ZooKeys 1055: 1-41 (202 1) A peer-reviewed open-access journal
doi: 10.3897/zookeys.1055.66796 RESEARCH ARTICLE #ZooKey S

https:/ / ZOO keys. pensoft.net Launched to accelerate biodiversity research

Resolving a century-old case of generic mistaken
identity: polyphyly of Chitoniscus sensu lato resolved
with the description of the endemic New Caledonia

Trolicaphyllium gen. nov. (Phasmatodea, Phylliidae)

Royce T. Cumming!??, Stéphane Le Tirant', Thies H. Biischer*

| Montreal Insectarium, 4101 rue Sherbrooke est, Montréal, Québec, H1X 2B2, Canada 2 Richard Gilder
Graduate School, American Museum of Natural History, New York, NY 10024, USA 3 Biology, Graduate
Center, City University of New York, NY, USA 4 Department of Functional Morphology and Biomechanics,
Zoological Institute, Kiel University, Am Botanischen Garten 9, 24118, Kiel, Germany

Corresponding author: Royce T. Cumming (phylliidae.walkingleaf@gmail.com)

Academic editor: Sven Bradler | Received 1 April 2021 | Accepted 13 July 2021 | Published 5 August 2021
http://zoobank.org/DB8C0779-E757-44ED-B9B2-397 EAZEF3BAE

Citation: Cumming RT, Le Tirant S, Biischer TH (2021) Resolving a century-old case of generic mistaken identity:
polyphyly of Chitoniscus sensu lato resolved with the description of the endemic New Caledonia Trolicaphyllium gen.
nov. (Phasmatodea, Phylliidae). ZooKeys 1055: 1-41. https://doi.org/10.3897/zookeys.1055.66796

Abstract

With every molecular review involving Chitoniscus Stal, 1875 sensu lato samples from Fiji and New
Caledonia revealing polyphyly, the morphology from these two distinct clades was extensively reviewed.
Morphological results agree with all previously published molecular studies and therefore Trolicaphyl-
lium gen. nov. is erected to accommodate the former Chitoniscus sensu lato species restricted to New
Caledonia, leaving the type species Chitoniscus lobiventris (Blanchard, 1853) and all other Fijian species
within Chitoniscus sensu stricto. Erection of this new genus for the New Caledonian species warrants
the following new combinations: Trolicaphyllium brachysoma (Sharp, 1898), comb. nov., Trolicaphyllium
erosus (Redtenbachher, 1906), comb. nov., and Trolicaphyllium sarrameaense (Grofer, 2008a), comb. nov.
Morphological details of the female, male, freshly hatched nymph, and egg are illustrated and discussed
alongside the Chitoniscus sensu stricto in order to differentiate these two clades which have been mistaken

as one for decades.

Keywords
Camouflage, Drehu, Grande Terre, Ile de Bélep, LIle-des-Pins, Lifou, Lifu, Maré, mimicry, new combina-

tion, Phasmida, Tiga, walking leaf

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

2 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Introduction

Phasmatodea, the stick and leaf insects, are a group of rather large herbivorous in-
sects that is well known for their diversity of morphological adaptations facilitating
imitation of parts of plants (Bedford 1978). One particular lineage of phamids is well
known for its perfect mimicry of plant leaves: the walking leaves (Phylliidae). The
phylogenetic relationships of phasmids in general (Bradler et al. 2015; Goldberg et
al. 2015; Robertson et al. 2018; Biischer et al. 2018a; Glaw et al. 2019; Simon et
al. 2019) and phylliids in particular (Bank et al. 2021) are subject to several studies
based on morphological, as well as molecular data and corroborated the monophyly
of Phylliidae on the one hand but recovered Phyllium as paraphyletic (Bank et al.
2021). Chitoniscus sensu lato in particular are rather short and stout leaf insects, which
perfectly blend in with the foliage of the plants they dwell on (Fig. 1). Within their
largely tree dominated, canopy dwelling habitats (Fig. 2) such small leaf insects are
well hidden from potential predators. Due to their size and their, more or less, close
distribution on New Caledonia and the Fiji islands, several species in past years were
assigned to Chitoniscus sensu lato based on general morphological features. Large-scale
phylogenetic studies on Phasmatodea repeatedly recovered Chitoniscus sensu lato as
polyphyletic (e.g., Buckley et al. 2009; Bradler et al. 2015; Robertson et al. 2018;
Forni et al. 2020; Bank et al. 2021). Apparently the two distributional centers (New
Caledonia and Fiji) of these superficially similar types of leaf insects represent two
separate lineages within Phylliidae, with the clade from Fiji always recovered as sister
to the remaining phylliids, while the placement of the New Caledonia clade has been
recovered within the remaining phylliids in different locations depending upon the
tree topology recovered (Buckley et al. 2009; Bradler et al. 2015; Forni et al. 2020;
Bank et al. 2021). Convergent traits are common within Phasmatodea (Buckley et al.
2009; Goldberg et al. 2015; Robertson et al. 2018; Biischer et al. 2018, 2019; Zeng
et al. 2020) and particularly insular dwarfism is a common explanation for some small
size convergences in vertebrates (e.g., Lomolino 2005) and also reported for insects
(Hayashi 1990). Therefore, in light of the phylogenetic results, we aimed to review the
assemblage of taxa assigned to Chitoniscus sensu lato to deliver morphological evidence
for the two similar sized lineages, that have been considered congeneric since 1904
(Kirby 1904). The distribution, including the furthest latitude south reported for any
phylliid, of these miniaturized phylliids indicates two distinct geographic clusters, that
render the monophyly of Chitoniscus sensu lato even more unlikely. In turn, the two
distributional centers of Chitoniscus sensu lato are not only separated, they are also
interconnected by different phylliid taxa (Brock et al. 2021). Hence, the resemblance
of the two lineages rather likely arises from secondary adaptation towards similar selec-
tive pressures, i.e., convergently. Specimens formerly assigned to Chitoniscus sensu lato
were traced in museums, private collections, and other sources and were examined to
evaluate the identities of the two groups of small-sized leaf insects. We challenged the
present interpretation of Chitoniscus sensu lato with this dataset and compared these
two lineages of small sized Phylliidae using morphological and distributional data.
In the following we aimed to answer the research questions: i) Which morphological

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 1

ae

—

= cat

Figure |. Dorsal habitus of a live adult female Trolicaphyllium sarrameaense comb. nov. photographed by
Thierry Salesne (New Caledonia) in March 2011, in Vallée Pierrat, La Foa, Grand Terre.

Figure 2. Example of Trolicaphyllium gen. nov. habitat on Dogny Plateau, Sarramea Commune, pho-

tographed by Thierry Salesne (New Caledonia) in August 2011, at approximately 1,000 meters elevation

A view from the trail over the plateau B view of the primary forest undergrowth.

characters separate these two groups of leaf insects? ii) How can the observed molecular
disjunct within Chitoniscus sensu lato be explained phenotypically and geographically?
iii) How can this conflict be resolved taxonomically?

4 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Materials and methods

The following collection acronyms are used.

AMNH — American Museum of Natural History, New York, USA;

BPBM Bishop Museum, Honolulu, Hawaii, USA;

Coll DG Private collection of Detlef Grofer, Berlin, Germany;

Coll RC Private collection of Royce T. Cumming, California, USA;

Coll SLT Private collection of Stéphane Le Tirant, Québec, Canada;

CUMZ Cambridge University Museum of Zoology, Cambridge, United Kingdom;

IAC Institut Agronomique néo-Calédonien, La Foa, Nouvelle-Calédonie;

IMQC Insectarium de Montréal, Montréal, Québec, Canada;

MNHN- Muséum National d'Histoire Naturelle, Paris, France;

MZPW Polish Academy of Sciences, Museum and Institute of Zoology, Warsaw,
Poland;

MHN Muséum d Histoire Naturelle, Geneva, Switzerland;

NHMB __ Naturhistorisches Museum, Basel, Switzerland;

NHMUK Natural History Museum United Kingdom, London, United Kingdom;

NHMW Naturhistorisches Museum Wien, Vienna, Austria;

QM Queensland Museum, South Brisbane, Australia;

SDEI Senckenberg Deutsches Entomologisches Institut, Miincheberg, Germany.

Photography

Photographs of specimens deposited within the IMQC collection and Coll SLT were
taken by René Limoges using a Nikon D850 DSLR camera (Nikon Corporation,
Tokyo, Japan) with Nikon Micro-Nikkor 200mm f/4 lens on Manfrotto 454 micro-
metric positioning sliding plate (Manfrotto, Casolla, Italy). Lighting was provided by
two Nikon SB-25 flash units with a Cameron Digital diffusion photo box (Henry’s,
Vancouver, Canada).

