Biodiversity Data Journal 6: e22676 oO)
doi: 10.3897/BDJ.6.e22676 open access
Single Taxon Treatment

Unique extrication structure in a new megaspilid,

Dendrocerus scutellaris Trietsch & Miko
(Hymenoptera: Megaspilidae)

Carolyn Trietsch?, Istvan Mik6*, David G. Notton$, Andrew R. Deans*

+ Frost Entomological Museum, Penn State University, University Park, PA, United States of America
§ Natural History Museum, London, United Kingdom

Corresponding author: Carolyn Trietsch (cut162@psu.edu)
Academic editor: Jose Fernandez-Triana
Received: 30 Nov 2017 | Accepted: 22 Jan 2018 | Published: 30 Jan 2018

Citation: Trietsch C, Mik6 |, Notton D, Deans A (2018) Unique extrication structure in a new megaspilid,
Dendrocerus scutellaris Trietsch & Miké (Hymenoptera: Megaspilidae). Biodiversity Data Journal 6: e22676.
https://doi.org/10.3897/BDJ.6.e22676

ZooBank: urn:lsid:zoobank.org:pub:1E3054A2-A8F5-4E4C-81C1-848991B15B6E

Abstract

Background

A new species, Dendrocerus scutellaris Trietsch & Miké (Hymenoptera: Megaspilidae), is
described here from male and female specimens captured in Costa Rica. This species is
the only known ceraphronoid wasp with a straight mandibular surface and raised dorsal
projections on the scutellum, called the mesoscutellar comb. It is hypothesised that the
function of the mesoscutellar comb is to aid the emergence of the adult from the host,
especially since the mandibles lack a pointed surface to tear open the pupal case. The
authors also provide phenotypic data in a semantic form to facilitate data integration and
accessibility across taxa and provide an updated phenotype bank of morphological
characters for megaspilid taxonomic treatments. In updating this phenotype bank, the
authors continue to make taxonomic data accessible to future systematic efforts focusing
on Ceraphronoidea.

© Trietsch C 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 Trietsch C et al

New information

A new species, Dendrocerus scutellaris (Hymenoptera: Megaspilidae) Trietsch & Miko, is
described from both male and female specimens captured in Costa Rica.

Keywords

Ceraphronoidea, morphology, systematics, taxonomy, eclosion

Introduction

Ceraphronoidea is a relatively small superfamily of parasitoid wasps with a worldwide
distribution (Johnson and Musetti 2004). The superfamily is composed of two extant
families: Ceraphronidae and Megaspilidae. Dendrocerus Ratzeburg, 1852 is the second
most diverse megaspilid genus with approximately 118 species described worldwide.
Dendrocerus is also the most well-known megaspilid genus due to the agriculturally
relevant species D. carpenteri (Curtis, 1829), which is used as a model organism to study
parasitoid behaviour and ecology (Chow and Mackauer 1999, Mackauer and Chow 2015,
Mackauer 2017, Nakashima et al. 2016, Schworer et al. 1999), but much work remains to
be done on the life history and taxonomy of the group.

Eclosion is the adult emergence from the pupal case in holometabolous insects. In most
holometabolous insects, the tearing of the pupal case is achieved by the movement of the
insect and the increased hemolymph pressure caused by muscle contractions (Gullan and
Cranston 2010, Zdarek and Denlinger 1992). Insects that are also protected by a cocoon or
puparium may cut or push their way out with their mandibles and legs, or rely on
specialized structures such as projections on the head or backward-facing spines on the
dorsal surface of the abdomen (Gullan and Cranston 2010). Packard Jr (1878) reported
spines called the sector coconis present at the base of the forewings in Bombyx mori
(Linnaeus, 1758) and several species of Saturniidae (Lepidoptera) and observed the spine
in use by an emerging Actias luna (Linnaeus, 1758). Abdominal spines and _ frontal
protuberances serving as “cocoon-cutters” have also been reported on male Psychidae
(Lepidoptera); these structures are absent from females, which do not extricate themselves
from the pupal case Davis 1975.

