Research Article

Journal of Orthoptera Research 2022, 31(2): 143-156

New species of awl-head katydids, Cestroohorus and Acanthacara,
from the Andes of Ecuador (Orthoptera, Conocephalinae, Cestrophorini)

HOLGER BRAUN!, GLENN K. Morris?

1 Divisi6n Entomologia, Museo de La Plata, Paseo del Bosque s/n°, 1900 La Plata, Argentina.
2 Biology Department, University of Toronto at Mississauga, 3359 Mississauga Rd, ON, Canada.

Corresponding author: Holger Braun (braun@fcnym.unlp.edu.ar)

Academic editor: Klaus-Gerhard Heller | Received 15 February 2022 | Accepted 8 April 2022 | Published 30 September 2022

https://zoobank. org/42CACG6FO0-6424-4883-B0B5-A81CE88A71 BE

Citation: Braun H, Morris GK (2022) New species of awl-head katydids, Cestrophorus and Acanthacara, from the Andes of Ecuador (Orthoptera,
Conocephalinae, Cestrophorini). Journal of Orthoptera Research 31(2): 143-156. https://doi.org/10.3897/jor.31.82306

Abstract

The Cestrophorini are small katydids of Ecuador’s montane rainfor-
est bearing a prominent awl-shaped fastigium verticis. They are unusual
among Conocephalinae in lacking pre-tympanic ear chambers: their ear-
drums are exposed on their fore tibiae. There are presently two genera,
Cestrophorus Redtenbacher, 1891 and Acanthacara Scudder, 1869. Awl-head
habitat includes both climax forest and anthropogenically disturbed areas
(e.g., pastures, roadsides) on lower slopes in the drainage of the volcanoes
Aliso, Chiles and Tungurahua. At night, males perch on low vegetation
and stridulate to attract females. To three extant species, we add a further
seven, two in Cestrophorus and five in Acanthacara. Male calling songs were
recorded and analyzed for all three Cestrophorus species and for three of the
Acanthacara spp. We describe and discuss the waveforms of their sinusoid
and transient sound pulses in time and frequency domains.

Keywords

bioacoustics, ear, fastigium, montane, sinusoid, song, spectrum, stridula-
tion, transient

Introduction

Dita Klimas and Glenn Morris made several trips to the
Ecuadorean Andes (Fig. 1) between 1983 and 2003 in search of
tettigoniid sound signals. Near Banhos on pasture slopes of Volcan
Tungurahua (Fig. 2) and in remnant wet forests southwest of
Baeza' (Fig. 1), they found species of small conocephaline katydids
(Fig. 3). These insects are characterized by a glistening black
frons, a prominent, distally attenuated tip-deflected fastigium of
the vertex recalling a cobbler’s awl (Fig. 4) and, peculiar among
conocephalines, superficial tibial tympana, i.e., eardrums not
recessed within slitted chambers (Fig. 5). At present, these
Andean ‘awl-head’ insects comprise just two genera: Cestrophorus
Redtenbacher, 1891 and Acanthacara Scudder, 1869 in the tribe
Cestrophorini Gorochoyv, 2015.

The holotype female of Acanthacara acuta Scudder, 1869 was
collected in 1867 by the naturalist James Orton. As he recounts in
The Andes and the Amazon, Or Across the Continent of South America
(Orton 1870), his party journeyed eastward by horse from Quito,
over the mountains on a rugged trail via Papallacta to Baeza and
Cosanga, then across the Rio Cosanga and on downvalley toward
Napo (Archidona, Tena). The Orton expedition’s Orthoptera
specimens were subsequently identified and named by Samuel
H. Scudder (1869); on one of these specimens, a female, Scudder
established a monotypic new taxon, Acanthacara acuta . This holo-
type, deposited in the Harvard Museum, lacks forelegs, making it
evident why Scudder makes no mention of naked tympana.

In his 1891 monograph on Conocephalidae, Josef Redtenbacher
names a conocephalid with superficial tympana: Cestrophorus
paradoxus Redtenbacher, 1891. “Ausgezeichnet durch das offene
Trommelfell an den Vorderschienen” |Distinguished by the open
tympanum on the fore tibiae.| This species is based upon a lone
male specimen labeled as from Madagascar. Label information
is “Coll. B. v. Watt. Central Madagascar Dr. H. Dohrn”. A very
effective colored drawing of the specimen given in Karny’s Genera
Insectorum (1912, plate 8, item 16) is reproduced here (Fig. 6). On
February 10 and 19, 1988, we (Dita Klimas and GKM) collected
amongst a large calling deme of this species, males stridulating
at dusk in understory vegetation along a trail beside the loud
cascade of the Rio Aliso, near where it joins the Rio Cosanga—a
locale very far from Madagascar. The two white maculae on the
pronotal metazona of the males helped in detection and capture.
One supposes Redtenbacher’s choice of the name paradoxus may
have something to do with his finding Madagascar an odd locality
or perhaps he reacted to the open eardrums (Since Dohrn only
travelled to western Africa, this is likely a case of mislabeling of a
specimen coming from his collection in the museum at Stettin).

