (one /sts and one msts). Pedal area
on prothorax much more sclerotised than other two, with six setae of similar length

The morphology of the preimaginal stages of Rhinusa neta 35

0.1 mm

Figure 3. Mature larva (L,), clypeus and labrum, dorsal view (a): c/s — clypeal seta, /ms — labral seta; epi-

pharynx, ventral view (b): a/s — anterolateral epipharyngeal seta, ams — anteromedian epipharyngeal seta,

lr — \abral rod, mes — median epipharyngeal seta.

36 R. Scibior & J. Egtowski / ZooKeys 807: 29-46 (2018)

0.1 mm

Figure 4. Mature larva (L,)5 left mandible, dorsal view: mds — mandibular dorsal seta.

0.25mm

Figure 5. Mature larva (L,), maxillae and labium (L,): dms— dorsal malar seta, /gs— ligular seta, sts — sti-

pital seta, pms — postmental seta, prms — premental seta, vms — ventral malar seta.

The morphology of the preimaginal stages of Rhinusa neta 37

Ab Il Thill

Ab VIII-X

msts msts

|
2.0mm

Figure 6. Mature larva (L,), selected segments, lateral view: as — alar seta, dls — dorsolateral seta, dpls

msts

— dorsopleural seta, ds — dorsal seta, /s — lateral seta, /sts — laterosternal seta, msts — mediosternal seta, pds —
postdorsal seta, prs — prodorsal seta, prns — pronotal seta, ps — pleural seta, ss — spiracular seta, sts — sternal

seta, ¢s — terminal seta, vp/s — ventropleural seta.

(ps1—6) on all segments of thorax. Chaetotaxy of meso- and metathorax analogous,
consisting of eleven setae: mesonotum with five setae (pds/—3, one prs and one dbs).
Epipleurum with four setae (as/—3 and one vp/s), sternum with two setae (one dts and
one msts). Pedal areas of meso- and metathorax unsclerotised.

Abdomen (Figure 6). Abdominal segments I-VII of similar shape. Tergites I-VII
with two folds, prodorsum with one seta on ridge (prs1), postdorsum with five setae:
four located dorsally (pds 1—3, dls) and one, longest seta (ss) on spiracular area. Epipleu-
rum with four setae (dp/s1—3 and 1 vpls), sternum with two setae (one /sts and one msts).
Segments I-VI with unicameral spiracles, others ([IX-X) without spiracles. Segment
VIII with two folds, setae arranged as on segments I-VII, except for lack of seta prs.
Segment IX with four setae, two on pleura (one ds and one /s) and two on sterna (one &
and one sts). Segment X with two small setae, one on pleura and one on sterna (both #s).

Description of pupa. (Figs 7—9, Table 2) Measurements (in mm). Body length: 3.32—
3.40 (mean 3.35), width (between the apex of mesofemora) 1.90—1.98 (mean 1.92).

Colouration. Yellow-brown with distinct chaetotaxy.

Head (ventral view): rostrum reaches end of mesothorax, with one short seta
(drs) apically. Head with distinct eyes and one seta (sos) at their inner edge. Antennae
at base of rostrum. Massive. Zhorax: pronotum wider than long, trapezoid-shaped,

38 R. Scibior & J. Letowski / ZooKeys 807: 29-46 (2018)

Table 2. Differences of the pupa of Rhinusa neta and R. bipustulata based on the publications of Scherf
1964, Anderson 1973, Gosik 2010a, and on personal research.

Rhinusa neta Rhinusa bipustulata
Body length 3.35 mm (mean), width (between the apex of length 2.9-5.0 mm, width (between the apex of
mesofemora) 1.92 mm (mean), yellow-brown mesofemora) 1.50—2.60 mm, white or yellowish
Head rostrum with 1 seta (drs), head with 1 seta (sos) rostrum with 3 setae — 2 drs, 1 es, head with 2 setae
(brs)
Thorax pronotum: 8 setae: 2 aps, 3 Ips, 2 bps, 1 dps, all femora | pronotum: 9 setae: 2 aps, 3 lps, 2 bps, 2 dps, all femora
with 1 long seta (fes) with 2 long setae (fes)