Photographs from SDEI were taken by Arne Kohler (SDEI) using either a Nikon
D7200 camera (Nikon Corporation, Tokyo, Japan) or Leica M205C-microscope (Lei-
ca Microsystems Inc., Buffalo Grove, USA). The stacking software used were Zerene
Stacker (for the Nikon images; Zerene Systems LLC, Richland, USA) and Helicon
Focus (for the Leica images; Helicon Soft Ltd., Kharkiv, Ukraine).

Photographs of specimens within the first authors collection (Coll RC) were taken
by RC using a Canon 5D Mark II and a MP-E 65mm macro lens and stacked using
Zerene Stacker (Zerene Systems LLC, Richland, USA). The eggs of Trolicaphyllium
sarrameaense comb. nov. were photographed using a Nikon D3500 camera (Nikon
Corporation, Tokyo, Japan) mounted on a Wild M3C stereomicroscope (Wild, Heer-
brugg, Switzerland) and manually stacked. Adobe Photoshop Elements 13 (Adobe
Inc., San Jose, USA) was used as post processing software.

Egg orientation terminology follows Clark (1978), and wing venation terminology

follows Burt (1932) and Ragge (1955).

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia z)

Scanning electron microscopy (SEM)

Micrographs were obtained from dried samples, which were sputter coated with 10 nm
gold—palladium. Overview images were obtained with a Hitachi TM3000 SEM (Hi-
tachi High-technologies Corp., Tokyo, Japan) at 15 kV acceleration voltage using a
rotatable specimen holder (Pohl, 2010). Detailed micrographs were obtained in the
SEM Hitachi $4800 (Hitachi High-technologies Corp., Tokyo, Japan) at an accelera-
tion voltage of 5 kV. Adobe Photoshop Elements 13 (Adobe Inc., San Jose, USA) was
used as post processing software.
Morphological abbreviations (listed morphologically anterior to posterior)

al-—a9 antennomeres 1—9 M media

st stridulatory file MA media anterior

st stridulatory ridge MP media posterior

ar arolium MP1 first media posterior

cl claw MP2 second media posterior
eul—5 euplantula 1-5 Cu+MA+MP - fused cubitus, media an-
tal—5 tarsomere 1—5 terior, and media posterior
ri median ridgelike expansion Cu cubitus

C costa CuA cubitus anterior

Sc subcosta CuP cubitus posterior

R radius Cu+1AA ~~ cubitus and first anterior
R1 radius 1 anal

R2 radius 2 1A first anal

Rs radial sector 1AA-7AA _ first—seventh anterior anal
R-M radius to media crossvein 1PA-5PA _first—fifth posterior anal
Results

The results of our morphological and biogeographic examination of Chitoniscus sensu
lato strongly support the presence of at least two independent lineages, thereby neces-
sitating the recognition of a new genus, Trolicaphyllium gen. nov., to accommodate
the endemic New Caledonia taxa. The erection of this novel genus is supported by the
identification of autapomorphic morphological features (discussed below) as well as
years of molecular results recovering Chitoniscus sensu lato as polyphyletic (e.g., Buck-
ley et al. 2009; Bradler et al. 2015; Robertson et al. 2018; Forni et al. 2020).

Taxonomy

Trolicaphyllium gen. nov.
http://zoobank.org/FDDA1369-F249-45 1C-85A8-C1298F10EA58

Type species here designated. Phyllium brachysoma Sharp, 1898.

6 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Taxonomic hierarchy. Due to the general phylliid morphological features, and the
consistent recovery of this clade nested within the greater phylliids in molecular stud-
ies, we herein place this genus within the tribe Phylliini Brunner von Wattenwyl, 1893.

Discussion. The selected type species for this new genus is Phyllium brachysoma
Sharp, 1898 (= Trolicaphyllium brachysoma (Sharp, 1898), comb. nov.) which was the
first species described and is represented by two female syntype specimens collected on
Lifou Island (Fig. 22). With the differentiation of the various species within this genus
somewhat vague due to possible morphological variability, we felt the original species
from a single known exact locality was the best choice as type species.

This new genus has been confused for decades with the similarly sized Chitoniscus
Stal, 1875 sensu stricto from nearby Fiji due to their superficial similarities. All molec-
ular phylogenies which have included both Fijian and New Caledonian samples have
recovered these as polyphyletic (e.g., Buckley et al. 2009; Bradler et al. 2015; Robert-
son et al. 2018; Forni et al. 2020; Bank et al. 2021), with the Chitoniscus sensu stricto
as sister to all other extant phylliids. Within the phylliid-wide phylogeny of Bank et
al. (2021) the New Caledonian clade was recovered as sister to Comptaphyllium Cum-
ming et al. 2019b with high support. Interestingly, few morphological features link
these two genera, and it appears as though based upon morphological similarity, higher
level relationships among the phylliids are difficult to ascertain. Only the intra-generic
relationships appeared to agree readily when reviewing molecular and morphological
data (Bank et al. 2021).

Little is presently known about the Trolicaphyllium gen. nov. ecology at the mo-
ment, as the only host plant records we have seen to date are from a Ficus sp. (recorded
by Thierry Salesne; New Caledonia) and Syzygium cumini (recorded by Sylvie Cazeres
(IAC); Fig. 3). The only additional information we have regarding the ecology of this
genus are short notes gleaned from specimen labels. In particular, “rainforest” appeared
on many labels within the QM collection as noted by Geoff Monteith.

Morphological differentiation from Chitoniscus sensu stricto. Features which
liken these two genera together are their short length (ca. 40 to 60 mm) and broad
bodies. Both genera have species which have smooth/tapered abdominal shapes or can
be strongly lobed (within both males and females). The eggs of both species are small
and lack pinnae therefore they superficially resemble each other.

However, when the finer details of these two genera are reviewed, the differences
between them are significant (Table 1). A key to genera is not presented here as a thor-
ough key was published within Bank et al. (2021) to all phylliid genera and can still
be used to key to the Chitoniscus sensu lato couplet, at which point the features within
Table 1 can then be used to differentiate these genera.

Autapomorphic features. Several morphological features unite the New Caledo-
nian species and support monophyly of this clade within the phylliids. Within females,
the euplantula 2 and 3 on the tarsus has the unique feature of a ridge-like expansion
running along the entire tarsomere (Fig. 12B), a feature not seen in any other phylliids.
Within males the alae venation (Fig. 14) is unique within the phylliids as the media
anterior (MA) and media posterior (MP) veins fuse with the cubitus (Cu) at different
locations along the cubitus and run fused to the wing margin (versus other phylliid

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 7

Table |. Summary of morphological features for differentiating Chitoniscus Stal, 1875 sensu stricto from

Trolicaphyllium gen. nov. as these two have been mistakenly associated for more than a century. Listed

morphologically from the anterior to posterior.

Female

Antennae

Antennae: third antennomere

Antennae: third antennomere

(sf teeth)

Trolicaphyllium gen. nov. Chitoniscus Stal, 1875 sensu stricto

Antennomeres III, VIII, and [X widened, broader than] Antennomeres HI, VHI, and IX not widened, with

the antennomeres between; Fig. 4A. similar diameter as the antennomeres between; Fig. 4B

Not broadened, sr shifted anteriorly, sf meets sr at half
of its length; Fig. 5B. Sf short, < 30 teeth; Fig. 5B
Teeth with a weakly bilobed apex; Fig. 5D

Broadened, sr not shifted anteriorly, sf meeting sr in
anterior third; Fig. 5A. Sflong, = 35 teeth; Fig. 5A
Teeth with a smooth apex; Fig. 5C

Antennae: first antennomere

Dorsal surface without notable expansion, flush with | Dorsal surface with expansion projecting anteriorly

anterior of the segment; Fig. 6A, C alongside the 2" antennomere, projecting beyond the

anterior end of the segment; Fig. 6B, D

Protibial interior lobe

Prescutum anterior rim
sagittal spine

Ventral coxae color

Tegmina: R and M

Always spanning the full length of the protibial shaft | Either absent or even in the most well-developed forms
only on the proximal half, never fully spanning
Spine and rim distinct, but not large; Fig. 7A. Rim

and spine situated on the anterior margin, not strongly

Spine and rim prominent; Fig. 7B. Rim strongly
protruding and angled posteriorly; Fig. 8B
protruding posteriorly; Fig. 8A
Green, similar shade as the remainder of the insect;
Fig. 9A
R runs parallel with M until the split of Rs, at which
point Rs bends away distinctly; Fig. 10A

Sky blue in color; Fig. 9B

R diverges steadily from M for the full length,
therefore the split of the Rs is not a significant bend;

Fig. 10B
Tegmina: R-M crossvein R—M crossvein does not fade, but fully reaches to and R—-M crossvein thins and fades before reaching M;
connects with M; Fig. 10A Fig. 10B
Terminal abdominal segment Broad; almost two times as wide as long; Fig. 11A Narrow; approximately as long as the greatest width;
Fig. 11B

