Research Article

Journal of Orthoptera Research 2023, 32(1): 43-53

Nofes on the distribution, ecology, and life history of
Maotoweta virescens (Orthoptera, Rhaphidophoridae, Macropathinae)
and a comparison of two survey methods

James M. H. Tweep!2, MICHAEL WAKELIN?, BRUCE McKINLaAy4, TARA J. Murray4

1 Ahika Consulting, 2 Dowling St, Dunedin 9016, New Zealand.

2 Current address: School of Biological Sciences, Centre for Biodiversity and Conservation Science, The University of Queensland, Brisbane, QLD, Australia.

3 4Sight Consulting, 195 Rattray St, Dunedin 9016, New Zealand.

4 Biodiversity Group, Department of Conservation, Level 1/265 Princes St, Dunedin 9016, New Zealand.

Corresponding author: James M. H. Tweed (jtweed@outlook.com)

Academic editor: Klaus-Gerhard Heller | Received 6 May 2022 | Accepted 19 September 2022 | Published 24 March 2023

https://zoobank. org/4A59C254-8255-4C6B-97B6-32A3FD0425F9

Citation: Tweed JMH, Wakelin M, McKinlay B, Murray TJ (2023) Notes on the distribution, ecology, and life history of Maotoweta virescens (Orthoptera,
Rhaphidophoridae, Macropathinae) and a comparison of two survey methods. Journal of Orthoptera Research 32(1): 43-53. https://doi.org/10.3897/

jor.32.86076

Abstract

When described in 2014, Maotoweta virescens was believed to be one
of New Zealand's rarest cave wéta (Rhaphidophoridae). Here, we present
new information about the distribution, ecology, and life history of the
species. M. virescens has now been recorded from indigenous forest sites
throughout the length of the western South Island, where it can occur in
relatively high abundance. M. virescens shows a close association with ar-
boreal mosses, particularly Weymouthia mollis, roosting within them during
the day and feeding on them at night. The wéta has also been documented
feeding on lichens and dead insects. The species is hypothesized to have
a lifecycle of approximately one year, closely linked to season. Eggs are
thought to hatch out relatively quickly after being laid in summer and
early autumn, with the species overwintering as nymphs and maturing the
following late spring through to early-autumn. Further work is required to
fully understand its biology. A comparison was made between active night
searching and vegetation beating as two different methods for the detec-
tion and monitoring of M. virescens. Beating of W. mollis and other suitable
M. virescens microhabitats was found to be significantly more effective than
night searching. Our results show that M. virescens is widespread and can
occur at relatively high densities within South Island temperate forests,
with the species’ perceived rarity to date largely owing to a lack of survey
effort and the past use of ineffective sampling methods.

Keywords

beating, cave wéta, data deficient, New Zealand, moss

Introduction

Orthopteroid insects belonging to the family Rhaphidophori-
dae are found throughout most temperate regions of the world
(Hubbell and Norton 1978). Rhaphidophorids are commonly
referred to as cave crickets, camel crickets, or sand-treader crickets
in various parts of the world. Many rhaphidophorid species are
entirely confined to caves, while many others are typically closely
associated with other cavities such as tree hollows, burrows, or leaf

litter, sheltering within them during the day and emerging at night
to feed (Ingrisch and Rentz 2009).

Within New Zealand (NZ), rhaphidophorids are commonly
known as cave wéeta. The name ‘wéta’ is also used for New Zealand
Orthoptera in the family Anostostomatidae, including the tree
weta (Hemideina spp.) and giant wéta (Deinacrida spp.), which are
often viewed as national icons. However, the more secretive cave
weta are relatively poorly known. The NZ cave wéta fauna is diverse
relative to the country’s land area. The 71 known species (Trewick
et al. 2016) equate to 8.6% of the world’s rhaphidophorid species
(Cigliano et al. 2022). Little is known about the ecology and biol-
ogy of most cave wéta. Previous studies within NZ have focused on
cave dwelling species (Richards 1954, 1961, 1962, 1965, 1966, Fea
and Holwell 2018), but little has been published on species found
in other habitats, such as forests. More recent taxonomic studies
have added to our knowledge of the ecology and biology of NZ’s
cave weta (e.g., Cook et al. 2010, Johns and Cook 2014, Fitness et
al. 2018, Hegg et al. 2019, 2022), but further studies are needed.

None of NZ’s cave wéta have yet been assessed for the IUCN
Red List IUCN 2022). However, Trewick et al. (2016) evaluated
all 71 species of cave wéta known at that time (56 described, 15
tag named taxa) using the New Zealand Threat Classification Sys-
tem (NZTCS), which assesses a species’ risk of extinction based
on estimates of population size and trend criteria (Townsend et
al. 2008). At that time, 25 cave wéta species were classified as At
Risk or Data Deficient (Trewick et al. 2016). The category Data
Deficient indicates that there is insufficient information on the
population size and trend of a species to properly assess its threat
status. Improving our understanding of the distribution, ecology,
and biology of Data Deficient species is essential to assigning an
appropriate threat classification and enabling effective conserva-
tion measures where they are needed.

Despite its distinctive green coloration, which distinguishes it
from almost all other NZ cave wéta species, Maotoweta virescens
Johns & Cook, 2014 escaped scientific attention until recently. At

JOURNAL OF ORTHOPTERA RESEARCH 2023, 32(1)

44

the time of its description, M. virescens, commonly called the moss
weta, was believed to be one of the rarest species of cave wéta in
New Zealand as it was known from only seven specimens (Johns
and Cook 2014). Five of the seven were collected from the Takit-
imu Mountains in Southland in 2006, while the remaining two
were collected more than 60 years earlier, one each from Fiordland
and northwest Nelson (Johns and Cook 2014). The apparent rarity
of the species meant that little information existed in relation to
its distribution, ecology, and biology and therefore its population
size or trend (Johns and Cook 2014), and consequently, the spe-
cies was classified as Data Deficient within the NZTCS when first
assessed (Trewick et al. 2016).