In Hymenoptera, wood-boring families have been observed to have specialised structures
for extricating themselves from the pupal chambers inside wood where they develop
(Vilhelmsen and Turrisi 2011). Ibaliidae, Orussidae and Stephanidae have upward- or
backward-facing cuticular processes situated anterodorsally on the head. Emerging wasps
use these structures to anchor their heads while chewing through wood with their
mandibles, but they could also be used to clear debris or pull themselves through the
wooden galleries (Vilhelmsen and Turrisi 2011). Similar cuticular processes and spines on
the mesosomata of Ibaliidae, Stephanidae, Aulacidae, the cynipoid family Liopteridae and

Unique extrication structure in a new megaspilid, Dendrocerus scutellaris ... 3

the ichneumonid subfamily Rhyssinae may function in the same way (Turrisi and
Vilhelmsen 2010, Vilhelmsen and Turrisi 2011, Van Noort and Buffington 2013, Rousse
and Van Noort 2014). Along with wood-boring families, mesoscutal spines are found in
Platygastroidea (Austin 1984, Johnson et al. 2008); instead of assisting in emergence from
wooden galleries, these spines may assist wasps in emerging from the remains of their
hosts.

Here, a new species is described of Dendrocerus captured in Costa Rica characterised by
the presence of a straight mandibular edge and the mesoscutellar comb, which could aid in
emergence. These two structures have never before been recorded in Ceraphronoidea and
are discussed here for the first time.

Materials and methods

Point-mounted specimens were borrowed from the Natural History Museum (NHMUk) in
London, United Kingdom. Specimen data is provided in Suppl. material 1. All specimen
data was also entered into a Microsoft Excel spreadsheet template from GBIF so that the
data could be published on GBIF using the Integrated Publishing Toolkit (httos://
www.gbif.org/news/82852/new-darwin-core-spreadsheet-templates-simplify-data-
preparation-and-publishing). Specimens are deposited at the Natural History Museum in
London, United Kingdom (NHMUK) and at the Frost Entomological Museum, University
Park, PA, USA (PSUC).

Point-mounted and glycerine-dissected specimens were examined using an Olympus
SZX16 stereomicroscope with an Olympus SDF PLAPO 1XF objective (115x) and an
Olympus SDF PLAPO 2XPFC objective (230 magnification). Blue-Tac (Bostik, Inc.,
Wauwatosa, Wisconsin, USA) and molding clay (Sculpey, Polyform Products Company, Elk
Grove Village, Illinois, USA) was used to stabilise specimens during imaging and
observation. Stacks of bright field images were taken manually on an Olympus CX41
microscope with a Canon EOS 70D camera attached. Images were subsequently aligned
and stacked using Zerene Stacker Version 1.04 Build T201706041920. Figures were
created in Adobe Photoshop elements Version 3.1.

To prepare specimens for male genitalia dissection, metasomata were removed from point-
mounted specimens and cleared with 35% H»Ob> (Alfa Aesar) for 24 hours, then moved to
5% acetic acid (Distilled White Vinegar, Great Value) for 24 hours and subsequently moved
to glycerol for dissection and short-term storage. Dissections were performed with #5
forceps (Rubis 5A-SA, Bioquip) and #2 insect pins (BioQuip). Male genitalia were then
mounted between 1.5 mm thick, 24x50 mm cover glasses and imaged using an Olympus
FV10i confocal laser scanning microscope. Following the methods of Miko and Deans
2013, auto-fluorescence was collected between 470 and 670 nm with three channels
assigned contrasting pseudocolors (420-520 nm, blue; 490-520 nm, green; and 570-670
nm, red). The images were processed in ImageJ (Version 2.0.0-rc-54/1.51g, Build
26f53fffab, Schindelin et al. 2015) using FlJl (Schindelin et al. 2012).

4 Trietsch C et al

For the descriptions of male and female specimens, morphological characters (following
Burks et al. 2016) were scored based on observations of point-mounted and glycerine-
stored specimens. Specimen data, OTU concepts, natural language phenotypes and
images were compiled in the online database MX (http://purl.oclc.org/NET/mx-database)
which was used to render the Diagnosis, Description, Material Examined and Etymology
sections. Anatomical terms follow the Hymenoptera Anatomy Ontology (Yoder et al. 2010).

Semantic statements were generated in Protégé Version 5.0 beta-15 following the methods
of Trietsch et al. (2015). Statements were written in OWL Manchester Syntax (see
examples from Balhoff et al. 2014, Balhoff et al. 2013, Miko et al. 2015, Miko et al. 2014).
All definitions and descriptions of morphological structures were mapped to classes in
phenotype-focused ontologies, including: Hymenoptera Anatomy Ontology (HAO),
Phenotypic Quality Ontology (PATO), Biospatial Ontology (BSPO), OBO Relation Ontology
(RO), Ontology for Biomedical Investigations (OBI) and Information Artifact Ontology (IAO);
these ontologies are available at htip:/Mwww.ontobee.org (Xiang et al. 2011). By
standardising taxonomic data through ontology-based semantic representation, we aim to
facilitate future systematic work by facilitating the integration of taxonomic data sets from
different sources, expediting computerised searches across these data (Balhoff et al. 2013,
Deans et al. 2012, Miko et al. 2014).