Cerci texture

Weakly granular/smooth; Fig. 11A Heavily granular; rough textured; Fig. 11B

Tarsus Euplantula 2 and 3 with ridgelike expansion along the Euplantula 2 and 3 without ridgelike expansion;
entire tarsomere; Fig. 12B Fig. 12B

Male

Ocelli Well developed; Fig. 13A Absent; Fig. 13C, D

Protibial interior lobe

Prescutum

Alae: R split into R1 and Rs

Alae: MA and MP

Always spanning the full length of the protibial shaft | Typically, absent or in well-developed forms only on
the proximal half, rarely fully spanning and if so only

as a thin lobe

Anterior margin more typical of a phylliid with the Anterior margin angled posteriorly, making the

margin not strongly curved, making the prescutum prescutum appear very stout; Fig. 13C, D
appear less compacted; Fig. 13A, B

Split is approximately 7 of the way through the wing; Split is approximately halfway through the wing

Fig. 14

Media anterior (MA) and media posterior (MP) veins

Media anterior (MA) runs unfused to the wing
fuse with the cubitus (Cu) at different locations along | margin; media posterior (MP) fades without fusing or

the cubitus and run fused to the wing margin; Fig. 14 reaching the wing margin

Eggs

Operculum
General chorionic texture

Microstructures

Freshly hatched nymph

Raised on the ventral end, not centrally raised, no pit, | Centrally raised and with a pit in the center; Fig. 15F
minimal granulation throughout; Fig. 15C
Small spherical surface structures; Fig. 16A, B, also Tuberculate chorionic surface, rough; Fig. 16D, E,

present on the micopylar cap Fig. 16C pinnate micropylar cap; Fig. 16F

Mushroom-like smooth granula; Fig. 17B Small pinnae arranged in ridges; Fig. 17E

Meso-, metafemoral
coloration

Mostly black in color, no prominent white patches;
Fig. 18B

Prominent white patch on the center of the exterior
lobe and onto the femoral shaft; Fig. 18A

Mesonotum

Abdominal coloration

Distribution

Slender, posterior width similar to length; Fig. 18A Stout, posterior width greater than length; Fig. 18B

Abdomen black with the margins of segment II-IV
and VI-IX green; Fig. 18A
New Caledonia; Fig. 21

Abdomen uniformly black, no green margins; Fig. 18B

Fiji

genera which for example can have the MA and MP often fuse and run together to the

wing margin, fuse with the Cu after first fusing together, never fuse and simply fade be-

fore reaching the margin, or fuse with the Cu at different locations but are also joined
by the first radial (R1) and radial sector (Rs) and all run together to the wing margin).

8 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Figure 3. Adult female Trolicaphyllium cf. sarrameaense comb. nov. found feeding on Syzygium cumini

Sarramea county, near La Foa, January 2021 (recorded and photographed by Sylvie Cazeres (IAC)) A dor-

soanterior, habitus B dorsal, habitus.

These autapomorphic features help to define the new genus Trolicaphyllium gen. nov.
within the Phylliidae as well as differentiate them from the Chitoniscus sensu stricto.

Generic characteristics. The Trolicaphyllium gen. nov. are small to medium, with
females ranging from 42.0 mm (in the smallest recorded Trolicaphyllium erosus comb.
nov.; Redtenbacher 1906) to 60.0 mm long (in the largest Trolicaphyllium sarrame-
aense, comb. nov.; Grofer 2008b), with males from 38.5 mm to 43.3 mm (in the
smallest and largest Trolicaphyllium brachysoma, comb. nov.; Grofer 2008b). Typical
general coloration is green, but in captivity orange/yellow has been induced (Fig. 19).

Legs. Both sexes have interior tibial lobes on the protibiae which span the full
length, lack lobes on the protibial exterior, and the meso-, metatibiae are simple, lack-
ing both interior and exterior lobes. In both sexes the profemoral interior lobe is broad-
er than the exterior lobe (distinctly so in males with a width almost two times that of
the exterior lobe, sometimes in females the interior and exterior are almost even in
width). In both sexes the profemoral interior lobe is generally only marked with three
or four broadly spaced teeth (quite dulled in females; slightly more serrate in males).
Both sexes have the interior meso-, and metafemoral lobes slightly broader or about
even in width to the exterior lobes, but the interior lobes are always more prominently
marked by serration.

Antennae. Females have antennae with nine segments with segments I, III, VIII,
and IX notably broader than the other segments (Fig. 4A) and the stridulatory file has

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 9

Figure 4. Scanning electron micrographs of female antennae A, C Trolicaphyllium sarrameaense comb.

noy. B, D Chitoniscus sensu stricto A, B overview of the antenna, medial view A right antenna B left
antenna C, D third antennomere. Abbreviations: al—a9, antennomeres 1—9 st stridulatory file, sr stridula-

tory ridge. Scale bars: 300 um (A, B), 200 um (C, D).

more than 35 teeth (Fig. 5A). Males have antennae which range from 23 to 26 seg-
ments with most segments covered in setae which are longer than the segment is wide.

Head capsule. Males have well-developed ocelli (Fig. 13A), and both sexes have
head capsules which are marked throughout by distinct granulation which is relatively
evenly spaced and, in some cases, appears to be in slightly anterior to posterior rows
(Figs 7A, 13A).

Thorax. The thorax is similar in both sexes with mesopleurae that are narrowly di-
verging from the anterior to the posterior and are marked with five to seven tubercles,
occasionally with sparse setae interspersed (Figs 7A, 13A). In both sexes the prescutum
is about two times wider on the anterior than long with lateral margins marked by
six to eight tubercles, and a prescutum surface which is only slightly granular. When
viewed laterally, both sexes have the prescutum anterior rim marked prominently with
a raised sagittal spine and both have a prosternum which is prominently marked by a
broad, warty tubercle (Figs 8A, 13B).

Wings. Female tegmina are always long, reaching onto abdominal segments VII
or VIII and male tegmina are moderate in length, reaching onto abdominal segment
III. Females always have highly reduced alae, no more than just a nub (Fig. 22A). Male
alae are always fully developed in an oval-fan configuration and reach onto abdominal
segment IX (Fig. 14). Female tegmina have a subcoastal vein; radial vein which runs

Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Figure 5. Scanning electron micrographs of female stridulatory organs A, C Trolicaphyllium sarrame-
aense comb. nov. B, D Chitoniscus sensu stricto A, B overview of stridulatory ridge C, D teeth of stridula-

tory file. Scale bars: 100 um (A, B), 20 um (C, D).

Figure 6. Scanning electron micrographs of female scapus (1** antennomere) A, C Trolicaphyllium sar-

rameaense comb. nov. B, D Chitoniscus sensu stricto A, B overview of scapus, lateral view C, D medial

view. Scale bars: 200 um.

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 11

Figure 7. Details of the head through thorax, dorsal A Trolicaphyllium sarrameaense comb. nov. (holo-
type) (DEI Hemimetabola, #100215) B Chitoniscus sp. “Suva” (RC Coll 18-176).

parallel with the media and splits into the first radial about halfway through its length
and terminates in a radial sector and in a small radial to medial crossvein which does
fully connect; a bifurcate medial vein; a bifurcate cubitus vein; and a first anal vein
which fuses with the cubitus early on (Fig. 10A). Male tegmina have a subcoastal vein;
radial vein which runs parallel with the media throughout the full length of the wing
and branches into the first and second radial about one third and two thirds of the
way through the wing length respectively and terminates as the radial sector; the media
runs parallel with the radius and has two media posterior splits near the central area of
the wing and terminates as the media anterior; the cubitus is unbranched; and there is
a first anal which fuses with the cubitus early on (Fig. 14). Male alae (Fig. 14) have a
costal vein running along the anterior margin; a subcostal vein which runs for about
two thirds of the length and then fuses with the costal vein; the radial vein is bifurcate
when it splits about two fifths of the way through the wing length where they diverge,
run parallel, then converge sharply at the apex but don’t seem to reach the wing mar-
gin; the media is the most unique feature of the alae as it splits early on into the media
anterior and posterior which run parallel until the media posterior fuses with the cu-
bitus followed by the media anterior also fusing with the cubitus; the cubitus is fused
with the first anterior anal for the majority of the length until the first anterior anal

12 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Figure 8. Lateral details of the head and thorax A Trolicaphyllium sarrameaense comb. nov. (holotype)
(DEI Hemimetabola, #100215) B Chitoniscus sp. “Suva” (RC Coll 18-176).

splits and runs to the wing margin; the cubitus, media anterior, and media posterior
run fused to the wing margin; the anal veins are split into two groups, the anterior
anals and the posterior anals (with seven anterior anals and five posterior anals).