To improve our knowledge of rare or poorly known species
such as M. virescens, survey methods must be designed to maxi-
mize the chance of reliably detecting the target species when it is
present (Schori et al. 2020). The use of ineffective survey meth-
ods can negatively influence our understanding of species ecology
and rarity (Gaston 1994). Forest-dwelling cave wéta are noctur-
nal (Richards 1961) and so spotlighting desirable habitat at night
has traditionally been the main method of detection (e.g., Johns
and Cook 2014, Hegg et al. 2019). However, spotlighting has been
found to be relatively unsuccessful for the cryptic M. virescens, with
Johns and Cook (2014) reporting a detection rate of one wéta for
every 192 minutes of searching. To resolve this, we attempted
to identify the most suitable method for detecting and possibly
monitoring M. virescens during targeted surveys for Data Deficient
invertebrates in the Southland Region.

J.M.H. TWEED, M. WAKELIN, B.

MCKINLAY AND T.J. MURRAY

The objectives of the current study were as follows: (1) to
improve our understanding of the distribution, ecology, and life
history of M. virescens, (2) to identify the most suitable means of
detecting and/or monitoring M. virescens, and (3) to recommend
an appropriate threat classification for M. virescens to help deter-
mine whether conservation action is required for its protection.
The findings from this study may have relevance to other species
of forest-dwelling Rhaphidophoridae.

Methods

Field surveys.—Surveys for M. virescens were undertaken at 20
South Island sites from January-June 2021 (Table 1). These sur-
veys were part of a wider Department of Conservation (DOC)-led
project (Tweed and Wakelin 2021) intended to increase knowl-
edge on the distribution and relative abundance of invertebrate
species from the Southland region of NZ classified as Data Defi-
cient within the NZTCS.

Surveys were conducted in a range of habitat types, including
mixed temperate forest, open beech forest, subalpine shrubland,
and alpine grasslands. However, most surveys were conducted
within mixed temperate forest or open beech forest. These are the
characteristic forest types of the higher and lower rainfall regions
of NZ’s South Island, respectively (Table 1).

In the South Island, the canopy of mixed temperate forest
comprises a variable mixture of tree species including several spe-
cies of Podocarpaceae (podocarps), Nothofagaceae (southern
beeches), and Myrtaceae (myrtles), among others (Wardle 1991).

Table 1. Locations surveyed for Maotoweta virescens during this study arranged from north to south. Site name area codes follow Crosby
et al. (1998): FD = Fiordland, OL = Otago Lakes, SI = Stewart Island, SL = Southland, WD = Westland. Annual average rainfall values
were extracted from Ministry for the Environment (2015). Survey type codes are as follows: P/A = presence/absence survey (i.e., beating
and/or night searches used for detection but not timed); TNS = timed night search; TBS = timed beating survey (during daylight). The

total duration for each timed survey is given in minutes.

Site name Habitat Average annual Survey date(s) Latitude (°), Survey type M. virescens No. specimens
rainfall (mm) Longitude (°) detected collected
Karangarua Valley, WD Mixed temperate forest 8,374 08/06/21 -43.707, 169.867 P/A (day + night) Yes 2
Martins Bay, WD Mixed temperate forest 5,644 22-23/02/21, -44,342, 168.009 P/A (day + night) Yes 6
26/02/21
Hokuri Creek, WD Mixed temperate forest 6,211 25/02/21 -44.409, 168.059 TBS (225 mins) Yes 17
George Sound, FD Mixed temperate forest 7,884 03/02/21 -44.985, 167.438 P/A (day + night) Yes 2
Henry Pass, FD Alpine grassland, 8,383 01-02/02/21 -45.010, 167.498 P/A (day only) No NA
subalpine shrubland
Caswell Sound, FD Mixed temperate forest 7,386 04/02/21 -45.047, 167.307 TNS (100 mins), Yes 8
TBS (70 mins)
Lake Marchant, FD Mixed temperate forest 7,386 05/02/21 -45.056, 167.317 P/A (day only) Yes
Junction Burn, FD Mixed temperate forest 6,306 09-11/02/21 -45.151, 167.498 P/A (day + night) Yes 4
Lake Mistletoe, OL Open beech forest 1,311 12/02/21 -45.201, 167.824 No NA
Hanging Valley Track, Mixed temperate forest 7,782 01/03/21 -45.471, 167.143 TNS (180 mins), Yes 12
Doubtful Sound, FD TBS (95 mins)
Old Doubtful Track, Mixed temperate forest 7,782 02/03/21 -45.479, 167.171 TBS (90 mins) Yes 4
Doubtful Sound, FD
Wilmot Pass, FD Mixed temperate forest and 7,009 04/03/21 -45.512, 167.197 P/A (day only) Yes 1
subalpine scrub
Princhester Creek, Open beech forest 1,096 06/03/21 -45.600, 167.956 TBS (105 mins) Yes 1
Takitimu Mountains, SL
Grebe Valley, FD Mixed temperate forest 4,019 26/01/21 -45.659, 167.344 P/A (day only) Yes 1
Borland Saddle, FD Open beech forest, 2,278 25/01/21 -45.747, 167.382 P/A (day only) No NA
alpine grassland
Borland Lodge, FD Open beech forest 1,318 24/01/21 -45.780, 167.533 P/A (day + night) No NA
Rakeahua Valley, SI Mixed temperate forest 1,751 08-11/03/21 -46.982, 167.881 P/A (day + night) No NA
Ulva Island, SI Mixed temperate forest 1,401 13/03/21 -46.892, 168.099 P/A (day only) No NA
Fern Gully, SI Mixed temperate forest 1,387 14/03/21 -46.929, 168.130 P/A (day only) No NA
McLean Falls, SL Mixed temperate forest 1,339 15/03/21 -46.572, 169.347 TBS (20 mins) Yes 2

JOURNAL OF ORTHOPTERA RESEARCH 2023, 32(1)

J.M.H. TWEED, M. WAKELIN, B. MCKINLAY AND T.J. MURRAY

The presence and/or dominance of each of the canopy species var-
ies geographically. The understories are typically dominated by
broadleaved trees, shrubs, and ferns. Most surfaces are covered in
thick layers of mosses, such as Weymouthia mollis (Hedw.) Broth.,
as well as numerous liverworts and lichens (Fig. 1A). These forests
are typical of much of the western South Island, Fiordland, and
the Catlins regions (Wardle 1991). The forests of Stewart Island
are similar in composition but lack the southern beeches (Wardle
1991). Although numerous subclassifications can be designated
(e.g., podocarp-broadleaf, beech-podocarp, etc.), here mixed tem-
perate forest is used to refer collectively to the relatively high-rain-
fall forests, which are typically more diverse than the open beech
forests described below.