Abdomen | dorsal part of segments I—VIII with 4 setae of unequal | dorsal part of segments I-VIII with 4 setae of unequal
length in one row and 2 of setae located laterally on | length in one group (3) and 1 seta located laterally and

pleural area I-VI 1 seta on pleural area I-VHI
ventral part of segments I-VIII with 4 of setae, of ventral part of segments I—-VII with 5 short setae
which 1 medial is longer and 3 shorter, arranged in row distributed in regular lines

abdominal segment VIII with 4 setae of unequal length} abdominal segment VIII with 2 microsetae located
located dorsally, 1 lateral slightly shorter and 4 short dorsally and 2 short, thin setae located ventrally
setae located ventrally in regular line

abdominal segment IX without setae abdominal segment IX with 3 microsetae located
ventrally
pseudocerci (urogomphi) longer, clearly visible pseudocerci (urogomphi) very short, poorly visible

with two distinct, highly sclerotised, bare tubercles at anterior margin, with eight
long setae: apsI—2, [ps1-3, dps2, and bps1—2 (Figs 7-9). Mesonotum longer than
metanotum. Latter with two clearly visible scutellar shields posteriorly. Dorsal part of
meso- and metanotum with three setae (7msns, mtns) of unequal length located later-
ally. All femora with one long, thin seta (fes) located apically. Abdomen: tergites -VII
with four setae in one row slightly beyond midpoint of segment. Longest located near
lateral outer margin, on segments I-V below spiracle entrance, on others (VI-VIJ)
centrally. Of three remaining setae, two short — centrally located and third from mid-
dle of segment, second from centre somewhat shorter, but clearly shorter than outer
seta. Segment VIII with four setae, shortest located medially, longest approx. three
times longer than first. Segment IX with one distinct urogomphi, darker, bent back,
highly chitinised (pseudocerci — pc) (Figs 7, 8). Sternites: segments I-VIII with four
setae arranged in one row, of similar length except longest pair located medially (Figs
7, 9). Spiracles on abdominal segments I-V placed laterally, functional. Pleurites (IH-
VIII) with seta of equal length, slightly shorter and curved on segment VIII, pleurites
(I-II) without setae (Figure 7).

Biological information. After overwintering, adults emerge in May and June,
depending on weather conditions in the year (Burakowski et al. 1997; Wilson et. al
2005). Initially, they feed on the vegetative parts of plants, and after the inflorescence
has been formed they feed on the generative parts. After copulation, the females lays
eggs into channels bored in the seed capsules and then uses excrement to seal the hole.
One or two larvae were usually observed in one seed capsule. Approximately 10-12
days after eggs were laid eggs in the laboratory, L, larvae appeared, which fed on the
seeds without causing them to swell. The full larval stage lasted on average 29 days,
followed by pupation. This stage lasted approximately 18 days. ‘The full development

The morphology of the preimaginal stages of Rhinusa neta 39

1.5mm

Figure 7. Pupa, lateral view: aps — apical pronotal seta, bps — basal pronotal seta, dps — discal pronotal seta,
drs — distrirostral seta, fes— femoral seta, /ps— lateral pronotal seta, msms — mesonotal seta, mins — metanotal

seta, pds — postdorsal seta, pls — pleural seta, pe — pseudocerci, sos — supraorbital seta, sp — spiracle.

40 R. Scibior & J. Letowski / ZooKeys 807: 29-46 (2018)

IRTP

1.5mm
Figure 8. Pupa, dorsal view: aps — apical pronotal seta, bps — basal pronotal seta, dps — discal pronotal seta,
Jes — femoral seta, /ps— lateral pronotal seta, msns — mesonotal seta, mins — metanotal seta, pds — postdorsal

seta, sp — spiracle,

cycle of the beetle in laboratory conditions averaged 58 days. Some larvae died in the
seed capsules, having been attacked by parasitic hymenopterans of the superfamily
Chalcidoidea, with parasitism reaching 20%. Species complete one generation per year
and the new generation of adults emerge in August and September.

The morphology of the preimaginal stages of Rhinusa neta 4]

fes

1.5mm

Figure 9. Pupa, ventral view: aps— apical pronotal seta, dps — basal pronotal seta, dps — discal pronotal seta,
drs — distrirostral seta, fes — femoral seta, /ps — lateral pronotal seta, pc — pseudocerci, sos — supraorbital seta.

42 R. Scibior & J. Letowski / ZooKeys 807: 29-46 (2018)

Discussion

In the last ten years a number of studies by various authors have described the larval
and pupal morphology of several taxa of Curculionoidea (Curculionidae, Apionidae):
Lixinae (Gosik and Skuhrovec 2011; Gosik and Wanat 2014; Skuhrovec and Volovnik
2015; Trnka et al. 2015, 2016), Tychiini (Skuhrovec et al. 2014, 2015; Gosik et al
2017), Ceutorhynchinae (Gosik 2010b), Bagous (Gosik 2008), Hyperini (Skuhrovec
2006, 2007; Skuhrovec and Bogusch 2016), Entiminae (Gosik and Sprick 2013; Go-
sik et al. 2016), Molytinae (Sprick and Gosik 2014; Arzanov 2016) and Apionidae
(Gosik et al. 2010; Wang et al. 2013; Letowski et al. 2015). However, within the tribe
Mecinini there are only two studies providing detailed descriptions of certain preim-
aginal stages of a few taxa (Gosik 2010a; Jiang and Zhang 2015).