All figures, media files, protocols, semantic statements and supplementary files are

available on figshare at https://figshare.com/projects/Unique extrication structure

in a new megaspilid Dendrocerus scutellaris Hymenoptera Megaspilidae Trietsch and
Mik /27007. The taxonomic treatment file generated from MX (Suppl. material 2) and the

OWL file containing all semantic statement annotations (Suppl. material 3) are also

available on GitHub at__https://github.com/hymao/hymao-data/blob/master/
scutellaris semantic statements.owl and https://github.com/hymao/hymao-data/blob/
master/scutellaris mx taxonomic treatment.owl.

Taxon treatment
Dendrocerus scutellaris Trietsch & Mik6, sp. n.

° ZooBank urn:lsid:zoobank.org:act:-FAC23EE4-1B59-48EE-B20A-65472BCD9589

Materials

Holotype:

a. scientificName: Dendrocerus scutellaris; kingdom: Animalia; phylum: Arthropoda; class:
Insecta; order: Hymenoptera; family: Megaspilidae; taxonRank: species; genus:
Dendrocerus; specificEpithet: scutellaris; country: Costa Rica; countryCode: CR;
stateProvince: Guanacaste; verbatimLocality: COSTA RICA: Guanacaste Pr.: Santa Rosa
N. P.: 300m Bosque San Emilio; verbatimElevation: 300m; eventDate: 1985-04-27/5-11;
verbatimEventDate: 27.iv-11.v.1985; eventRemarks: sample SE.6.C. BMNH(E) 2008-87;
individualCount: 1; sex: male; lifeStage: adult; catalogNumber: NHMUK010812028;
recordedBy: D Janzen & |. Gauld; identifiedBy: Carolyn Trietsch; dateldentified: 2017;
language: en; institution|D: http://biocol.org/urn:lsid:biocol.org:col:34665; institutionCode:

Unique extrication structure in a new megaspilid, Dendrocerus scutellaris ... 5

NHMUK,; collectionCode: Insects; basisOfRecord: PreservedSpecimen; occurrencelD:

http://grbio.org/institution/frost-entomological-museum-penn-state-university/53e1ac2c-
ealc-4ff2-8649-5017127e66b9

Paratypes:

a.

scientificName: Dendrocerus scutellaris; kingdom: Animalia; phylum: Arthropoda; class:
Insecta; order: Hymenoptera; family: Megaspilidae; taxonRank: species; genus:
Dendrocerus; specificEpithet: scutellaris; country: Costa Rica; countryCode: CR;
stateProvince: Guanacaste; verbatimLocality: COSTA RICA: Guanacaste Pr.: Santa Rosa
N. P.: 300m Bosque San Emilio; verbatimElevation: 300m; eveniDate: 1985-10-5/26;
verbatimEventDate: 5-26.x.1985; eventRemarks: sample SE.6.C. BMNH(E) 2008-87;
individualCount: 1; sex: female; lifeStage: adult; catalogNumber: NHMUK010812044;
recordedBy: D Janzen & I. Gauld; identifiedBy: Carolyn Trietsch; dateldentified: 2017;
language: en; institutionID: http://biocol.org/urn:lsid:biocol.org:col:34665; institutionCode:
NHMUK,; collectionCode: Insects; basisOfRecord: PreservedSpecimen; occurrencelD:
http://grbio.org/institution/frost-entomological-museum-penn-state-

university/19410856-81 ec-4ea2-b003-861d28be9fab
scientificName: Dendrocerus scutellaris; kingdom: Animalia; phylum: Arthropoda; class:

Insecta; order: Hymenoptera; family: Megaspilidae; taxonRank: species; genus:
Dendrocerus; specificEpithet: scutellaris; country: Costa Rica; countryCode: CR;
stateProvince: Guanacaste; verbatimLocality: COSTA RICA: Guanacaste Pr.: Santa Rosa
N. P.: 300m Bosque San Emilio; verbatimElevation: 300m; eventDate: 1985-07-5/8-3;
verbatimEventDate: 13.vii-3.viii.1985; eventRemarks: sample SE.6.C. BMNH(E) 2008-87;
individualCount: 1; sex: female; lifeStage: adult; catalogNumber: NHMUK01081 2045;
recordedBy: D Janzen & |. Gauld; identifiedBy: Carolyn Trietsch; dateldentified: 2017;
language: en; institutionID: http://grbio.org/cool/29fv-ztxs; institutionCode: PSUC;
collectionCode: Insects; basisOfRecord: PreservedSpecimen; occurrencelD: http://
grbio.org/institution/frost-entomological-museum-penn-state-

university/60cf3fa8-009b-4b7e-a529-fc933f737604
scientificName: Dendrocerus scutellaris; kingdom: Animalia; phylum: Arthropoda; class:

Insecta; order: Hymenoptera; family: Megaspilidae; taxonRank: species; genus:
Dendrocerus; specificEpithet: scutellaris; country: Costa Rica; countryCode: CR;
stateProvince: Guanacaste; verbatimLocality: COSTA RICA: Guanacaste Pr.: Santa Rosa
N. P.: 300m Bosque San Emilio; verbatimElevation: 300m; eventDate: 1985-07-5/8-3;
verbatimEventDate: 13.vii-3.viii.1985; eventRemarks: sample SE.6.C. BMNH(E) 2008-87;
individualCount: 1; sex: male; lifeStage: adult; catalogNumber: NHMUK010812030;
recordedBy: D Janzen & I. Gauld; identifiedBy: Carolyn Trietsch; dateldentified: 2017;
language: en; institutionID: http://biocol.org/urn:lsid:biocol.org:col:34665; institutionCode:
NHMUK,; collectionCode: Insects; basisOfRecord: PreservedSpecimen; occurrencelD:

http://grbio.org/institution/frost-entomological-museum-penn-state-university/50d80e83-
a282-43c7-9514-eb821ee2b64f

Description

Body length universal: 2.6-2.7 mm.

Colouration: Colour hue pattern: head and mesosoma black; metasoma, mouthparts,
legs and scape except for the basal part dark brown; base of scape light brown. Colour
intensity pattern: proximal part of scape lighter than the rest of the scape.

Trietsch C et al

Head: Cephalic size (csb): mean: 750-1100 um. Head height (lateral view) vs. eye
height (anterior view): HH:EHf=1.25-1.75. Head height vs. head length: HH:HL=1.2-1.5.
Head width vs. interorbital space: HW:lOS=1.6-1.9. Head width vs. head height:
HW:HH=1.5-2.0. Male ocular ocellar line vs. lateral ocellar line: OOL:LOL=2.1-2.6. Male
ocular ocellar line vs. posterior ocellar line: OOL:POL=0.95-1.0. Female ocular ocellar
line vs. lateral ocellar line: OOL 1.6—2.5 x as long as LOL. Anterior ocellar fovea shape:
fovea not extended ventrally into facial sulcus. Occipital carina sculpture: crenulate.
Median flange of occipital carina count: absent. Preoccipital carina count: present.
Preoccipital lunula count: present. Preoccipital furrow count: present. Preoccipital
furrow anterior end: preoccipital furrow ends inside ocellar triangle. Dorsal margin of
occipital carina vs. dorsal margin of lateral ocellus in lateral view: occipital carina is
ventral to lateral ocellus in lateral view. Transverse scutes on upper face count: absent.
Rugose region on upper face count: present. Rugose sculpturing on head and
mesosoma count: present. Facial pit count: facial pit present. Intertorular carina count:
present. Ventral margin of antennal rim vs. dorsal margin of clypeus: not adjacent.
Median region of intertorular area shape: concave. Subtorular carina count: present.
Torulo-clypeal carina count: present. Supraclypeal depression count: present.
Supraclypeal depression structure: absent medially, represented by two grooves
laterally of facial pit. Antennal scrobe count: absent. Mandibular tooth count: 1.
Mandibular lancea count: absent. Distal edge of mandible: flat.

Antennae: Male flagellomeres shape: branched. Male scape length vs combined
length of Fi+F2: longer or equal. 6th male flagellomere length vs. width, “sensillar”
view: elongate, more than 2x as long as wide. Male flagellomere branches count: 7
branches ; 8 branches . Branch of male flagellomere 5 length compared to flagellomere
6: longer than length of flagellomere 6. Branch of male F5 length vs. length of male F5:
longer than length of flagellomere 5. Male F6 length vs. combined length of F7+F8:
shorter than length of flagellomere 7+8. Sensillar patch of the male flagellomere
pattern: F7-F9. Basal resilin-rich area of male antennal branches count: absent. Female
F1 length vs. pedicel length: 1.0-1.2. Female ninth flagellomere length: F9 less than F7
+F8.