Abdomen. Both sexes have variable abdominal shapes; females can range from
spade-shaped to broad and boxy with prominently projecting abdominal lobes VII and
VII; males can be narrowly-ovoid and lack lobes to broadening until segment VII and
converging with lobes. Female subgenital plate is short and stout with the apex reach-
ing the anterior margin of the terminal abdominal segment and ending in a fine point;
the gonapophyses VIII are long and slender, slightly exceeding the apex of the terminal
abdominal segment; the cerci are relatively flat, marked sparsely with a granular surface
with margins slightly marked with setae (Fig. 11A). Males have a broad, triangular
vomer which is singularly pronged, hooking up into the paraproct.

Egg. Ege morphology is only known at present from Trolicaphyllium sarrameaense,
comb. nov. (Fig. 15A—C). Yasumatsu (1942) suggested an egg for Trolicaphyllium
brachysoma comb. nov. but the specimen the eggs were from was not collected on New
Caledonia and likely represents a different genus and is unrelated to Trolicaphyllium
gen. nov. based upon the illustration given. This general egg description is based upon
examined material and on images of eggs from several sources all appearing to come

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 13

Figure 9. Ventro-posterior view of live females showing their exposed coxae coloration A Trolicaphyl-

lium sarrameaense comb. noy. taken by Thierry Salesne (New Caledonia) March 2011, in Vallée Pierrat,
La Foa, Grand Terre B Chitoniscus sp. “Suva” (RC Coll 18-176) live photograph taken by Thierry Heitz-
mann (Philippines).

from Trolicaphyllium sarrameaense comb. nov. females. Average length approximately
3 mm long. Eggs when viewed laterally are somewhat rectangular but with the dorsal
surface slightly convex and longer than the ventral, giving the egg a slight bent ap-
pearance (Fig. 15B). Surfaces are marked throughout with shallow, irregular smooth
patches which are accentuated by having darker coloration than the overall egg colora-
tion. Eggs lack pinnae, but instead have small granulation scattered across the capsule
which is most prominent and abundant along the capsule margins and notably sparse
on the flat surfaces. The egg operculum is conically raised on the ventral margin only,
not centrally raised like most phylliid eggs. The raised operculum is only about half as
tall as wide and increases from the dorsal margin to the highest point on the ventral
margin. The operculum apex has a similar granulation to that found on the capsule
margins. Overall egg coloration variable, from a pale tan to light brown, or darker
brown, with the pitting on the capsule darker in color and the granulation throughout
lighter in color (Fig. 20).

Nymphs. Freshly hatched nymphs are known at present for Trolicaphyllium sar-
rameaense comb. nov. (Fig. 18A) but are unknown for the other Trolicaphyllium gen.
nov. species. Therefore, a comparison between species is not possible at this time. This

14 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Figure 10. Female tegmina venation A Trolicaphyllium sarrameaense comb. nov. (Coll SLT) B Chitonis-
cus feejeeanus from SDEI (#100213). Abbreviations: Sc (subcosta); R (radius); R1 (radius 1); Rs (radial
sector); R-M (radius to media crossvein); M (media); MA (media anterior); MP (media posterior); Cu
(cubitus); CuA (cubitus anterior); CuP (cubitus posterior); 1A (first anal).

Figure | 1. Female genitalia details, ventral view A Trolicaphyllium sarrameaense comb. nov. (Coll SLT)
B Chitoniscus sp. “Suva” (RC Coll 18-176).

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 15

Figure 12. Scanning electron micrographs of tarsi A, C Chitoniscus sensu stricto B Trolicaphyllium sar-
rameaense comb. nov. A male, overview B, C females, tarsomeres 1—5. Abbreviations: ar, arolium, cl, claw,

eul—5, euplantula 1-5. Tal—5, tarsomere 1-5, ri, median ridgelike expansion. Scale bars: 500 um.

generalized description is based upon images of Trolicaphyllium sarrameaense comb.
nov. shared by Detlef Grofer (Germany). Body long and slender; profemora and proti-
biae with thin interior lobes but lack exterior lobes; meso- and metafemora with thin
interior and exterior lobes; meso- and metatibiae simple, lacking lobes. ‘The base col-
oration throughout the antennae, head, thorax, abdomen, meso- and metafemora is
black. Profemora and all tibiae and tarsi are lighter colored, ranging from dark brown
to tan/reddish. All joints between the tibiae and femora are marked with white. ‘The
meso- and metafemoral exterior lobes are marked with a medial white spot occupying
approximately the central third of the lobe. The abdomen is slender and longer than
the antennae, head, and thorax combined. Centrally the abdomen is black, but the
margins of segments I-IV and VI-VII are bordered with a lime green color.

New combinations

Trolicaphyllium brachysoma (Sharp, 1898), comb. nov.
Trolicaphyllium erosus (Redtenbachher, 1906), comb. nov.

Trolicaphyllium sarrameaense (Grofer er, 2008a), comb. nov.

16 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Figure 13. Details of male head through thorax A, B Trolicaphyllium sarrameaense comb. nov., para-
type male (#100214); photographs by Arne Kohler (SDEI) C, D Chitoniscus sensu stricto A, C, D head
through thorax, dorsal B head through thorax, lateral C Chitoniscus sp. from the NHMUK, photograph
by RC D live Chitoniscus sp. “Suva”, photograph by Thierry Heitzemann (Philippines).

Etymology. Trolicaphyllium meaning “leaf that walks noiselessly”. This generic epi-
thet is a compound of the Latinized name Phyllium the type genus for the family
(from Greek gudor, -ov (phyllon, -oy) + -um; Poitout 2007), coupled with the prefix tro
lica from the Drehu (Dehu) language phrase which means “walk noiselessly” (Tyron
1967). We wished to honor the original inhabitants of this area by using a local tradi-
tional language. We chose this name because these beautiful insects are so elusive and
noiselessly living in the trees where they are often overlooked. This new genus is neuter
in gender, following Phyllium.

Distribution. At present Trolicaphyllium gen. nov. specimens are only known from
the country of New Caledonia, with records from Grande Terre, Lifou, Tiga, Maré, Ile
de Bélep, and Uile-des-Pins islands (Fig. 21). Likely other islands may also be suitable,

but we have yet to locate specimen records from museums or observations.

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 17

Trolicaphyllium brachysoma (Sharp, 1898), comb. nov.
Figures 14, 22, 24, 25

Material examined. (35 2 9, 11 6, 2 unsexed nymphs): Syntypes (2 9.2): “Phyllium
(Chitoniscus) brachysoma. Type D.S. Lifu. Dr. Willey. 1897” and “Phyllium brachysoma.
Type ex parte. D. Lifu. Willey. 1897” (CUMZ; Fig. 22). See Suppl. material 1 for
additional specimens reviewed, their collection data, and depositories.

Remarks. ‘This was the first phylliid species recorded from New Caledonia and was
therefore the first described Trolicaphyllium gen. nov. species, consequently, we here
designate it as the type species for the new genus. Additionally, it was chosen as it has ac-
ceptably accurate collection data (Lifou Island; a rather small island instead of a general
locality from the larger main island, which possibly contains several species) thereby re-
moving some degree of possible confusion which could surround such old and difficult
to distinguish specimens. ‘This precise locality will allow future reviewers with adequate
material sampled from numerous islands to identify species boundaries and determine
if this species ranges across New Caledonia or if it is restricted to Lifou Island.

The syntype females were collected by Dr. Arthur Willey in 1897 while he was liv-
ing on Lifou Island (Fig. 23; Sharp 1898). Dr. Willey was traveling and living in New

R1

Figure 14. Male tegmina and alae venation Trolicaphyllium cf. brachysoma comb. nov. (Coll RC 16-094).
Abbreviations: C (costa); Sc (subcosta); R (radius); R1 (radius 1); R2 (radius 2); Rs (radial sector); M (media);
MA (media anterior); MP (media posterior); MP1 (first media posterior); MP2 (second media posterior);

Cu+MA+MP (fused cubitus, media anterior, and media posterior); Cu (cubitus); Cu+1AA (cubitus and first
anterior anal); 1A (first anal); LAA—7AA (first—seventh anterior anal); 1PA—5PA (first—fifth posterior anal).

18 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Figure 15. Comparison of Chitoniscus sensu stricto and Trolicaphyllium gen. nov. eggs A—C Trolicaphyl-
lium sarrameaense comb. nov., imaged by TB of eggs from Coll DG A dorsal B lateral C opercular (ante-
rior) D-F Chitoniscus sp. “Suva” (RC Coll 18-272) D dorsal E lateral F opercular (anterior).

Figure 16. Scanning electron micrographs of specialized chorionic structures of the eggs A—C Trolicaphyl-

lium sarrameaense comb. nov. D=F Chitoniscus sensu stricto A, D overview of micropylar plate B, E detail

of micropylar plate C, F micropylar cap. Scale bars: 300 um (A, D), 100 um (B, E, F), 50 um (C).