The beech forest habitats surveyed were dominated by one or
more of the southern beeches, with a relatively open, low-diversi-
ty understory comprised largely of divaricating shrubs (Fig. 1B).
These open beech forests are typical of the forests of drier areas to
the east of the Southern Alps (Wardle 1991). Mosses, lichens, and
liverworts were also abundant, though the species composition
differed, with a general lack of the hanging mosses seen in the
mixed temperate forests.

Surveys for M. virescens were undertaken by a) visual spotlight
searches at night, and b) beating of understory vegetation during the
day. Notes were recorded on the habitat in which each wéta was de-
tected, including the plants on which they were observed, the struc-
ture of the surrounding forest, and the elevation. Some wéta encoun-
tered at each location were collected for morphological analysis.

Comparison of survey methodologies.—In addition to the presence-
absence surveys noted above, timed night searches and daytime
beating searches were undertaken at a subset of sites.

Night searches. Timed night searches were undertaken at two
Fiordland locations: Caswell Sound and Doubtful Sound (Table 1).
Searches involved walking through suitable M. virescens habitat and
scanning vegetation, particularly hanging and climbing mosses, with
head torches. Any M. virescens encountered were recorded along with
details of location, time of detection, the vegetation they were detect-
ed on, weather conditions, and any other notable information. The
number of surveyors and the survey duration were recorded to cal-
culate search effort. Night searches occurred between 21:00-23:00
NZDT hours, though the total length of the survey varied. Data on
night searches from the type locality of Princhester Creek in the Tak-
itimu Mountains were also extracted from Johns and Cook (2014).

Beating. We used daytime beating as the primary method for
detecting M. virescens during this study. Preliminary work indi-
cated that M. virescens might roost within mosses during the day,
so we opted to use daytime beating as a sampling method. The
traditional beating method for sampling invertebrates from veg-
etation uses a flat or slightly convex beating tray. Here, beating for
M. virescens was undertaken using an entomological net (38 cm
diameter) instead of a flat tray, as it ensured wéta were not able to
jump away before being recorded. Wéta specimens were primarily
collected off the inside walls of the net, although some smaller
nymphs were found among the debris in the bottom of the net.

Timed beating surveys were conducted following the same
methodology as timed night surveys and were conducted at six lo-
cations (Table 1). Hanging and climbing mosses were targeted for
beating over an entomological net, as described above. The start
and end times of the survey were recorded to allow for calculation
of the search effort. Beating surveys typically occurred between
10:00 and 19:00 NZDT hours, although the length of the survey
varied between sites.

45

Fig. 1. Forest types surveyed during this study. A. Typical mixed
temperate forest photographed at Hokuri Creek in the lower Hol-
lyford Valley, FD (note the extensive covering of Weymouthia mollis
and other mosses and liverworts on the trunks and limbs of most
trees and shrubs, as well as the forest floor); B. Typical open beech
forest photographed within the Takitimu Mountains, SL (photo
credit: N Harbison-Price).

Statistical analysis. —A Wilcoxon rank-sum test was used to com-
pare the mean search time per M. virescens specimen observed
for night searching and beating surveys. Analysis was conduct-
ed using the wilcox.test() function of the statistical software R
(R Core Team 2021). Data were plotted using the package ggplot2
(Wickham 2016).

Additional distribution records.—The curators of NZ’s largest en-
tomological collections were contacted to determine whether
they held any M. virescens specimens: New Zealand Arthro-
pod Collection (NZAC), Auckland Museum (AMNZ), Te Papa
(MONZ), Canterbury Museum (CMNZ), Lincoln University
Entomology Research Collection (LUNZ), and Otago Muse-
um (OMNZ). A single specimen was reported from the AMNZ
collection, while CMNZ holds those specimens reported by Johns
and Cook (2014). No other specimens were reported. Records
were also obtained from T Jewell (pers. comm.), R Morris (pers.
comm.), and from iNaturalist (2022).

JOURNAL OF ORTHOPTERA RESEARCH 2023, 32(1)

46

Distribution and environmental variables.—All available records of
M. virescens were plotted using QGIS v3.16.0. The elevation of
each record was assessed using NZTopo50 map series. Values for
the annual rainfall at the detection locations were extracted from
the Ministry for the Environment's annual average rainfall data
(Ministry for the Environment 2015). Area codes used through-
out represent biogeographical regions identified by Crosby et al.
(1998) and are routinely used when documenting the collection
localities of invertebrate specimens within NZ.