Recently, Gorochov (2015) described a male specimen of a sec-
ond Acanthacara species, A. ridiculosa Gorochov, 2015, taken near
the San Rafael Waterfall. This locality is east of the road junction

1 An earthquake in March 1987 damaged the historic townsite of Baeza and led to the creation of a ‘displaced Baeza’ farther east; our collecting was
upslope of the elder Baeza in remnant forest along a path beside a small gurgling stream.

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

144 H. BRAUN, G. K. MORRIS

infas +

Bx : ce r= yacach
on os {
/ ‘ oe o
Wa OLEQ
Atacaze ai) 4 i DUCTS Tf iy, e E
i cu aa) Rio ce
> _pytleave QS . 2

kaQu nad \E " oi Mn

ew lLay.4e YOrmida™

Ae “ tabills gh ps MiCrta Pubes uy :
storga- GH ja eg
“a
Al “9 a

} Rio/Be [hejo

ey
ig Qe
Diaz de Pine

> Santa Rosa de ut7os

San Francisco/de Borja

BAEZA

be Berngion (~~ oe
UM i Ae mA |
< Zz RO ALSO Ware
ayy és cata Cosanga
Ny) x e 2
63
ae ay?
\ a ~ am i
alle AO) _;; dv
{ , Qe os c Mle de * Saraya
} ‘Iss PS duslis dar ia = be recy
chi® pe") © wate Algy da 3 LARS : Ric
wll! By pos a oS
(@y’ osequandsé Bajo : alupas is
nies ( 5 Rio we Pangaydcy- ) Ge ao
b Ala quez oe : Mondapag= a a
eer a Rio eI pee ~ “f
2 Laney N N
ce oO
y at A CUNG p RO
' ners © eee
Lae D® R >=

ss Belisario

LCEDO}! { @ Mulligui

N Pa zalieo 46 p, LES,
Pe : hy
ics eh. rng Nan = See

peeaiguin S66 José Poalb— ce

, ye: Andrés oe jes
\(Présidente Urbina \_ 2 gna ve
B) @\ Marcos EspinetA en me
p PILLARO © J \(

Wy. Miguelit Y ones
Emilié Maria ferép>
agqueriip-Me / is, 3

y™ \Sucre
| os Andes| wv x » -
PATATE E! Trum oo Sy ;
SPENLEO Kj & (fH
a, oy o
hagoh ,
©. Rio’ Verde

BANOS Cio-Pattaze Se Negro of
Fatima

PUYO

~ Guanandd/

op;

Dayano

fey Ms bia

= Araius?

/ : 4 f / » 3 aie 5
ee apa
, Teniente ude Oy se 2 ‘ r
R, gy = ee A a reyes |

llapo™ //@ 4 oo @. Veracruz
Provideicia: Senora osde Bayushig . Madre Tie \ arqui
an_tsidro K,\ \

13 P S®. Indillana

Fig. 1. Part of a map, Republica del Ecuador, Instituto Geografico Militar; scale 1:1,000.000. Banos, north of the volcano Tungurahua,
is bottom left. Papallacta is top left, just north of Volcan Antisana; Baeza is down-valley to the east. Cosanga the town and Rio Cosanga
are near map center, a few km beyond Baeza in the direction of Archidona.

at Baeza, farther downvalley in the direction of Coca. Gorochov
grouped Acanthacara and Cestrophorus, making the latter the type
genus of a new tribe, Cestrophorini (Gorochov 2015).

We present nine species of Cestrophorini; all but one,
Cestrophorus amplitenuis sp. nov., are from the drainage of
volcanoes Aliso and Tungurahua, including probable males of
Acanthacara acuta. We have examined a set of photographs of
the A. acuta type female, kindly provided by Piotr Naskrecki

and of higher resolution than those previously available on
the Orthoptera Species File Online (Cigliano et al. 2022); our
females compare convincingly. The new species C. amplitenuis
sp. nov. was located in Provincia Carchi, along a road (182)
leading from Tofino (nr Tulcan) to the town of Maldonado’; a
large population of singers were found roadside at night, several
kilometers west of the Espeletia-dotted paramo of Volcan Chiles
and a few kilometers east of Maldonado.