Mesosoma and Metasoma: Ventrolateral invagination of the pronotum count: present.
Notaulus posterior end location: adjacent to transscutal articulation. Soeculum ventral
limit: not extending ventrally of pleural pit line. Mesoscutellar comb count: present.
Mesoscutal length vs. anterior mesoscutal width: MscL/AscW=1.2-2.0. Anterior
mesoscutal width vs. posterior mesoscutal width: AscW/PscW=0.7-0.9. Median
mesoscutal sulcus posterior end: adjacent to transscutal articulation. Axillular carina
count: absent. Scutoscutellar sulcus vs. transscutal articulation: adjacent.
Mesometapleural sulcus count: present. Metapleural carina count: present.
Anteromedian projection of the metanoto-propodeo-metapecto-mesopectal complex
count: present. Anteromedian projection of the metanoto-propodeo-metapecto-
mesopectal complex shape: Bifurcated.

Male Genitalia: Distal margin of male S9 shape: convex. Proximolateral corner of male
S9 shape: blunt. Proximodorsal notch of cupula count: absent. Gonostyle/volsella

Unique extrication structure in a new megaspilid, Dendrocerus scutellaris ... 7

complex proximodorsal margin shape: with deep concavity medially. Submedian
conjunctiva on distoventral margin of gonostyle/volsella complex: length (range of
fusion of parossiculus/parossiculus complex from gonostipes): more than 4/5. Apical
parossiculal seta number: one. Dorsal apodeme of penisvalva count: absent. Distal
projection of the penisvalva count: absent. Sensillar plate of the aedeagus shape:
distinctly less than half as wide as the male genitalia. Distal projection of the
parossiculus count: present. Dorsomedian conjunctiva of the gonostyle-volsella
complex count: absent. Cupula length vs. gonostyle-volsella complex length: cupula
less than 1/2 the length of gonostyle-volsella complex in lateral view. Parossiculus
count (parossiculus and gonostipes fusion): present (not fused with the gonostipes).
Distoventral submedian corner of the cupula count: absent. Harpe length: harpe shorter
than gonostipes in lateral view.

Diagnosis

Dendrocerus scutellaris (Figs 1, 2, 3, 4, 5, 6) belongs to the Dendrocerus halidayi
species group (Dessart 1995, Dessart 1999), based on the branched male
flagellomeres, bifid anteromedian projection of the metanoto-propodeo-metapectal
complex and the presence of parossiculal projections with 3 parossiculal setae. This
species is distinguished from all other ceraphronoid species by the presence of the
mesoscutellar comb, an anatomical cluster that is composed of a row of spines
medially on the mesoscutellar-axillar complex. This species is also unique amongst
Ceraphronoidea in that the distal edge of mandible is flat and not pointed.

200 um

an
Figure 1. EES

Dendrocerus scutellaris habitus, with arrows pointing to the mesoscutellar comb. A. Male
holotype (NHMUK010812028). B. Female paratype (NHMUK010812044). C. Dorso-lateral
view of the mesoscutellar comb (female paratyoe NHMUK010812045).

Trietsch C et al

Figure 2. EE

Dorsal view of Dendrocerus scutellaris. A. Male holotype (NHMUK010812028). B. Female
paratype (NHMUK010812044).

Figure 3. EE

Frons of Dendrocerus scutellaris. A. Male holotype (NHMUK010812028). B. Female paratype
(NHMUK010812044). C. Image showing the flat distal edge of the mandible from the male
paratype (NHMUK01081 2030).

Unique extrication structure in a new megaspilid, Dendrocerus scutellaris ...

Figure 4. doi

Antennae of the two known male specimens of Dendrocerus scutellaris, with arrows pointing to
the variable eighth branch. The branch is more developed in the male holotype (A;
NHMUK010812028) than in the male paratype (B; Male NHMUK010812030).

Figure 5. EEl

Genitalia of the male holotype (NHMUK010812028). A. Dorsal view. B. Ventral view.

10 Trietsch C et al

Figure 6. Efl

CLSM images of the genitalia of the male holotype (NHMUK010812028). A. Ventral view. B.
Dorsal view.