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 1g

Figure 17. Scanning electron micrographs of chorionic microstructures on the eggs A=D Trolicaphyl-
lium sarrameaense comb. nov. E=H Chitoniscus sensu stricto A, B mushroom-like granula C, D, G, H sur-

face microsculpture C surface of the granula D exochorionic surface microstructures E, F pinnae. Scale

bars: 100 pm (A, E), 20 um (B, F), 10 um (G), 5 um (D), 3 um (H), 1 pm (C).

A B

Figure 18. Illustrations of freshly hatched nymphs for comparison, dorsal habitus. Illustrations by Liz
Sisk (USA). Nymph size is approximated to be relative to each other based upon the few photographs avail-
able but is only an estimate A Trolicaphyllium sarrameaense comb. nov.; overall nymph length from head
to tip of abdomen approximately 7 mm (Gréfer 2008b); illustration based upon photographs from Detlef
Gréfer (Germany) B Chitoniscus sp. “Suva” based upon images supplied by Mayk de Haan (Belgium).

Britain, New Hanover, eastern New Guinea, and Lifou Island between 1895 and 1897
in search of living Pearly Nautilus colonies which he could capture, collect eggs from,
and rear through development in order to study their embryology (Wiley 1899; Kerr
1943). Although his years of expedition yielded many great discoveries of which he

20 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Figure 19. Captive bred Trolicaphyllium sarrameaense comb. nov. dorsal, habitus, female reared and
photographed by Detlef Gréfer (Germany).

published prolifically, he was unfortunately unsuccessful in his primary goal of rearing
eges to maturity (Willey 1899). Willey lived on the west coast of Lifou Island on “San-
dal Bay” (modern Santal Bay) from July 1896 to March 1897; and while no exact date
was given with the syntype set of females, they are noted as being collected in 1897.
Therefore, they are from the beginning of the year (January through March), and most
likely from late January when a severe gale passed through the area (wreaking havoc
on his Nautili traps; Kerr 1943) which likely knocked the phylliids from the canopy
enabling them to be found by Dr. Willey. While males occasionally will fly to lights

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 2

x

Figure 20. Trolicaphyllium sarrameaense comb. nov. eggs showing the variation in coloration, photo-
graphs by Sylvie Cazeres (IAC), eggs laid by females from Vallée Pierrat, Commune de La Foa A lighter
colored eggs B first five eggs laid by the female from Figure 3.

3X Trolicaphyllium brachysoma
d. | @ Trolicaphyllium brachysoma
| * Trolicaphyllium sarrameaense
® Trolicaphyllium sarrameaense
xX Trolicaphyllium sp.
©) Trolicaphyllium sp.
* Trolicaphyllium erosus

lle de Bélep

L‘lle-des-Pins

Figure 21. Distribution map noting all presently known Trolicaphyllium gen. nov. records which could
be traced and accurately noted. See Suppl. material 1 for full details for all records presented. Stars indi-
cate a record based upon a specimen, circles represent a record based upon a photographic observation.

Produced with SimpleMappr (Shorthouse, 2010).

at night, females and nymphs are most often only found on the ground after storms
when they are knocked from their typical canopy habitat and found lower (Brock and
Hasenpusch 2003, 2015).

22 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

No etymology was given by Sharp, but it can be assumed that he chose brachysoma
to denote the size of the species, from the Greek words brachy- (short) and -soma (body).

Differentiation. For female Trolicaphyllium brachysoma comb. nov., one feature
which appears to differentiate this species from the other two is the abdominal shape,
which is lobeless, and tapered, giving them a spade-shaped appearance. It is worth
noting however that in many phylliids abdominal shape is often a poor feature for dif-
ferentiation as it is often variable within a single species (Cumming et al. 2020b), and
even in the syntype set of two females, one female is notably more tapered (Fig. 22B)
than the other (Fig. 22A). Trolicaphyllium brachysoma, comb. nov. is about the same
size as Trolicaphyllium sarrameaense comb. nov. (ca. 60 mm) which can differentiate
them from Trolicaphyllium erosus comb. nov. which are notably smaller (ca. 40 mm).

Correctly matching up male and female phylliids is frequently a significant chal-
lenge due to their elusiveness in nature and sexual dimorphism and therefore opposite
sexes can only be confirmed through molecular comparison or captive rearing (Cum-
ming et al. 2020c; Cumming et al. 2021). Unfortunately, we have yet to confidently
confirm a male Trolicaphyllium brachysoma comb. nov. and therefore, at this time can
only illustrate presumed males (Fig. 24) which follow the morphology of the female by
having a smooth tapered abdomen and falling within an appropriate size range for a
potential male (38 to 43 mm). Trolicaphyllium erosus comb. nov. has no presumed male

records we are aware of (as no possibilities have been located in collections which are

f ws

Phylliuns « Aline As
brackysonta .
Type DS, 10mm

obi fu. Dr. Wilkeg- 18 ——=

Figure 22. Syntype females of Trolicaphyllium brachysoma comb. nov. the herein designated type species
for the new genus. Photographs by Paul Brock (United Kingdom) of the set within the CUMZ A dorsal
habitus with tegmina spread; note the lack of developed alae B dorsal habitus with tegmina closed.

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 25

Figure 23. A Arthur Willey (1867-1942), collector of the Trolicaphyllium brachysoma comb. nov. fe-
males in 1897 from Lifou Island while searching for the Pearly Nautilus; image used from the public
domain due to expired copyright; from Kerr (1943) B Lifou, cliffs on the north end of the island slightly
farther north of where Willey was stationed 1896-1897; photograph by user Bahnfrend in Novem-
ber 2007; used under Creative Commons 3.0 (CC BY-SA 3.0) (https://commons.wikimedia.org/wiki/
File:Jokin,_Lifou,_2007_(4).JPG).

small enough to represent a male of this species) but based upon female size the male
Trolicaphyllium erosus comb. nov. is likely rather small.

Distribution. The type locality for this species is Lifou island, but brachysoma-
like specimens with the tapered, lobeless abdomen have been found on Grande Terre
(Fig. 21) and LIle-des-Pins (Fig. 25) as well. Additionally, within the MNHN there
is a female which was collected on Ile de Bélep, which is the only phylliid record we
have seen from this island, and we only tentatively note this specimen as this species
as it has slight lobes on the abdomen and could not be examined in person. Hopefully
future molecular analyses with material from multiple islands will reveal if these are all
one species or several.

Trolicaphyllium erosus (Redtenbacher, 1906), comb. nov.
Figures 26, 27

Material examined. (10 9 9): Syntypes (2 9 9): “Syntype; MNHN-EO-PHAS1018;
Museum Paris Nelle Caledonie Canal Woodia Dr. Francois 783-92. Chitoniscus erosus

24 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

10 mm

Figure 24. Dorsal habitus of male Trolicaphyllium cf. brachysoma comb. nov. A Bouloupari Commune,
March 2013 (Coll RC 16-095) B Sarramea Commune, February 2009 (Coll RC 16-094).

Kaateu (New Caledonia) in November 2020 A dorsal, habitus B same individual as in A but zoomed out

to give scale/perspective.

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 25

* "i gpathngetehatabrn cine crsliiniatst ft”

a r é
: / *
Lhe tberjne cued

LAAT 4
Hive -
Arcus yt Vian
pee. é és £) @

Ween PARIS | |

Crkecler te
Woolen :
Dt From cot |

pot 92.

MNHN-EO-PHAS1018

Figure 26. Trolicaphyllium erosus, comb. nov. syntype specimen from the MNHN collection. Photo-
graphs by: Emmanuel Delfosse (MNHN) A habitus, dorsal B habitus, ventral. Associated data labels
inserted between and to the right.

Redt.; Chitoniscus erosus Redtb. Brunner det. 1900” (MNHN;; previously stored in al-
cohol, Fig. 26); “Coll. Brv.W. Neu Caledon Deyrolle; det. Redtenb Chitoniscus erosus;
4738” (NHMW; Fig. 27).

See Suppl. material 1 for additional specimens reviewed, their collection data, and
depositories.

Remarks. This was the second species described from New Caledonia and was
described by Redtenbacher (1906) where he gave little to differentiate the species from
Trolicaphyllium brachysoma comb. nov. except for the abdominal shape and the overall
size as being smaller.

Within the original description by Redtenbacher the number of syntypes was
vague, but at least three are explicitly stated as “New Caledonia (Coll. M., Mus. Paris);
New Guinea (Mus. Budapest)” (Redtenbacher 1906). At least one syntype was within
Redtenbacher’s own collection (noted as “Coll. M.” within his work) and eventually
his collection was deposited in Vienna where it resides today, and the specimen could
be traced (Fig. 27; Kaltenbach 2003). Additionally, he states at least one syntype from
the “Mus. Paris” which has also survived and was traced (Fig. 26).