2 Pedro Vicente Maldonado was a famous Ecuadorean scientist, cartographer, etc., of the 18" century. His name appears on two towns in Ecuador: this

in Prov. Carchi, but also another in the neighboring Prov. of Esmeraldas.

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

H. BRAUN, G. K. MORRIS

Fig. 2. Volcan Tungurahua emerges from clouds, 1983.

Calling song analyses of three of these cestrophorines com-
prised a poster paper by GKM in 1987 at the VI" International
Meeting on Insect Sound and Vibration at Odense, Denmark. At
the time, these species were planned to belong to a new genus
“Gymnacoustes”, a reference to their naked tympana. The ISV post-
er’s ‘Gymnacoustes isoharmonicus’ (here reproduced as Fig. 17) is
the species herein designated Acanthacara ortoni sp. nov., and the
poster's ‘G. unizip’ is Acanthacara incisa sp. nov. (Fig. 18). The spe-
cies epithet ditachus resides now in the genus Cestrophorus.

A superficially similar undescribed conocephaline from mon-
tane areas on the slopes of Volcan Pichincha (near Quito) is read-
ily distinguished from Cestrophorini by its possession of slitted
pre-tympanal chambers and a large subnotal resonance cham-
ber formed from the pronotal metazona. This insect is termed
"Agraeciine x" by Morris and Mason (1995). This same species
is misidentified as Acanthacara acuta in a recent paper (Jonsson
et al. 2017).

Methods

Dita Klimas and GKM hunted perched katydids by sight at
night, scanning by headlamp the vegetation bordering forest paths
and taking photographs. The stridulation of tropical tettigoniids
is not always useful in revealing a singer's location, but we were
also aided by heterodyne devices (‘bat detectors’). Specimens were
captured by hand-herding into an insect net then transferred in-
dividually to small plastic jars. Some field recordings were made
using a Sony Walkman tape recorder (WM DGC Stereo Cassette-
Corder with an ECM 909 microphone) and are limited to the au-
dio frequency range.

145

rab’

Fig. 3. A live male of A. incisa collected roadside just below the small
settlement Pondoa on northern aspect of Volcan Tungurahua, July
1985. Locality in a field name is a bad idea: when what you have
christened "Baeza Blackface" is apparently taken later near Bahos
and you have to reference it as Bafos' Baeza Blackface, confusion is
likely, especially when these specimens sort into more species later.

A subset of specimens were individually caged, maintained on
pieces of apple, and transported alive via jet aircraft to Toronto,
Canada. Here, as they called from a small cylindrical aluminum
screen cage, their songs were recorded, with equipment reaching
into the ultrasonic (Bruel & Kjaer 4" microphone 4135 or 1/8"mi-
crophone 4138), onto a Racal Store 4 DS Instrumentation Tape
Recorder running at 30”/s. The microphone output went initially
to a B&K Impulse Precision Sound Level Meter 2204. This in-lab
recording system responded to sound frequencies flat to 70 kHz.
Room temperature was ~21°C.

Analysis of analog tape recordings began with digitization. A
Krohn-Hite filter (Model 3202) band-passing 125-15000 Hz was
employed to anti-alias sound frequencies input to a computer
sound card via Cool Edit. The Racal playback was slowed by a fac-
tor of 8, so a Cool Edit sample rate of 22050 Hz sufficed to digitize
any real-time ultrasonics. Output from the Sony Walkman record-
er running in real time was digitized at 48000 samples per sec-
ond. Fourier transforms were then calculated using the windowing
spreadsheet DADiSP (DSP Development Corp.). Figures of time
and frequency domain analyses were made using Corel Draw.

Repositories are the Museo de La Plata (MLP) and the Acad-
emy of Natural Sciences in Philadelphia (ANSP). Additional pic-
tures, including all holotypes, will be available on Orthoptera Spe-
cies File Online (Cigliano et al. 2022).

Taxonomy
Cestrophorini Gorochov, 2015

Small agraeciine-like conocephalines with fully exposed tym-
pana. Tegmina in males covering up to the entire abdomen or re-
duced to about pronotum length; in females, rudimentary or ab-
sent. Coloration light yellowish brown to greenish, with whitish,
dark brown, or black markings and patterns. Fastigium of vertex

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

146 H

. BRAUN, G. K. MORRIS

Fig. 4. Scanning electron micrograph (SEM) of male A. ortoni fastigium verticis.

Fig. 5. SEM of superficial tympanic membrane on proximal tibia
of A. ortoni.

acutely pointed, from just projecting beyond antennal scapus to
quite long, slightly downcurved or almost straight. Acoustic spira-
cle tiny, exposed below ventral margin of pronotum. Prosternum
unarmed. Ovipositor of females about as long as head and prono-
tum combined, slightly upcurved (lower margin strongly curved,
upper margin little curved or almost straight), moderately broad
with acuminate tip. Inhabiting Andean foothills of Ecuador.