Observations of captive wéta.—A total of five adult female and two
adult male M. virescens were kept in captivity for up to one month
to observe their behavior and diet. The incidentally biased sex
ratio among captive specimens available meant that up to four
females were kept together with a single male. Wéta were kept in
a plastic tank lined with paper towel. The tank was misted once
per day to keep it moist. Twigs were placed in the tank for the
weta to climb and roost on. Mosses (Weymouthia mollis (Hedw.)
Broth., Orthotrichaceae sp.), lichens (Cladonia ?confusa R. Sant.,
‘Lobaria sp., Pseudocyphellaria sp., Yarrumia ?colensoi (C.Bab.)
D.J.Galloway), liverworts (?Trichocolea ?mollissima (Hook.f. &
Taylor) Gottsche, ?Lepicolea sp.), and the leaves of some vascu-
lar plants (Coprosma rhamnoides A.Cunn., Metrosideros sp., Fuscos-
pora sp., Weinmannia racemosa (L.f.) Pillon et H.C.Hopkins) were
collected from the same localities as the wéta and placed within
the tank. Insect carcasses were also offered to the captive wéta
in the form of freshly caught hoverflies (Melanostoma fasciatum
(Macquart, 1850) (Diptera, Syrphidae), which were swept from
rank grass and killed by freezing.

Behavioral observations were made opportunistically both
during the day and at night, and given the small sample size avail-
able, no attempt was made to undertake a full quantitative analy-
sis of behavior. At night, the wéta were observed using a red light,
as this is known to cause less disturbance to cave wéta than white
or yellow lights (Butts 1983). The relative locations of individuals
within the tank, whether they were feeding, and interactions be-
tween individuals were all recorded. Lichens and hoverfly bodies
were inspected for signs of feeding each morning.

Morphological characteristics.—Both nymphs and adults were col-
lected to study the growth and development of M. virescens. A total
of 10 adults and 51 nymphs were collected from various locations
during the surveys. Specimens were preserved in 70% ethanol
and have been deposited within the Phoenix Collection housed
at Massey University, Palmerston North, NZ. The length of the
hind femur, hind tibiae, body, and ovipositor for the females were
measured using digital calipers for all collected specimens. The
presence or absence of an ovipositor was used to sex the speci-
mens, which may have led to some early instar female nymphs
being falsely identified as males. Due to this uncertainty, no statis-
tical comparison was made between the body sizes of male and fe-
male nymphs. Morphology measurements were plotted using the
package ggplot2 (Wickham 2016) within the statistical software R
(R Core Team 2021).

Results

Distribution.—Maotoweta virescens has now been recorded through-
out the length of the South Island of NZ, with most records oc-
curring to the west of the Southern Alps (Fig. 2). Records extend
from the Cobb Valley (NN) in the northwest to McLean Falls in
the Catlins Conservation Park (SL) in the southeast (Fig. 2). The

J.M.H. TWEED, M. WAKELIN, B. MCKINLAY AND TJ. MURRAY

170°E 180

North Island *..
Rate

Rainfall (mm)
Ga <= 500

GE 500 - 750
[) 750 - 1000
MB 1000 - 1250
MMB 1250 - 1500
GHB 1500 - 2000
MJ 2000 - 3000
MB 3000 - 4000
Hl > 4000

Fig. 2. Known records of Maotoweta virescens. A. Records overlain
on the current extent of indigenous forest; B. Records overlain
on mean annual rainfall. Circles represent records of M. virescens
obtained during this study, triangles are confirmed records from
other sources, and crosses indicate sites surveyed during this sur-
vey at which M. virescens was not detected. The extent of indig-
enous forest was taken from Landcare Research (2020). Rainfall
data is from the Ministry for the Environment (2015) Area codes
and boundaries follow Crosby et al. (1998).

latter record (-46.57157, 169.34744) marks the only confirmation
of the species from the east coast of the South Island, extending
the known range by 150 km eastwards, with the nearest known
population occurring in the Takitimu Mountains, SL. Maotoweta
virescens was detected at most sites surveyed during this study, with
the exceptions of Borland Lodge (FD), Borland Saddle (FD), Hen-
ty Pass (FD), and Lake Mistletoe (OL) (Fig. 2, Table 1). Maotoweta
virescens was also not detected on Stewart Island despite extensive
searching (Fig. 2, Table 1).

Habitat.—Maotoweta virescens is now known from a wide elevation
range, having been recorded from sea level at Caswell Sound, FD
during this study, and at altitudes of up to 1,200 masl at Mt Arthur,
NN, in the earlier study of Johns and Cook (2014). The species ap-
pears to be strongly associated with moderate-to-high rainfall for-
ests with all records occurring in areas averaging 1,096-8,374 mm
per year (Fig. 2). Princhester Creek in the Takitimu Mountains, SL,
and the Karangarua Valley, WD, represent the lowest and highest
precipitation sites, respectively.

Records from this study and additional distribution records
indicate that M. virescens is primarily associated with mature forest
habitats (Fig. 2). It has been recorded from both mixed temperate
forests and beech forests but was not detected in the subalpine
shrublands or grasslands surveyed during this study.

JOURNAL OF ORTHOPTERA RESEARCH 2023, 32(1)

J.M.H. TWEED, M. WAKELIN, B. MCKINLAY AND T.J. MURRAY

” L - 2 a f a - _
«= = : ee ee -.

iEF

47

=

Fig. 3. Photos of adult Maotoweta virescens. A. Female from Milford Sound, FD; B. Female from Lake Gunn, FD; C. Male from Milford
Sound, FD; D. Male from Runanga, WD. Photo credit: Tony Jewell (www. flickr.com/photos/rocknvole/).

Maotoweta virescens was detected in all mixed temperate for-
est locations surveyed in Fiordland, Westland, and the Catlins
(Table 1, Fig. 2). Within this forest type, both nymphs and adults
were found to be particularly closely associated with arboreal moss
and liverwort communities. Most M. virescens detected within this
forest type were beaten from the hanging moss Weymouthia mollis,
though some were also beaten from other moss species, lichens,
and leafy liverworts (Marchantiophyta: Jungermanniopsida),
while others detected at night were found climbing tree trunks.
The plant species on which the moss was growing seemed to have
little influence on the presence or absence of M. virescens, as indi-
viduals were beaten from moss growing on a diverse range of trees,
shrubs, and tree ferns, as well as dead trees and limbs. Fig. 3 shows
photos of live specimens in their natural habitat.