An additional syntype was explicitly noted as a nymph within the Budapest Muse-
um (with the wording suggesting that there is only one syntype within that collection).
Unfortunately, a fire during the Hungarian Revolution of 1956 destroyed the Budapest
syntype along with many of the museum's important type specimens (Brock 1998;

26 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Figure 27. Trolicaphyllium erosus comb. nov. syntype female originally from the collection of Brunner
von Wattenwyl, then passed on to Redtenbacher, now deposited in NHMW. Photographs by Harald
Bruckner (NHMW) A habitus, dorsal (scale bar only representative of this image) B habitus, ventral
C genitalia detail, ventral D details of the front legs, head, and thorax, dorsal E specimen data labels.

Foldvari and Papp 2007; Sabaj 2020). This syntype within the Budapest Museum was
noted as being a nymph female from New Guinea with large broad forelegs reminis-
cent of “Phyllium pulchrifolium Serv.” (Redtenbacher 1906). Based on this information
it is very likely that this was not actually a Trolicaphyllium gen. nov. specimen as this
genus is restricted to New Caledonia and is only known to have rounded profemoral
lobes. Instead, this nymph specimen was more likely a female Nanophyllium Redten-

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 27

bacher, 1906 of which certain species can be small and reminiscent of Trolicaphyllium
gen. nov. or Chitoniscus specimens but have broader profemoral exterior lobes (for
example Nanophyllium chitoniscoides (Grofer, 1992)).

Within the MNHN there is an adult female syntype specimen collected by Philippe
Francois (Fig. 28) from Canal Woodia (canal de Woodin), a common shipping path
which runs between Ile Quen and the south coast of Grande Terre (Bernard 1894).
The MNHN type database has the specimen reported as being collected sometime in
1892 (based upon the specimen label “-92”), however, this record number appears
to not correspond to the collection year as Francois was not in Oceania 1892. By all
accounts, Francois was actively researching in Oceania from 1888-1891, was back in
France in 1892, and then returned to Oceania from 1893-1895 (Bulletin Scientifique
1909; Dewarumez 2011). We believe that this date on the label instead corresponds
to the date the specimens were received by the museum and was instead collected by
Francois between 1888 and 1889 when he passed through Canal Woodia (canal de
Woodin) several times during his first journey to New Caledonia to study the biology
of coral reefs (Bouyssi 1997).

Interestingly, Redtenbacher only appears to have measured one specimen of the
type series, the one within his own collection (now within the NHMW), most likely
he had seen the Paris and Budapest specimens prior and did not measure them while
reviewing them. Harald Bruckner (NHMW) measured the single syntype within their
collection and it agrees with the measurements recorded by Redtenbacher (Fig. 27).
Interestingly, the smaller overall body length (42.0 mm) appears to be somewhat ar-
tificial as the abdomen is significantly excavated and somewhat ballooned outward,
pulling the abdomen shorter (Fig. 27C). This is supported by the observation that the
other features of this specimen (such as the tegmina length; 27 mm) are actually closer
to average sizes for other Trolicaphyllium gen. nov. specimens of other species. Realisti-
cally it seems this specimen if it were naturally flat might actually be closer to a range
of 50 mm, and not significantly smaller after all.

No etymology was given in the original description, but it can be assumed that
Redtenbacher was referencing the lobed abdominal shape with erosus, from the Latin e-
(out/away from) and -vosus (gnaw/peck), noting that the leaf-like body appears gnawed
on, giving it the undulating appearance.

Differentiation. To date this appears to be the least known species on New Cale-
donia as we have not been successful in tracing any additional females which fall within
this small size range of ca. 40 mm beyond one of the syntypes. All specimens examined
so far appear to belong to the other species with their larger size (ca. 50-60 mm).
In fact, it is only this smaller size which we have found as useful for differentiation
as the other features match up with the prominently lobed Trolicaphyllium sarrame-
aense comb. noy. females. The additional specimens identified as Trolicaphyllium erosus
comb. nov. within the MNHN are larger than the syntype within the NHMW and
several are rather morphologically similar to Trolicaphyllium sarrameaense comb. nov.
due to their larger size and lobed abdomen but are at this time tentatively left identified
as Trolicaphyllium erosus comb. nov. within the collection.

28 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Figure 28. Philippe Francois the collector of one of the syntype Trolicaphyllium erosus comb. nov. females

from within the MNHN collection A photographed in Vanuatu sometime between 1888 and 1895; used
with permission from Tajan (Tajan 2002) B later in life back home in Paris, France where he reviewed

many of the specimens he brought back from his expeditions (Bulletin Scientifique 1909).

Additionally, we have yet to locate any possible male Trolicaphyllium erosus comb. nov.
as all males located were much too large and appear to belong to the other two species.

Distribution. The only specimen we have located with detailed locality informa-
tion is the syntype female from the MNHN collection which has the additional in-
formation of “Canal Woodia” which is a small canal between Ile Ouen and the south
coast of Grande Terre (Fig. 21). The additional non-type specimens from the MNHN
are included within the distribution map, but only tentatively as they are slightly larger
than the measured syntype from NHMW and they have variable abdominal shapes,

some more strongly lobed than others.

Trolicaphyllium sarrameaense (Grofer, 2008), comb. nov.
Fiouires (15.3345, 4G, 5ASC. GAs eV ASSACOA OA TAS I2B., 138, Bal SASC,
16A—C, 17A—D, 18A, 19, 20, 29

Material examined. (8 29, 9 do, 3 eggs): Holotype and paratypes examined: 1
Of. 1653 eggs: “Chitoniscus, sarrameaensis, Neu Kaledonien, Sarramea, Sep. 2006,
det.Gréfer” (SDEI: HT 2, DEI Hemimetabola #100215; PT, DEI Hemimetabola
#100214; PT eggs, DEI Hemimetabola #100216); (SDEI; Figs 7A, 8A, 13A, B, 29).

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 29

See Suppl. material 1 for additional specimens reviewed, their collection data, and
depositories.

Remarks. As it was only described in 2008, this was the most recently described
species from New Caledonia with type material originally collected by Sigetake Su-
zuki in 2004 from Sarramea (Grofer 2008a). Within the original description this spe-
cies was not explicitly compared with the sympatric and morphologically very similar
Trolicaphyllium erosus comb. nov. but was instead only differentiated from Chitoniscus
lobipes Redtenbacher, 1906, where most features given for differentiation were simply
the features we discuss above as significant for differentiating the two genera.

Other lobed specimens have been recovered from throughout New Caledonia,
but unfortunately most have been nymphs (such as several from within the QM col-
lection) and therefore they could not be confidently identified as Trolicaphyllium sar-
rameaense comb. nov. or as Trolicaphyllium erosus comb. nov. nymphs. Unfortunately,
in GrofSer (2008b) the key to species of Chitoniscus sensu lato tried to use the female
tegmina radial and media venation pattern to differentiate species, but mixed up the
species. Within the key Trolicaphyllium erosus comb. nov. and Trolicaphyllium brachy-
soma comb. nov. (from New Caledonia) instead key out as the Fijian population and
Chitoniscus lobiventris (Blanchard, 1853) and Chitoniscus lobipes Redtenbacher, 1906
(from Fiji) key out as the New Caledonian population. We have reviewed the type
specimen photos available on the Phasmid Species Files (Brock et al. 2021; http://
phasmida.speciesfile.org) as well as numerous museum specimens, and always the fe-
male tegmina venation allowed accurate distinction of these two genera. Even if you
look past this inaccuracy within the key, unfortunately no additional features can be
gleaned from the further couplets to allow differentiation of Trolicaphyllium sarrame-
aense comb. nov. from Trolicaphyllium erosus comb. nov. (as the further couplets discuss
abdominal shape, which in these two species is identical/variable). At this moment
in time, we still lack significant details about the population of Trolicaphyllium gen.
nov. on Grande Terre as material is limited and molecular data has yet to be compared
across a wide sampling on the island. With phylliid abdominal shapes sometimes rath-
er variable within a single species, this makes us wonder if Trolicaphyllium sarrameaense
comb. nov. is in fact a valid species, or simply a synonym of Trolicaphyllium erosus
comb. nov. which was described more than 100 years previously from the same island.
Our examination of all type specimens which could be traced has not yet revealed ad-
ditional features for morphological differentiation besides the overall size of these two
species. Hopefully, future molecular analyses from across New Caledonia will reveal
if there are several species present on Grande Terre or if it is simply a single species
which can range in size from smaller (ca. 40 mm; Trolicaphyllium erosus comb. nov.)
to larger (ca. 60 mm; Trolicaphyllium sarrameaense comb. nov.). It is due to this lack of
sound molecularly based evidence and the propensity for phylliids to be morphologi-
cally variable that we refrain from synonymizing Trolicaphyllium sarrameaense comb.
nov. with Trolicaphyllium erosus comb. nov. as we feel a significant decision such as this
should be based upon a solid foundation. If future molecular analyses reveal that there
is only a single morphologically variable species of Trolicaphyllium gen. nov. on Grande

30 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Figure 29. Dorsal habitus Trolicaphyllium sarrameaense comb. nov. A holotype female (#100215)
B paratype male (#100214). Photographs by Arne Kéhler (SDEI). Scale bar: 10 mm.