Cestrophorus Redtenbacher, 1891

Etymology.—From original description: Greek kéotpo — Latin subula
[shoemaker’s awl] and épw — fero [bear, carry], surely referring to
the notable fastigium: “fastigium verticis articulo primo antennarum
fere duplo longius, subulatum, decurvum” (Redtenbacher 1891).
Diagnosis. —Small, robust to moderately compact. In males, pro-
notum posteriorly widened and metazona usually at least slightly
elevated; male tegmina covering abdomen completely or leaving
only tip exposed, left tegmen uniformly with coarse venation and
long cubital vein occupying considerably more than half of total
width. Male cerci short, broad, dorsally with obtuse medial lobe,
below that terminating in acuminate inward curved spine, and ven-
trally at the base with another upcurved spine. Male subgenital plate
with very short styli, almost looking like latero-terminal tips rather
than separately articulated styli, sometimes completely reduced.

Cestrophorus paradoxus Redtenbacher, 1891
Figs 6, 8A, B, 11, 12

Material examined.—ECUADOR e 3; Rio Aliso; 4 Jul. 2003; G.K.
Morris leg.; MLP ¢ 6 4; Rio Aliso; 10 Feb. 1988; G.K. Morris leg.;
ANSP ¢ 6 3; Rio Aliso; 19 Feb. 1988; G.K. Morris leg.; ANSP
¢ 5 3d; Rio Aliso; 4 Jul. 2003; G.K. Morris leg.; ANSP ¢ 1 9; Rio
Aliso; 19 Feb. 1988; G.K. Morris leg.; ANSP ¢ 192; Cosanga; 10 Feb.
1988; G.K. Morris leg.; MLP.

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

H. BRAUN, G. K. MORRIS

ORTHOPTERA

(estrophorus paradoxus, Redtenbacher.

Fig. 6. C. paradoxus. Illustration of male adult from Karny H.,
1912. Genera Insectorum Orthoptera Fam. Locustidae, Subfam.
Agraeciinae (Plate 8, item 16).

Redescription.—Robust with fastigium projecting well beyond
scapus. Males with contrasting coloration: fastigium blackish, dor-
sal surface of pronotum medially dark, in prozona and metazona
blackish, in metazona broadly trapezoideal and fringed by a pair
of ovoid elongate whitish lateral maculae (Fig. 8A), thin distal
portion of hind tibiae blackish. Male tegmina greenish, broad-
ened beyond width of pronotum and covering abdomen com-
pletely. Male cerci approximately broadly triangular in dorsal and
lateral view, obtuse medial lobes with inconspicuous obtuse and
recurved hook, almost touching in the middle, cercus terminating
in sharp upcurved spine, and at the base with long and more or
less perpendicularly upcurved spine (up to beyond the height of
the dorsal hook).

147

Fig. 7. C. amplitenuis pair mating in the field; part of a large deme
of singers in shrubby roadside vegetation at the type locality near
Ecuador's northern border with Colombia. Female lacks wings.

Measurements.—Male: midline pronotum 4.6 mm, fastigium
verticis 1.8 mm, tegmina 9.2 mm; female: midline pronotum
3.8 mm, fastigium verticis 1.7 mm (based on two specimens, no
apparent variation in size).

Note.—All specimens—in February 1988 and again in July
2003—were taken from beside a forest path tracing the south bank
of the Rio Aliso upstream; the site is reached by a (very) secondary
road branching west from the main highway just before the town
of Cosanga. About 3 km along this sideroad is the lodge Cabanas
San Isidro; a few km farther on, a posted sign at an iron bridge
identifies the Rio Aliso.

Cestrophorus ditachus sp. nov.
https://zoobank.org/39B53563-0D85-42CA-8DF2-80F9C45018AB
Figs 8C, D, 13

(‘Gymnacoustes ditachus’ Motris, 1987)

Material examined.—Holotype: ECUADOR e <; old Baeza; 11 Jul.
1985; G.K. Morris leg.; SN-2, MLP. Paratypes: ECUADOR e 1 0;
old Baeza; 10 Jul. 1985; G.K. Morris leg.; 85-1, Glassy Tegmina,
ANSP ¢ 1 3; Tungurahua; 25 Feb. 1985; G.K. Morris leg.; GLASSY
TEG, SN-3, ANSP ¢ 1 9; Cosanga; 19 Feb. 1988; G.K. Morris leg.;
MLP e 1 9; Cosanga; 19 Feb. 1988; G.K. Morris; ANSP.