Maotoweta virescens was also found within open beech forest.
A single nymph was beaten from a Coprosma rhamnoides shrub in
the forest understory at Princhester Creek in the Takitimu Moun-
tains, SL, the type locality for M. virescens. This shrub had a thin
layer of an unidentified species of moss on its stem. Although
mats of mosses and liverworts were present on most tree trunks,
the open beech forest habitat lacked the curtains of hanging moss
characteristic of M. virescens habitat within the mixed temperate
forests surveyed. Maotoweta virescens was not detected from open
beech forest searched near Borland Lodge, FD, or at Lake Mistle-
toe, OL; however, the species has been confirmed from Monowai
Flats, ~1 km from the site surveyed at Borland Lodge (T Jewell
pers. comm; Fig. 2).

Although no adults of any other cave wéta species were en-
countered while beating moss for M. virescens, the nymphs of oth-
er species were occasionally caught, including Talitropsis chopardi
(Karny, 1937) and Notoplectron brewsterense (Richards, 1972).
Several species of cave wéta were also routinely encountered on
the trunks of trees or on the forest floor during night searches for
M virescens, including Miotopus richardsae Fitness, Morgan-Rich-
ards, Hegg & Trewick, 2018, Talitropsis sedilloti Bolivar, 1882, and
several Isoplectron species.

Morphological characteristics.—Based on body measurements and
the development of female genitalia, all specimens collected ap-
peared to be either adults or early-instar nymphs (Fig. 4). Only a
single late-instar nymph was observed during the surveys: a pe-
nultimate instar female that underwent its final molt in captivity
less than 24 hours after capture and was therefore measured as an
adult (depicted in Fig. 5H).

The lengths of the bodies (2.3-5.1 mm), hind femur (2.1-
4.2 mm), and hind tibia (2.2-4.5 mm) of the nymphs measured
(n = 51) displayed an almost continuous range, with no discrete
size classes evident that could be used to separate instars. The two
nymphs collected from the Karangarua Valley, WD, had margin-
ally longer hind tibiae and femora than any other early-instar
nymphs measured, but their body sizes overlapped with those of
the other collected nymphs (Fig. 4A, B). The female nymph from
Karangarua also had a longer ovipositor than all other female
nymphs (Fig. 4C).

JOURNAL OF ORTHOPTERA RESEARCH 2023, 32(1)

48

10.0

' ie ‘\
75 oak e Pd
éf

‘\ é
~ -
~ -

Hind femur length (mm)

=

S

—

s

=

2 @ oF |
5 emale
® & Male
2

ae)

=

ai i

Ovipositor length (mm)

9 12

6
Body length (mm)

Fig. 4. Hind femur (A), hind tibia (B), and ovipositor (C) length
of Maotoweta virescens specimens collected in this study plotted
against body length. The observations within the solid oval on
each plot are the specimens collected from the Karangarua Valley,
WD, in June; those within the dashed oval are adult specimens
collected during this study; those not circled are other early-instar
nymphs collected during this study.

Among adult specimens (n = 10), the length of the body, hind
femur, and hind tibia ranged from 8.6-10.8 mm, 7.2-7.6 mm,
and 8.1-9.1 mm, respectively, for males (n = 5), and from 7.8-
11.2 mm, 7.0-8.2 mm, and 7.3-9.0 mm for females (n = 5). Ovi-
positor length ranged from 4.6-5.9 mm.

Color variation.—The coloration of M. virescens was found to be
highly variable (Fig. 5), but all color morphs observed to date re-
semble the habitat of mosses, liverworts, and lichens in which the
weta lives (Figs 3, 5, 6). Individuals of distinctly different color
morphs were found cohabiting on several occasions. Fig. 5 shows
some of the color and pattern variations noted during this study,
although the full range of variation is even greater than depicted
here (also see Fig. 3 for further examples).

Behavioral observations.—In captivity, M. virescens was found to be
entirely nocturnal. During the day, the wéta would roost on twigs,
camouflaged among clumps of moss. When at rest, the wéta would

J.M.H. TWEED, M. WAKELIN, B. MCKINLAY AND TJ. MURRAY

fold their antenna beneath their body and then fold them again, ap-
proximately beneath the mesocoxa, so that the tips lay flat along the
branch on which they were sitting (i.e., they were folded into a col-
lapsed S-shape when viewed laterally; Fig. 6). Individuals were ob-
served roosting both separately and near one or more other wéta. In
the field, the number of wéta beaten from a clump of moss contain-
ing M. virescens varied between one and five individuals. Nymphs
and adults were usually detected separately, although on some occa-
sions, nymphs were beaten from the same clumps of moss as adults.

At night, captive M. virescens would roam around their enclo-
sure, climbing along twigs as well as the walls and ceiling of the
enclosure. Roaming wéta waved their antenna in front of them
constantly, stopping only when they encountered a food source.
When two individuals met each other, they would pause briefly,
inspect each other with their antenna, and then move around one
another, continuing their path. No aggression was observed be-
tween individuals. Captive individuals that died overnight were
removed the following day. No feeding damage was observed on
any of the dead wéta.

No mating was observed in captivity or in the field, but males
and females were found in proximity on numerous occasions.
Oviposition was also not observed but the swollen abdomen of a
female caught at Martins Bay (26 February 2021) suggested at least
some females were gravid at the time the surveys were conducted.

A single captive wéta was observed undergoing ecdysis from
the penultimate instar to an adult on the 04 March 2021. The
female (depicted pre-molt in Fig. 5H) clung to the underside of
a twig with its head facing downwards. At the final stages of the
process, the wéta hung from its exuviae, attached only by the tips
of its antenna and ovipositor, which were the last structures to
be withdrawn. The entire process took approximately 30 minutes.
The pigmentation of the female was somewhat paler following
ecdysis, although this darkened quickly. The patterning of the in-
dividual remained unchanged.