In the genus Rhinusa, the most detailed morphology of immature stages in Europe
can be found only for the species R. bipustulata in a study by Gosik (2010). For the
remaining, fragmentarily described species, the only such studies are publications by Em-
den (1938) (larvae: R. antirrhini, R. collina, R. neta), Scherf (1964) (larvae: R. antirrhini,
R. bipustulata, R. collina, R. linariae, R. neta, R. tetra and pupae: R. antirrhini, R. bipus-
tulata, R. collina, R. linariae) and Anderson (1973) (larvae: R. antirrhini, R. neta, R. tetra
and pupae: R. antirrhini, R. neta, R. tetra). For the very closely related genus Gymnetron,
the immature stages of three species (G. miyoshii Miyoshi, 1922, G. auliense Reitter, 1907
and G. vittipenne Marseul, 1876) have recently been described (Jiang and Zhang 2015).

A study by Emden (1938) includes key characters by which the larvae of R. neta
can be distinguished from R. antirrhini and R. collina. R. neta has a lighter, brownish-
yellow head with a coarsely granulate frons. In addition, this species has 2—3 basal
bristles of the maxillary mala that are more prominent than the others (Figure 5).

Scherf (1964) presents only few data on the biology of R. neta larvae, regarding its
spectrum of host plants, feeding site, and the shape of the cecidia it causes. A work by
Anderson (1973) presents graphics illustrating the frons of R. neta with an identical ar-
rangement of setae (but unnumbered and unnamed) as in the present study, as well as
characteristic, transverse asperities on its surface, making the L, larvae easily distinguish-
able from Rhinusa antirrhini, which also feeds on the seeds of Linaria sp. (in which the
frons of the L, larva is smooth). Another distinctive character of R. neta is the presence
of a long endocarina extending 4/5 of the length of the frons. On the epipleuron and
pleuron of the abdominal segments (I—VIII) of the L, larvae, there is a group of setae
dpls\—3 and vpls1, which differs from the typical arrangement found in weevils (dp/s1—2
and vpls1—2), but is confirmed in the key by Anderson (1973), according to which the
three epipleural setae dp/s distinguish R. neta from R. antirrhini, which has only two.

The number of setae on the dorsal surface of mandible within the Curculionidae
family usually varies from 0 to 2. On this surface, there are also sensillae in the number
of 0 to 3. The mandible of the discussed taxon generally resembles the system present in
Ceutorhynchinae in terms of the setae and sensillae system (Scherf 1964), except that
R. neta has three setae of similar length arranged in one line. The arrangement of the
three setae at the mandible surface discussed in the paper is unique within this family.

The morphology of the preimaginal stages of Rhinusa neta 43

In regard to the characters contained in the key by Marvaldi (2003) describing
the length of a few setae on the frons (/s4, des5, and Jes), they are also well visible in
this species, but setae fs5, des3, and /es2 are well developed as well. On the other hand,
the lengths of setae fs4 and fs5, which in Curculionidae sensu lato should be at least
of similar length (or fs4 should be longer), are not in agreement. In R. neta the pat-
tern is reversed, as fs5 is longer than fs4. A similar relationship between the lengths of
these two setae is also reported in a study on R. bipustulata (Gosik 2010a), where fs5
is designated as fs3.

As regards the biology of species, in addition to Rhinusa taxa, data on R. pilosa
have been published as well (Gassmann et al. 2014). Phylogenetic research by Cal-
dara et al. (2010), based on morphological data and host plants, indicates that the
taxa most closely related to R. neta are R. collina (which is also confirmed in the key
by Emden (1938)), R. eversmanni, R. canescens and R. soluta, but their preimaginal
stages have not yet been described in detail. The similarities and differences between
the larvae and pupae of R. neta and R. bipustulata, which has been studied in the
greatest detail by Gosik (2010a), are presented below. The most significant differences
between these species in the case of the L, larval instars and pupae are shown in bold
in Tables 1 and 2.

The information given in the two tables, grouping all available differences in the
morphological structure of the L, larva and pupa, can be used to prepare more detailed
keys, both between the taxa given above and at the level of the tribe.

In the case of the pupae of the two taxa, the differences are in the number and
location of the pairs of setae on the rostrum and head, number of pairs of setae on the
prothorax, number of setae on the femora, location of the setae on the tergites, number
of setae on the pleurites, number of setae on the sternites of segments I-IX, and length
of the pseudocerci (or urogomphi).

Data presented by Wilson et al. (2005) indicate that in Canada the development
cycle of R. neta lasts ca. 40-60 days, including 20-30 days for the larval stages and
10-15 days for the pupal stage.

Acknowledgements

The authors would like to thank Krzysztof Olszak, Mariola Maj, and Wioleta Maj
for their help in collecting and analysing the biological material and the reviewers for
considerably improving the manuscript.

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