Etymology.—Named for its two-part, two-pulse-rate, song struc-
ture, readily apparent to the human ear in real time. Greek 61 di
[two], tacénoo tachos [speed]. This insect is also named (inadvert-
ently but deservedly) for Dita Klimas, katydid field photographer
extraordinaire.

Diagnosis. —More slender and uniformly colored than
C. paradoxus, with shorter tegmina. General coloration pale
greenish; in males, metazona of pronotum with brown
trapezoidal spot fringed by elongate whitish lateral spots. Male
tegmina leaving abdomen tip exposed. Females uniformly
greenish and apterous. Male cerci with obtusely triangular
dorsal lobe (internally with inconspicuous toothlet at the tip)
and robust inward-curved acuminate spine, baso-ventral spine
with broad base and tapering in perpendicularly upcurved tip;
above it on same lobe, another short spine (difficult to see). Styli
completely reduced.

Measurements.—Male: midline pronotum 4.3 mm, fastigium
verticis 1.7 mm, tegmen 7.5 mm, hind tibiae 8.6 mm; female: mid-

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

148 H. BRAUN, G. K. MORRIS

Cestrophorus spp.

paradoxus

proximal/ventral tooth

ditachus

_ distal/terminal tooth

proximal/dorsal tooth

-

amplitenuis amplitenuis

Fig. 8. Cestrophorus spp. male genitalia compared. A. White pronotal maculae of C. paradoxus; B. Parameres of C. paradoxus ‘upside-
down dancing anteaters’; C. Dorsal aspect C. ditachus parameres; D. Lateral view of C. ditachus paramere; E. Photo of terminalia of
C. amplitenuis; F. Lateral aspect of C. amplitenuis paramere.

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

H. BRAUN, G. K. MORRIS

line pronotum 4.1 mm, hind tibiae 9.7 mm, ovipositor 8.7 mm
(based on holotype and one paratype).

Field notes. —We hunted in light rain at the [historic pre-earth-
quake] townsite of Baeza, along a muddy rock-strewn trail fenced
by barbed wire, uphill beyond the hospital and cemetery on the
night of July 10, 1985. We recorded and captured one male ‘agrae-
ciine’ of “pearly pale cast”, [like C. paradoxus| with white maculae
prominent laterad on its pronotal metazona, its very pale greenish
tegmina shorter than the abdomen, and its eardrums not recessed
behind slits [field name ‘glassy tegmina’]. This specimen is now the
holotype male. On July 11, GKM recorded another singer up the
eastern branch of the trail above Baeza but failed to capture him.

On July 25, 1985, we drove from Quito and parked part way
up Volcan Tungurahua at signed "ecological reserve" hut under
construction, below Pondua. Many C. ditachus sp. nov. were heard
singing from shrubby vegetation scattered about a pasture (never
a bovid seen). GKM “recorded a male singing from well above
my head in a clump of bamboo and one small hardwood tree.
After recording, we bent the bamboo down and searched the foli-
age with our lights,” finding and capturing the presumed singer.
“As we left the immediate vicinity of the road and climbed several
hundred feet, the incidence of [C. ditacus sp. nov.] singers declined
to zero. They had ceased calling by 10:30 pm. Chilly and soon one
could only hear single quiet lisps recurring at intervals of several
seconds, presumably Acanthacara incisa.”

Cestrophorus amplitenuis sp. nov.
https://zoobank.org/F43EDD15-D715-4F3A-AADD-9426CBO4ADFF
Figs 7, 8E, F, 14

Material excamined.—Holotype: ECUADOR e <; Prov. Carchi, hwy
182, e. of Maldonado; 16 Apr. 1990; G.K. Morris leg.; MLP. Para-
types: ECUADOR ® 1 9; Prov. Carchi, hwy 182, e. of Maldonado;
16 Apr. 1990; G.K. Morris leg.; ANSP ¢ 7 3G, 2 2Q; Prov. Carchi,
hwy 182, e. of Maldonado; 16 Apr. 1990; G.K. Morris leg.; ANSP
e 4 3d; Prov. Carchi, nr. road btwn Maldonado and Tulcan, s.
of Rio La Plata, 3100 m., primary forest; 26-31 Jul. 1988; Glenn,
Pedersen & Wechsler leg.; ANSP on loan to GKM.

Etymology.—Named in reference to the ‘dying fall’ of each
call’s amplitude: each song emission begins as intense sinusoids
that then diminish (Fig. 14 B,C). Latin amplio [made large],
tenuis [thin].