Diet.—Maotoweta virescens were observed feeding on the moss
Weymouthia mollis in the field during night searches. Weymouthia
mollis was actively fed on by captive M. virescens but appeared to
lose its palatability as it dried out. Some feeding was observed on
a second moss offered (Orthotrichaceae sp.) but not for sustained
periods, suggesting it was not a preferred food source.

Captive wéta actively fed on the foliose lichens offered, particu-
larly Yarrumia ?colensoi. The wéta ate holes through the middle of
the sheets of Yarrumia but were only observed feeding on the edges
of Pseudocyphellaria and ?Lobaria lichens. No feeding was observed
on the fruticose Cladonia confusa. No browsing was observed on ei-
ther the liverworts or the leaves of any of the vascular plants offered.

All insect carcasses offered to the captive wéta were consumed
on the first night; however, several captive wéta that died overnight
were not fed on by others prior to their removal the following day.

Comparison of survey methodologies.—The mean search time per
M. virescens specimen detected using beating was significantly low-
er than that of active night searching (Wilcoxon’s test, p = 0.038,
Fig. 7). When searching suitable habitat, M. virescens was encoun-
tered on average once every 28.1 minutes while beating and every
157.3 minutes while active night searching (Fig. 7). For beating,
this dropped to one individual every 12.7 minutes if the Prinches-
ter Creek survey (105 minutes per individual) was excluded. Prin-
chester Creek was the only open beech forest habitat included in
the timed surveys, with the remaining sites all being mixed tem-
perate forest (see Table 1).

JOURNAL OF ORTHOPTERA RESEARCH 2023, 32(1)

J.M.H. TWEED, M. WAKELIN, B. MCKINLAY AND T.J. MURRAY 49

B

Fig. 5. Examples of phenotypic variation displayed by Maotoweta virescens. A. Male, Martins Bay, WD; B. Female, Martins Bay, WD;
C. Female, Doubtful Sound, FD; D. Female, Wilmot Pass, FD; E. Male, Martins Bay, WD; FE. Female, Martins Bay, WD; G. Male, Hokuri
Creek, WD; H. Penultimate instar female, Doubtful Sound, FD. Note: images are not to scale. Body length of all individuals was be-
tween 7.8 mm (H) and 11.2 mm (B).

Discussion ests of the western and southern South Island. However, records
from the Takitimu Mountains, SL (Johns and Cook 2014, R Mor-

This study has shown that M. virescens is widely distributed ris pers. comm., and this study) and Monowai Flats, SL (T Jewell
throughout NZ’s South Island. Current records suggest that the pers. comm.) indicate that the species is also capable of inhabiting
species is most closely associated with the mixed temperate for- open beech forest habitat. Given that the species has been detected

JOURNAL OF ORTHOPTERA RESEARCH 2023, 32(1)

50

across a wide latitudinal and elevational range, as well as from
several different forest ecotypes, it seems likely that the species will
be recorded from other locations in the South Island following
further survey efforts. We did not detect M. virescens on Stewart
Island during this study, but given that ours was the first target-
ed search effort for the species on the island, more survey effort
is needed. Several other cave wéta species are known from both
the South Island and Stewart Island, including Talitropsis sedilloti
(Michel et al. 2008) and Miotopus richardsae (Fitness et al. 2018).
Similarly, although the species has not yet been recorded from the
North Island, its presence cannot be discounted, as several of NZ's
cave wéta species are known to inhabit both the North and South
Islands, including both species mentioned above. Suitable forest
habitat for M. virescens, including Weymouthia mollis, is present on
both Stewart Island and the North Island.

Although some species of Rhaphidophoridae are known to be
closely associated with plants (e.g., the North American species
Gammarotettix bilobatus (Thomas, 1872) (Stidham 2005)), most
described NZ cave wéta species are typically cavity dwellers, shel-
tering in locations such as caves, tree cavities, or under and among
debris on the ground, coming out only at night to feed (Richards
1962, 1966, Hegg et al. 2019). Maotoweta virescens may be unique
among the described cave wéta species within NZ and globally, as
it appears to spend most, if not all, of its life cycle within arboreal
mosses and lichens. The cryptic coloration of the species further
supports its moss-dwelling specialization, as it undoubtedly func-
tions to conceal M. virescens from native visual predators, such as
insectivorous birds, while roosting within mosses during the day
and possibly from nocturnal predators such as ruru/morepork (Ni-
nox novaeseelandiae) while foraging at night. The diversity of color
morphs (see Fig. 5) suggests that M. virescens may have evolved to
inhabit and blend into a wide range of different micro-habitats.
The cavity-dwelling behavior of most other NZ cave wéta during
the day means they have less need for such cryptic coloration and
may explain why most are various shades of brown and gray. The
antennal folding behavior and exaggerated hind tibia spines of M.
virescens (see Johns and Cook (2014) for morphological descrip-
tion) further enhance the camouflage of this species. The double-
folding of the antenna possibly serves to conceal the species fur-
ther among its moss habitat by reducing its overall length while
also protecting them from damage. Tettigonids that rely on plant
mimicry are also known to conceal their antennae, with differ-
ent species displaying methods such as folding them along their
bodies, laying them flat along twigs, or in some cases deliberately
extending them in unusual positions to mimic the plants among
which they are hidden (Nickle and Castner 1995). The spines on
the hind tibia of M. virescens (clearly visible in Fig. 5C, D) closely
resemble the phyllids of the mosses within which they live. Evi-
dence for the effectiveness of this adaptation is shown by the
presence of similar spines in the unrelated Pleioplectron crystallae
Hegg, Morgan-Richards & Trewick, 2019, a ground dwelling spe-
cies of NZ cave wéta known to be a moss specialist (Hegg et al.
2019). Many tettigoniids also possess anatomical and coloration
adaptations to mimic mosses and lichens (e.g., Lichenodraculus
matti Braun, 2011), traits that Nickle and Castner (1995) suggest
evolved primarily to protect the insects against diurnal predators.
Further use of beating as a method to search for cave wéta may
reveal currently unknown species with similar habits, both within
NZ and in other parts of the world.