Etymology

This species is named for the presence of the mesoscutellar comb, which is unique to
this species and is not found in any other known ceraphronoid species.

Distribution

This species is only known from Costa Rica.

Discussion

Dendrocerus scutellaris belongs to the halidayi species-group, which is characterised by
the presences of flabellate antennae in males (Dessart 1995, Dessart 1999). This new
species is one of the few Dendrocerus species that also possesses a bifurcated
anteromedian projection of the metanoto-propodeo-metapecto-mesopectal complex (Fig.
1). This character is also present in D. africanus and D. australicus Dodd 1914, both
members of the halidayi species-group Dessart 1995, Dessart 1999. Based on the
morphological features which these species share in common, it is hypothesised that this
species is the closest known living relative to Dendrocerus scutellaris.

D. scutellaris is unique amongst members of the halidayi species-group in that, while other
species have up to six fully formed branches on the flagellomeres (Dessart 1999, Dessart
1995), Dendrocerus scutellaris has 7 fully formed branches with a variable eighth branch
that is more developed in the holotype male specimen than in the paratype male (Fig. 4).

Unique extrication structure in a new megaspilid, Dendrocerus scutellaris ... 11

The length of the seventh branch also varies between specimens; in the holotype, the
branch is as long as the branch on the seventh flagellomere is as long as the seventh
flagellomere, while in the paratype specimen, it is shorter than the seventh flagellomere.
Though the number of flagellomeres with branches and branch length has been used as a
character to describe new species of Dendrocerus in the past (Pezzini et al. 2014),
Dendrocerus scutellaris clearly exhibits intraspecific variation in the number and length of
the flagellar branches between both male type specimens. Thus, branch length and
presence of apical branches should not be used exclusively to describe Dendrocerus
species.

Dendrocerus scutellaris is distinguished from all other ceraphronoid species by the
presence of a straight mandibular surface (Fig. 3) and the presence of the mesoscutellar
comb (Fig. 1), a ridge of backward-facing dorsal projections present in both male and
female specimens. Though nothing is known about the life history or host identity of this
species, other species such as Dendrocerus carpenteri Curtis 1829 are known to parasitise
braconid parasitoids inside of aphid mummies (Mackauer and Chow 2015). It is
hypothesised that the function of the mesoscutellar comb is to aid in emergence and
extrication of the adult from its host. The function of the mesoscutellar comb is further
suggested by the fact that the distal surface of the mandible is straight instead of pointed,
and thus presumably cannot be used for piercing or tearing of the pupal case. All other
known Ceraphronoidea possess a pointed mandibular edge and lack the mesoscutellar
comb; the presence of a straight mandibular edge in the only ceraphronoid with a
mesoscutellar comb is not likely to be a coincidence.

Acknowledgements

The authors thank Missy Hazen for her expertise and assistance with CLSM at the Penn
State Microscopy and Cytometry Facility (University Park, PA). The authors would also like
to thank the reviewers, Simon van Noort and Aniruddha Mitra, for their insightful comments
and help in improving the manuscript. This material is based upon work supported by the
U. S. National Science Foundation, under Grant Numbers DBI-1356381 and
DEB-1353252. Any opinions, findings and conclusions or recommendations expressed in
this material are those of the authors and do not necessarily reflect the views of the
National Science Foundation.

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Supplementary materials

Suppl. material 1: Specimen Locality Information EZ

Authors: Carolyn Trietsch, Istvan Mik6, David G. Notton, Andrew R. Deans
Data type: occurences

14 Trietsch C et al

Brief description: A table listing all of the specimens used in this study and their associated
locality and repository information.

Filename: Supplementary File 1.xlsx - Download file (8.88 kb)

Suppl. material 2: MX Taxonomic Treatment File EES

Authors: Carolyn Trietsch, Istvan Mik6, David G. Notton, Andrew R. Deans
Data type: n3 File

Brief description: The taxonomic treatment file generated from MX used to write semantic
statements.

Filename: scutellaris_mx_taxonomic_treatment.n3 - Download file (217.95 kb)

Suppl. material 3: Semantic Statement Phenotype Annotations EE
Authors: Carolyn Trietsch, Istvan Mik6, David G. Notton, Andrew R. Deans
Data type: OWL file

Brief description: The file containing all of the semantic statement phenotype annotations.
Filename: scutellaris_semantic_statement_annotations.owl - Download file (17.11 MB)