Terre based upon a sampling throughout the island, then we feel a synonymization will
be necessary, but not until that time.

The etymology given in the original description is that this name is a toponym,
named after the type locality, Sarramea, New Caledonia (Grofer 2008a). The original
combination was with the masculine genus (Chitoniscus) and therefore in order for the
species name to agree in gender with our newly erected genus, the spelling of “sarrame-
aensis’ is changed to the neuter gender “sarrameaense’ .

Differentiation. Females can be differentiated from Trolicaphyllium brachysoma
comb. nov. based upon abdominal shape, as Trolicaphyllium brachysoma comb. nov. are
considered to have a spade-shaped abdomen, with smooth margins, versus Trolicaphyl-
lium sarrameaense comb. nov. which has a broad abdominal shape with parallel sides,
ending in lobed segments VII and VUI. From Trolicaphyllium erosus comb. nov. the

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 31

Pa aa w -

: <
na MD ierr oe. ee
. TS fe ed 2
PIE i ae gah

we ae ee

Figure 30. Live nymphs of Trolicaphyllium gen. nov. which could not be identified to species. Im-
ages from https://endemia.nc and used under creative commons license (CC BY-NC-SA 4.0) A Frédéric
Desmoulins, Plaine des Lacs, April 2014 B Hendrik Oesterlin, Koé (Dumbéa) elevation 185 meters, June
2006 C Julien Barrault, Hienghéne, November 2010 D Daniel and Iréne Létocart, Tchamba, October
2009 E Bernard Suprin, Dumbéa, April 2004 F Gildas Gateblé, Ouenghi, October 2012.

32 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

> / ies
*

if aa AN -
Figure 31. Unidentifiable Trolicaphyllium gen. nov. male nymph photographed on Tiga Island in August

a

=

2020 by Damien Brouste (New Caledonia) (iNaturalist user: damienbr) A dorso-anterior view B same

nymph, dorsal habitus C unidentified host plant on which the nymph was recorded.

only feature we have been able to identify as useful is the overall length, with Trolica-
phyllium erosus comb. nov. ca. 40 mm long versus Trolicaphyllium sarrameaense comb.
nov. ca. 60 mm long.

Unfortunately, males of Trolicaphyllium brachysoma comb. nov. and Trolicaphylli-
um erosus comb. nov. have never been confidently confirmed through breeding or mo-
lecular comparison. Based upon the confidently confirmed male/female Trolicaphyl-
lium sarrameaense comb. nov. however, we expect that the male morphology should
mirror the female morphology. Most likely the male Trolicaphyllium brachysoma comb.
nov. will lack prominent abdominal lobes and the male Trolicaphyllium erosus comb.
nov. will have distinct lobes to match with their female counterparts. Based upon the
female Trolicaphyllium erosus comb. nov. smaller size, we expect that the male must also
be rather small, which could likely be used as a feature for differentiation.

Distribution. To date we have only confirmed adult specimens and observations
which are the correct morphology and size of Trolicaphyllium sarrameaense comb. nov.
from central Grande Terre (Fig. 21). We have however seen nymph specimens which had
characteristically lobed abdomens which may represent this species from other locations
on Grande Terre, so we expect this species may be widespread throughout the island.

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 33

Within the MZPW collection there is a pair of Trolicaphyllium sarrameaense comb.
nov. specimens with the data of simply “Lifu”, which if true could lend credibility to
the hypothesis that perhaps these species are all variable in their abdominal shape (if
there is only one species present on Lifou island), but as these are antique and give
no other data, we do not take these as highly credible, and therefore exclude this re-
cord from further discussion and they are not included within the distribution map
(Fig. 21). Or it is possible Lifou island holds several morphologically different species.

Discussion

Generic identity

With significant confusion surrounding the distribution of Trolicaphyllium gen. nov.
species in New Caledonia (due to apparent intraspecific variation and sexual dimor-
phism), this leaves many records as unidentifiable to species (see Suppl. material 1).
Additionally, many records we have seen are of nymphs, which are rather difficult to es-
timate final adult morphology from (Fig. 30). These many records are still rather inter-
esting as they can help to clarify the distribution of this New Caledonian endemic genus
(Fig. 21). For example, a singular record of a male from the AMNH which was collected
by Lindsay Macmillan on Maré Island during the Whitney South Sea Expedition and
recorded as a “mantis” within the expedition journal, was located within the unidenti-
fied Mantodea drawer within the AMNH collection by the first author and represents
one of only two records we have seen to date from this island (Macmillan 1938).

With phylliids typically rather island endemic, it is uncertain at this point if the
records from Tiga (Fig. 31) and Maré islands are a currently described species (repre-
senting a range expansion), or if they are yet to be described species. The latter is pos-
sible given that no species have yet been described from these islands. Unfortunately,
neither of these records could be sequenced as one was observational and the other
too old to sequence, therefore little can be gleaned at this time regarding these islands.
With Trolicaphyllium gen. nov. records known from Grande Terre, Lifou, Tiga, Maré,
Ile de Bélep, and Lile-des-Pins islands, we expect that possibly other small islands in
New Caledonia such as Ouvéa may also have populations, but to date we are not aware
of any observational records or specimens from additional islands (Fig. 21). Hopefully,
future sequencing of museum specimens and additional local efforts to sample these
smaller islands such as Lifou (which will be necessary as it is the type locality for Troli-
caphyllium brachysoma comb. nov.) will reveal the true distribution of Trolicaphyllium
gen. nov. species in New Caledonia. Of particular use will likely be immature nymph
specimens present within many museum collections which although not very useful
for morphology, significantly increase the molecular data if sequenced and can add
clarity to species boundaries/intraspecific sequence variation.

Only now are the higher-level relationships within the phylliids being explored,
with the most likely sister group to Trolicaphyllium gen. nov. appearing to be the

34 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

Comptaphyllium (Bank et al. 2021). Geographically speaking, one possibility for “fill-
ing in this missing gap” between the New Caledonian clade and the Comptaphyllium
could be Pulchriphyllium groesseri (Zompro, 1998), a morphologically unique species
known only from the Solomon Islands between New Guinea and New Caledonia.
This species is only tentatively placed within the Pulchriphyllium due to the presence
of exterior lobes on the tibiae and similar tegmina venation, but due to the lack of
fresh material to sequence, this species has not yet been included within any molecular
phylogenies. Due to the similar body size and abdominal shape to certain Trolicaphyl-
lium gen. nov. species we wonder if Pulchriphyllium groesseri may indeed be related
and could geographically link these two genera, therefore giving more clarity to the
relationships within this group.

Additionally, geographically, it is possible that Vanuatu to the north of New Cal-
edonia also has suitability for phylliids and may have been part of their route of coloni-
zation to modern day New Caledonia assuming an origin of New Guinea for modern
phylliids (Bank et al. 2021). Interestingly however, to date Vanuatu lacks phylliid re-
cords which could be used as reference and no museum specimens have been located.

Morphologically it is not uncommon within the phylliids for single species to be
rather variable within their abdominal shape, ranging from tapered, smooth and boxy,
weakly lobed, to strongly lobed (Hennemann et al. 2009; Cumming et al. 2020b).
Review of every museum specimen we could locate has shown a significant variabil-
ity within the abdominal shape of many nymphs and multiple adults. We hope that
future molecular reviews of Trolicaphyllium gen. nov. specimens of variable morphol-
ogy from throughout Grande Terre and the surrounding islands will reveal how many
species there likely are in New Caledonia. Within phylliids there appears to be vastly
differing limits geographically for how far a single species will range, with numerous
examples of island endemics (e.g., Cumming et al. 2018, 2019a, 2020a) as well as
instances of single species spanning extensive geographic ranges (e.g., Cumming et al.
2020a, 2021). It is possible with Trolicaphyllium brachysoma comb. nov. known from
Lifou, and the others from Grande Terre, that there are at least two species (at least
one from each island) and we hope that future molecular review of a wide sampling
of specimens will reveal species geographic boundaries with more clarity. If molecular
reviews of numerous specimens from Grande Terre reveal only a single morphologi-
cally variable species on Grande Terre, this would likely mean that only two species
as presently known would be warranted Trolicaphyllium brachysoma comb. nov. from
Lifou and Trolicaphyllium erosus comb. nov. from Grande Terre, with Trolicaphyllium
sarrameaense comb. nov. a junior synonym of Trolicaphyllium erosus comb. nov. Hope-
fully, future molecular reviews will help clarify the Trolicaphyllium gen. nov. diversity
within New Caledonia.