Mosses, lichens, and dead insects were documented here as
part of the diet of M. virescens and are also known to be consumed
by other cave wéta species (Richards 1962, Butts 1983). However,

J.M.H. TWEED, M. WAKELIN, B. MCKINLAY AND TJ. MURRAY

Fig. 6. Adult female Maotoweta virescens exhibiting the double an-
tennal folding behavior displayed by this species when roosting
within their moss habitat during the day.

-

M. virescens was not observed feeding on vascular plants, even
though ferns and angiosperms are a major dietary component of
other cave wéta such as Insulanoplectron spinosum Richards, 1970b
(Butts 1983), Macropathus filifer Walker, 1869 (Richards 1954),
Pachyrhamma waitomoensis Richards, 1958 (Richards 1962), and
Pallidoplectron turneri Richards, 1958 (Richards 1962). Apparent
diet specialization on moss and lichen has been documented for
the ground-dwelling P. crystallae (Hegg et al. 2019), and the same
may be the case for M. virescens, although they are likely to be op-
portunistic feeders given that they were documented feeding on
dead insects in this study. Further work is required to understand
the full dietary range of M. virescens.

Rearing NZ cave wéta species from eggs and/or nymphs to
adulthood has been found to be challenging (Richards 1961, Butts
1983) and was not attempted here. However, based on our ob-
servations and knowledge of other cave wéta species, we suggest
several hypotheses about the life history of the species for future
testing. Adult M. virescens have been recorded from December to
March, and as one of the females collected here was observed un-
dergoing its final molt in early March, it appears maturation can
occur from at least early summer to early autumn. Although it was
not observed during this study, mating has been observed in both
December (Johns and Cook 2014) and in March (https://inatural-
ist.nz/observations/21440116). Oviposition therefore likely occurs
throughout summer into early autumn, and eggs may be laid in
the rotting wood of trees, as has been observed for the other arbo-

JOURNAL OF ORTHOPTERA RESEARCH 2023, 32(1)

J.M.H. TWEED, M. WAKELIN, B. MCKINLAY AND T.J. MURRAY

250

Wilcoxon test, p = 0.038

NO
[os]
(=)

©

=x
a
f=)

=
fo)
(=)

Mean time per specimen (minutes)

a
(>)

Beating (n=6)

Night searching (n=3)
Survey method
Fig. 7. Mean number of minutes searched per Maotoweta virescens
individual detected during timed beating and active night search-
ing surveys. The results of the Wilcoxon rank sum test are given.

real cave weta including Isoplectron armatum (e.g., https://inatural-
ist.nz/observations/91211038) and Talitropsis sedilloti (e.g., https://
inaturalist.nz/observations/2693757).

Among Orthopteran families such as Tettigoniidae (Hartley
and Warne 1972) and Anostostomatidae (Stringer 2001), the dura-
tion of the egg stage is known to be highly variable between species
and sometimes within species or even egg clutches. Similarly, the
eggs of some species undergo notable diapause while others do not
(Hartley and Warne 1972). Relatively little is known about the du-
ration of the egg stage in Rhaphidophoridae, with estimates vary-
ing greatly between species, ranging from one week to four months
for the North American Daihinibaenetes giganteus Tinkham, 1962
(Weissmann 1997) and up to eleven to twelve months for the Aus-
tralian Pallidotettix nullarborensis Richards, 1968 (Richards 1970a).
As such, one theory is that the eggs of M. virescens may overwin-
ter and hatch relatively synchronously the following spring, with
adults maturing approximately one year later. A seasonal lifecycle
with a prolonged egg stage has been documented for the much
larger Pachyrhamma waitomoensis with the egg stage lasting six to
seven months (Richards 1961). Pallidotettix nullarborensis also has a
prolonged egg stage, which Richards (1970a) proposed was likely
to ensure eggs hatched during optimal climatic conditions.

An alternative to the above theory is that M. virescens has a
short egg development period. This would mean that egg hatching
occurs relatively quickly after mating and oviposition in summer/
autumn. Nymphs would then overwinter in their early- to mid-
instars before reaching maturity the following year in late spring
to early autumn. Similar seasonal lifecycles have been document-
ed for other rhaphidophorids including Pachyrhamma edwardsii
(Scudder, 1869) from NZ (Richards 1961) and Hadenoecus subter-
raneus (Scudder, 1861) from North America (Hubbell and Norton
1978). Conversely, in P. turneri, instars of all ages can be found
cohabiting with adults at any given time of year, suggesting an ase-
asonal lifecycle (Richards 1961). De Pasquale et al. (1995) found
that Dolichopoda spp. exhibit aseasonal or seasonal development
depending on whether they occupied natural or artificial cave sites,
respectively, suggesting that the trait may be flexible for at least
some rhaphidophorid species. For M. virescens, a univoltine cycle
with reasonably strong seasonal synchrony in egg hatching is sup-
ported in the current study by the detection of only young nymphs
and adults between January and March (mid to late summer). If

51

M. virescens displayed an aseasonal lifecycle, it would be expected
that nymphs of all ages would have been recorded during the pre-
sent study, similar to what Richards (1961) observed for P. turn-
eri. Although based on evidence of only a single specimen, the
relatively long ovipositor of the female nymph collected in June
(winter) from the Karangarua Valley compared to all other meas-
ured nymphs further supports this, as ovipositor length is known
to be one of the best indicators of nymphal development among
NZ cave wéta (Richards 1961). Further sampling effort is required
across all months and seasons to confirm this proposed theory.