Diagnosis.—As C. ditachus, more slender than C. paradoxus. Fas-
tigium short and projecting only a little beyond scapus. General
coloration light amber; in males. dorsal surface of pronotum me-
dially dark brown, with whitish lateral fringes, especially in meta-
zona. Male tegmina slender, almost as long as abdomen but leav-
ing tip exposed. Females apterous. Male cerci with obtusely trun-
cated dorsal lobe and acuminate terminal spine; ventro-internal
process uniformly thin, fairly long, and slightly twisted.

Measurements.—Male: midline pronotum 4.4 mm, fastigium
verticis 1.1 mm, tegmen 7.3 mm, hind tibia 9.1 mm; female:
midline pronotum 4.0 mm, fastigium verticis 1.2 mm, hind tibia
9.5 mm, ovipositor 6.7 mm (based on holotype and one paratype).

Field notes.—A road (182) runs west along the Colombian bor-
der from Tulcan to Maldonado and beyond. The insects were tak-
en roadside roughly 50 km west of Tulcan. After Tofino, the road
climbs the slope of Volcan Chiles into paramo dotted with tall
columnar "grey friar" plants. Their flowers are like small sunflow-
ers in clusters. The road was (still is?) a single lane of rough wind-
ing dirt that favors switchbacks. We descended into a col of the
volcano and passed a strangely colored lake with the strong smell

149

of sulfur in the air. The light was beginning to fade as we crossed a
height of land on the west side of the volcano and began to stead-
ily descend. After proceeding downhill for several kilometers, we
left the paramo but were not yet into forest. We stopped here to
listen, the road bordered by shrubs and sedge, and heard singing.

Acanthacara Scudder, 1869

Etymology.—Not mentioned in the original description; probably
derived from Greek dxav0a — dcantha [thorn] and, as in Cestrophorus,
certainly referring to the vertex being “prolonged into a sharply
pointed, long and curved thorn” (Scudder 1869).

Diagnosis.—Habitus more slender compared to Cestrophorus,
with more delicately thin and elongate fastigium verticis. Tegmina
not much longer than the narrower and more elongate pronotum;
in males, the left tegmen with distinctively developed stridulatory
area with transparent fields, the vein with the stridulatory file un-
derneath relatively short. Male cerci not conspicuously broad at
base and male subgenital plate with distinct styli.

Redescription.—Small and slender, yellowish brown, brachypter-
ous coneheads with strongly oblique face and prominent, almost
straight or slightly recurved acuminate fastigium. Body length 17-
22 mm; fastigium length almost twice the eye diameter. Pronotum
shallow and rounded, dorsal contour flat or almost flat, posteri-
orly produced and in males diverging overtop bases of short teg-
mina that are of equal length or little longer than the pronotum,
leaving at least half of the abdomen uncovered in live individuals.
Stridulatory area of left tegmen subdivided in transparent fields
usually free from venation: a speculum lies right behind the short
cubital vein, and an adjacent lateral field lies left of this ‘mirror’.
The cubital vein is fairly bulgy and occupies half or a little more
of the total dorsal width of the tegmen. Females are apterous. The
tiny acoustic spiracles are directed latero-posteriorly. All genicular
lobes except the outer one of the fore tibiae armed. Male cerci at
base moderately wide, with more or less prominent distal dorsal
process and below that with another inward-directed process that
sometimes has a more delicate ventral appendage. Male subgenital
plate with short but distinct styli. Coloration ochre or light brown
with extensive black markings on face and with darker brown and
blackish markings and patterns on pronotum, abdomen and legs.
Living in montane woodland.

Notes.—All following diagnoses refer to males. Apart from the
development of male tegmina, the species can be distinguished
by the shape of male cerci. Measurements of the new species cor-
respond to the holotypes (there is no significant variation among
specimens of a particular species and there is little difference in
the body size of all species). It is difficult to assign females to cor-
responding males. Below the species accounts, a key to all seven
species is provided.

Acanthacara acuta Scudder, 1869
Figs 9A, 10A

Material examined.—ECUADOR ¢ 1 6; Rio Aliso, nr San Isidro
Resort, 2000 m; 2-6 Jul. 2003; G.K. Morris leg.; MLP ¢ 1 4; Baeza;
10 Jul. 1985; ANSP ¢ @; Cosanga; 10 Feb. 1988; G.K. Morris
leg.; ANSP.

Diagnosis.—Tegmina slightly longer than pronotum; venation
at costal margin sometimes greenish. Pronotum sparsely pubes-
cent and with contrasting coloration: lateral lobes dark, dorsal
portion light with dark median markings on front and rear mar-
gin, sometimes separation of dark lobes and lighter dorsal por-

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

150

A. acuta

A. ortoni

Fig. 9. Acanthacara spp. male genitalia compared.

tion developed as light medially restricted lateral stripes on disc.
Last tergite shallowly emarginate. Cerci in dorsal portion elongate,
inward-curved, and pointed; below that, another, slightly stronger
and also inward-directed pointed branch, with dorsally slightly
more sclerotized ridge, so the cerci look bifurcate in caudal view.
Styli very short but distinctive, 1-2 times as long as wide.