Functionally relevant morphological characters

Some morphological features separating Chitoniscus sensu stricto and Trolicaphyllium
gen. nov., namely tarsal and egg morphology, can shed further light on the evolutionary

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia iB)

history of these groups, as the morphological difference can be a result of adaptations
that accompany the process of speciation. ‘Their functional relevance can highlight the
functional constraints which led to the specific morphological traits. The overall tarsus
morphology in phasmids in general and in Phylliidae in particular is quite conserved,
but the differences found are probably results of adaptations to the specific environ-
ments of the species (Biischer and Gorb 2017; Biischer et al. 2018a, b). While the male
tarsus of both groups is similar and not different in morphology when compared to
other Phylliidae (Biischer et al. 2019), the female tarsi differ in one functional feature.
The tarsi of Trolicaphyllium sarrameaense com. nov. females bear an extension in form
of a median ridge of the euplantulae on the tarsomeres 2—4 (Fig. 12B), which is so far
not reported for any other phasmid in this form. This accessory ridge can elongate the
adhesive surface of the tarsus distally and increase traction along the length of the tar-
sus, as euplantulae are primarily used for generation of friction in phasmids (Busshardt
et al. 2012; Labonte and Federle 2013; Biischer and Gorb 2019; Biischer et al. 2020a).
However, the arrangement of the euplantulae stabilizes the attachment primarily in
the proximal-distal direction, which could be beneficial in the typical postures of these
insects in which their legs are arranged circular around the stout body. Furthermore,
the elongation of the tarsal chain increases traction on thin stems, if the tarsi grasp
around the substrate (Biischer et al. 2020a). A similar effect is additionally achieved
by the accessory euplantula on tarsomere 5. This feature is consistently present in all
investigated Phylliidae but lacking in many other phasmid species (Vallotto et al. 2016;
Biischer et al. 2019).

The eggs of both groups differ significantly in the modification of their exochori-
onic surface. While Trolicaphyllium gen. nov. bear distinct microscopic spherical struc-
tures on the surface of the eggs (Fig. 17A—D), the eggs of Chitoniscus sensu stricto
have a rough, porous surface. These surfaces can be fundamentally different in their
function. The spherical structures might be water and dirt repellent, while the rough,
porous surface can facilitate water spreading or uptake (Watson et al. 2017). These
functions, however, need to be tested in subsequent studies to corroborate their po-
tential benefits.

The presence or absence of pinnae and their respective morphology have been
shown to be of taxonomic value for the eggs of Phylliidae already (Clark 1978; Cum-
ming et al. 2020a), this feature, however, is also of striking functional relevance (see.
Biischer et al. 2020b, c). The exochorionic pinnae of the eggs of Phyllium philippini-
cum are involved in a water responding adhesive system that attaches the eggs to dif-
ferent surfaces (Biischer et al. 2020b). Similar fringe-like expansions on their egg shells
are reported for other phylliid eggs and hypothesized to be involved in adhesion as well
(Biischer et al. 2020c). Due to their similarity in morphology, it is highly likely that
the eggs of Chitoniscus sensu stricto provide the same adhesive capability. These struc-
tures probably also carry a glue and expand when they come in contact with water and
distribute glue on the corresponding surface. Whether the mushroom-like elements on
the surface of Trolicaphyllium gen. nov. eggs provide adhesion and how their potential
adhesion responds to water is so far unknown and could be tested in subsequent stud-

36 Royce T. Cumming et al. / ZooKeys 1055: 1-41 (2021)

ies. This could also yield a more elaborate analysis of the evolution of adhesion in the
eges of Phylliidae including closely related lineages with different pinna morphologies.

To conclude, despite more than a century of considering the Fijian and New Cal-
edonian phylliids a single genus, we herein adjust the taxonomy of this polyphyletic
clade. Our erection of the Trolicaphyllium gen. nov. reflects the unique aspects of the
species of New Caledonia as distinct from their previously considered congenerics
(Chitoniscus sensu lato).

Herein we have addressed the several questions presented in the introduction regard-
ing these two groups of leaf insects. Firstly, although these clades are in general similar
due to their smaller size and abdominal shapes ranging from smoothly tapered to boxy
and strongly lobed, a thorough review of small and microstructures of adults, nymphs,
and eggs present a plethora of morphological features for easy and reliable differentia-
tion (Table 1). Secondly, although molecular data for species from these two countries is
rather limited, all results have been consistent and in agreement with our morphological
findings, with the two clades always corresponding to the geographic distributions (Fiji
always sister to the greater leaf insects and New Caledonia a distinct clade nested within
the greater phylliids). Thirdly, based upon our review, we assessed what taxonomic op-
tion would most clearly correct this issue. With such drastically different morphologies
for these two clades, as well as their unique morphologies from all other extant phylliids,
our most transpicuous taxonomic path was for clarifying these as genera.

Therefore, based upon years of molecular results, dozens of morphological features,
and the significant geographic isolation for these two clades of leaf insect, we feel that
the erection of Trolicaphyllium gen. nov. properly addresses the many discrepancies
which were glaringly problematic with the Chitoniscus sensu lato.

Acknowledgments

Thank you to the many photographers who shared great live images of phylliids with
us: Albert Kang (Malaysia), Thierry Heitzmann (Philippines), Patrice Kaateu (New
Caledonia), Thierry Salesne (New Caledonia), Detlef GrofSer (Germany), Thomas
Buckley (New Zealand), Damien Brouste (New Caledonia), Mayk de Haan (Belgium),
Sylvie Cazeres (IAC), and Christian Mille (IAC). Thank you to the many contributors
who posted images of Trolicaphyllium on https://endemia.nc which allowed review of
variable morphology as well as a better understanding of the distribution of species: Fré-
déric Desmoulins, Hendrik Oesterlin, Julien Barrault, Daniel and Iréne Létocart, Ber-
nard Suprin, Gildas Gateblé, Christian Siroux, Jacques Dangio, Nicolas Petit, Christine
Poellabauer, and Geoff Monteith. Thank you to the many people who sent us images of
museum specimens for review: Jessa Thurman (Australia), Susan Wright (QM), Miho
Maeda (BPBM), Jerilynn Chun (BPBM), James Boone (BPBM), Arne Kohler (SDED),
Paul Brock (NHMUK), Harald Bruckner (NHMW), Seraina Klopfstein (NHMB), Pe-
ter Schwendinger (MHN), and Emmanuel Delfosse (MNHN). Thank you to Stanislav
N. Gorb (Functional Morphology & Biomechanics, Kiel University) for enabling the
acquisition of multiple SEM images used within this work. Thank you to Paul Brock

Polyphyly of Chitoniscus resolved with new genus endemic to New Caledonia 37

(United Kingdom) for thoughtful discussion on the Redtenbacher type specimens.
Thank you to Christine Rollard (MNHN) who shared notes on Philippe Francois with
us. Thank you to Tony Robillard at (MNHN) for checking the museum logbooks for
information regarding the syntype 7! erosus females from “Canal Woodia’. Thank you
to Mark Youles (United Kingdom) and Scott Kirkland for helping to identify the type
locality for one of the syntype T° erosus females from “Canal Woodia’. Thank you to
Tajan Auction House (Paris, France) for sharing a wonderful photograph of Philippe
Francois. Thank you, Amélie Saint-Marc (Campus Condorcet, Paris-Aubervilliers,
France) for scanning and sending us selected pages from the archived work within
your collection; this was instrumental in learning more about the syntype from Canal
Woodin collected by Philippe Francois. Thank you to René Limoges (Canada) for tak-
ing many photographs for this work, as well as for many professional courtesies. Thank
you to our scientific illustrator Liz Sisk (USA) who did a beautiful job of illustrating
the freshly hatched nymphs for us as no image correctly captures the morphology since
nymphs always hold their abdomen or little legs at all angles and seem to be always
moving. We thank Michel Saint-Germain, head of collections and research and Maxim
Larrivé, director of the Montreal Insectarium for their support of our research.

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Supplementary material |

Table S1. Material examined (specimen data and deposition/ observational re-

cords) for localities used within the distribution map (Fig. 21) and to accompany

the discussion of each species

Authors: Royce Cumming, Stéphane Le Tirant, Thies H. Biischer

Data type: specimen data

Copyright notice: This dataset is made available under the Open Database License
(http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License
(ODDbL) is a license agreement intended to allow users to freely share, modify, and
use this Dataset while maintaining this same freedom for others, provided that the
original source and author(s) are credited.

Link: https://doi.org/10.3897/zookeys.1055.66796.suppl1