The lack of mid-instar nymphs observed during this study may
alternatively be explained by an ontogenetic niche shift in M. vire-
scens. For example, M. virescens may move up higher into the for-
est canopy during the mid-instar phases of its lifecycle. Cherrill
and Brown (1992) documented ontogenetic shifts in microhabi-
tat preference in the bush cricket Decticus verrucivorus (Linnaeus,
1758). Within the Rhaphidophoridae, ontogenetic niche shifts
have been documented for Hadenoecus subterraneus, which only
begins to leave its cave habitat to forage at night once it reaches the
fifth instar (Hubbell and Norton 1978). Interestingly, Dolichopoda
spp. also display variation in feeding habits and diet with age;
however, it is the subadults that differ from other life stages as
they tend to feed outside of caves while adults and early-instar
nymphs feed almost exclusively on resources within the cave (de
Pasquale et al. 1995).

As has been found for other cave wéta species (e.g., Richards
1961, Butts 1983), the sizes of M. virescens nymphs measured
here did not fall into discrete size classes corresponding to instar.
The number of instars for other rhaphidophorids varies between,
and possibly within, species and sexes (Hubbell and Norton
1978). For example, Pachyrhamma edwardsii has ten nymphal in-
stars in the male and nine in the female (Richards 1961), while
Insulanoplectron spinosum has nine in the male and ten in the fe-
male (Butts 1983). Because no mid- to late-instar nymphs were
found, we are not able to give an accurate estimate of the number
of nymphal instars for males or females of M. virescens. Clearly,
further work is required to fully understand the life history of
M. virescens and to test the various theories posed here.

When Johns and Cook (2014) described M. virescens, they be-
lieved it to be one of NZ’s rarest cave wéta species. The authors
presumably based this assumption on the difficulties that they
encountered detecting the species while undertaking targeted
night searching in the Takitimu Mountains, as well as the rela-
tive absence of M. virescens specimens within NZ’s entomologi-
cal collections. However, prior to the current study, no large-scale
survey had ever been conducted for M. virescens specifically. The
evidence presented here suggests that M. virescens may not be rare.
By compiling all known records, as well as conducting targeted
surveys using an ecologically appropriate method (i.e., beating),
M. virescens has been shown to be geographically widespread with-
in temperate South Island forest habitat and, in some cases, rela-
tively abundant. Although beating can be an effective means of
collecting some arboreal Orthoptera (Sperber et al. 2021), includ-
ing the arboreal Nearctic rhaphidophorid Gammarotettix bilobatus
(Stidham 2005), it has not typically been employed as a collecting
method for NZ cave wéta (e.g., Johns and Cook 2014, Hegg et al.
2019, 2022). Our findings suggest that active night searching, the
traditional method of cave wéta detection, is less effective for the
detection of M. virescens than beating in mixed temperate forest,
likely explaining why the species has not been detected regularly
in the past. This may explain why the first two known specimens
of the species were detected by the late Dr. R. R. Forster (see Johns

JOURNAL OF ORTHOPTERA RESEARCH 2023, 32(1)

52

and Cook 2014), an esteemed arachnologist who routinely em-
ployed beating to target spiders. Future studies of rhaphidophorid
diversity should consider employing foliage and moss beating as
part of their collection methods.

Within the open beech forest habitat of Princhester Creek in
the Takitimu Mountains, beating proved only marginally more ef-
fective at detecting M. virescens than night searching. This result
may indicate that open beech forest represents sub-optimal habitat
for M. virescens, meaning densities are naturally low. It could also
reflect the relative lack of hanging mosses within this habitat type,
which made beating more difficult. Habitat structure is known to
affect the efficacy of some Orthopteran survey methods, includ-
ing sweeping (Gardiner et al. 2005), hand collection (Bailey et al.
2003), and pitfall trapping (Schirmel et al. 2010). Targeted surveys
employing both beating and night searching may be required to
fully understand the relative abundance, ecology, and distribution
of M. virescens. It should be noted that the results of the beating
and active night searching surveys presented in this study are a pre-
liminary comparison in locations already confirmed as suitable
M. virescens habitat and are based on relatively small sample sizes.
It is likely that the total amount of survey time taken to detect the
species will vary from those documented here, particularly in sur-
veying sites in which the species occurs at naturally low densities,
as may be the case for open beech forest.

The field work reported here was completed as part of a wider
project to investigate the distribution of Data Deficient inverte-
brates in southern NZ (Tweed and Wakelin 2021). Such work is
essential for many of NZ’s cave wéta species, as well as numer-
ous other poorly known invertebrates, as a prerequisite to enable
effective threat classification and to inform whether conservation
management is required. This study has greatly improved our
knowledge of the cave wéta M. virescens and provided a more ef-
fective method to detect the species. The evidence presented indi-
cates that the weta has a much wider distribution than previously
thought, indicating a reassessment of the species threat status
was required. The evidence presented was assessed by the NZTCS
panel and contributed to the reclassification of the species as Not
Threatened (Trewick et al. 2022).

Acknowledgements

Thank you to all the volunteers who assisted with the field sur-
veys during which this research was conducted: Steve Kerr, David
Mayo, Liz Sherwood, and Nichaela Harbison-Price. Thank you to
Billy and the Deep Cove Outdoor Education Trust for providing
accommodation during fieldwork in Doubtful Sound. Thank you
also to Tony Jewell, Rod Morris, and Danilo Hegg for providing
location data and ecological notes from their encounters with
M. virescens. Thanks to all the curators who kindly responded to
requests about specimens within their collections: Kane Fleury
(OMNZ), Phil Sirvid (MONZ), John Marris (LUNZ), Johnathon
Ridden (CMNZ), John Early (AMNZ), and Grace Hall (NZAC).
The authors would also like to thank Danilo Hegg, Tony Jewell,
and Steve Kerr for their helpful comments and suggestions on a
draft of this manuscript, as well as the valued input of the two re-
viewers. Thanks also to Ahika Consulting who supported the first
author during this research. This research was partially funded by
the Department of Conservation Te Mana o Te Taio Threatened
Species Research Data Deficient programme (Contracts DOC-
6442664 and DOC-6665718). We also thank the Orthopterists’
Society and the editors of JOR for supporting the publication of
this paper.

J.M.H. TWEED, M. WAKELIN, B.

MCKINLAY AND TJ. MURRAY
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