Measurements.—Pronotum 4.2 mm, tegmina 5.1 mm, hind
tibiae 9.1 mm.

Notes.—Our three males are so similar to the female holotype
of A. acuta that we consider them conspecific. Fastigium shape and
coloration details of the body match very well (the type is unfor-
tunately lacking all legs except its right middle leg). The female
was collected by the naturalist James Orton somewhere between
Quito and the Napo region (Scudder 1869). His expedition spent

H. BRAUN, G. K. MORRIS

|

A. brachycyma

ta

A. dyonessa

A. incisa

time in Baeza and then camped at a locality about 6 km further
south on the banks of the Cosanga River (Orton 1870). This is
the very area where our specimens have been found, as well as the
ones of the following two new species, which differ in coloration.
According to measurements of pronotum and hind femora in the
original description, the holotype appears to be adult, not a last-
instar nymph as Gurney (1972) suspected.

Acanthacara brachycyma sp. nov.
https://zoobank.org/B40DA89A-98F9-41D6-AE7A-01C907CD5E8A
Pigs 9B, 0Bs ali5

Material examined.—Holotype: ECUADOR e 4; San Isidro, nr
Cosanga; 2-6 Jul. 2003; G.K. Morris; MLP. Paratypes ¢ 7 3d; San

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

H. BRAUN, G. K. MORRIS

A

. acuta

B

. brachycyma

C

. Zigzag

D

. dyonessa

. ortoni

. incisa

ro

hs

Fig. 10. Acanthacara adult males compared in dorsal aspect.

Isidro, nr Cosanga; 2-6 Jul. 2003; G.K. Morris leg.; ANSP ¢ 1 ¢;
Cosanga; 10 Feb. 1988; G.K. Morris leg.; ANSP ¢ 1 9; San Isidro, nr
Cosanga; 2-6 Jul. 2003; G.K. Morris leg.; MLP ¢ 7 99; San Isidro,
nr Cosanga; 2-6 Jul. 2003; G.K. Morris leg.; ANSP.

Etymology.—Greek Bpayvc — brachys [short] and kvyoa — kyma
[wave], a reference to the predominantly ultrasonic spectrum of
the song (noun in apposition).

Diagnosis. —Fastigium almost straight, very tip slightly down-
curved. Tegmina about as long as pronotum, stridulatory area of
left tegmen with translucent fields occupying almost %4 of total
length, the bulgy vein with stridulatory file underneath barely
longer than mirror width. Pronotum with small blackish medi-
an spot on anterior margin (sometimes surrounded by a pair of
smaller spots) and up to five spots on the rear margin, the middle
one being the most prominent and the most lateral ones contigu-
ous with the dark coloration of the lateral lobes. Last tergite shal-
lowly bilobate. Cerci with a small dorsal tip and terminating in a
ventrally directed process. The dorsal tip is directed medially and
obtusely pointed. The ventral process is S-shaped, curving first in-
ward and then downward, with an acute tip.

Notes.—Very similar to A. ridiculosa Gorochov, 2015 and
distinguished by the following differences: no reticulation on mirror
area of left tegmen (dense venation network in ridiculosa according
to photo in Gorochov 2015, fig. 69, cannot be illumination
artifact); rear margin of last tergite shallowly emarginate without
distinct lateral tips, rather with very broad lateral lobules (more or

151

less distinctly rounded tips in ridiculosa, see ventral view in fig. 71
(Gorochov 2015) for true contour, probably no shrinkage artifact);
the secondary (dorsal) tip or process on the cerci is very short
when viewed from all possible angles, directed inward, and in
approximately same plane as terminal zigzag process (in ridiculosa,
sticking out in dorsal view, apparently quite long in ventro-lateral
view of fig. 72); the zigzag process is distinctly thinner than rest of
cercus and fully S-shaped: curved first perpendicularly inward—
not quite horizontally but slightly downward—and then halfway-
rearward and perpendicularly downward (in ridiculosa, not thin
over noticeable length, tip close to compact base, the inward-
curved part relatively shorter in dorsal view in fig. 70). There are
broad, thin and transparent, remotely cup-shaped structures below
the cerci into which the latter could be stored, perhaps belonging
to the paraproct, without any elongate or pointed processes (in
ridiculosa, corresponding structure with conspicuous processes
visible in fig. 70 and looking acutely pointed in ventral view in
fig. 71). Subgenital plate shallowly emarginate, with two lobes
between the styli and with very short styli that are hardly twice as
long as wide (the subgenital plate of ridiculosa has a straight rear
margin and the styli considerably longer according to figs 71, 72).

Measurements.—Pronotum 4.3 mm, tegmina 4.0 mm, hind
tibiae 9.3 mm.

Acanthacara zigzag sp. nov.
https://zoobank.org/21093D8A-D9B0-486E-A67C-ABA40D71DD7D
Figs 9C, 10C

Material examined.—Holotype: ECUADOR e @; old Baeza; 10 Jul.
1985; G.K. Morris; MLP. Paratypes: ECUADOR e 3 4d; old Baeza;
10 Jul. 1985; G.K. Morris leg.; ANSP ¢ 1 4; old Baeza; 23 Apr.
1989; G.K. Morris leg.; ANSP.

Etymology.—Named for the alternating acute-angle direction
changes of the male cerci.

Diagnosis.—Very similar to preceding species, with slightly
longer cubital vein (longer than width of mirror) and different
cerci. Fastigium almost straight. Tegmina of same length as prono-
tum; pronotum with 1 or 3 small blackish spots on anterior mar-
gin and 3 larger spots on rear margin. Last tergite ending in two
lobes. Cercus with pointed medial branch, rectangularly inward-
directed; below that, another inward-directed process with thinner
and downward-directed appendage terminating in acute spinule.
The structures below the cerci, mentioned for the previous spe-
cies (see notes on comparison with A. ridiculosa above), here have
obtuse posterior tips.

Measurements.—Pronotum 4.0 mm, tegmina 4.3 mm, hind
tibiae 7.6 mm.

Acanthacara dyonessa sp. nov.
https://zoobank.org/D5BC4C3E-F9 DF-4F7C-99D5-399 6BDA5EAID
Figs 9D, 10D

Material examined.—Holotype: ECUADOR « <; old Baeza; 8 Apr.
1989; G.K. Morris; SN-2; MLP. Paratypes: ECUADOR e 2 3;
Rio Huagra Yacu near Baeza; 9 Apr. 1989; G.K. Morris leg.; ANSP
e 1G; Baeza; 23 Apr. 1989; G.K. Morris leg.; ANSP ¢ 1 3; Baeza;
11 Jul. 1985; G.K. Morris leg.; ANSP.

Etymology.—Greek dyo [dive], nessa [duck] — referring to shape
of male cerci resembling a diving duck.

Diagnosis.—Fastigium slightly longer than in other species.
Tegmina as long as pronotum. Pronotum with small blackish spot

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

152

on front margin and more or less extensive spot on rear margin.
Cerci with bulky and obtuse in- and upward-directed tip, below
that with another half as bulky inward-directed process, which has
a thin digitiform and pointed ventral appendage. Styli very short
and looking like lateral tips of the subgenital plate.

Measurements.—Pronotum 4.5 mm, tegmina 3.9 mm, hind
tibiae 9.6 mm.

Acanthacara ortoni sp. nov.

https://zoobank.org/5 DFD1F3D-770C-41 85-9 DEA-AF923FD609A8
Figs 4, 5, 9E, 10E, 16, 17

(‘Gymnacoustes isoharmonicus' — Morris 1987, field name:
Baeza Blackface)

Material examined.—Holotype: ECUADOR e 3; Tungurahua, Pon-
doa; 16 Jul. 1985; G.K. Morris leg.; 85-2; MLP. Paratypes: ECUA-
DOR e 1 3; Tungurahua, Pondoa; 16 Jul. 1985; G.K. Morris leg.;
85-1; ANSP e 1 4; Tungurahua, Pondoa; 16 Jul. 1985; G.K. Morris
leg.; 85-3; ANSP e¢ 1 4; Tungurahua, Pondoa; 16 Jul. 1985; G.K.
Morris leg.; 85-4 [field recorded 1 of 3, 85-1, 85-2, 85-3]; ANSP.

Etymology.—Dedicated to the aforementioned James Orton
(1830-1877), Professor of Natural history at Vassar College in
New York State, naturalist in South America (Orton 1916, Miller
1982). On his first trip there in 1867 he crossed the continent west
to east, starting in Ecuador, securing biological specimens along
the way. Among them were 22 new species of orthopterans, in-
cluding 9 species of katydids (described in Scudder 1869, 3 names
of grasshoppers are now considered synonyms). On the way home
from his third expedition, after a series of mishaps which affected
his health, he unfortunately died during a passage across Lake Titi-
caca at only 47 years old.

Diagnosis.—Similar to the next species. Tegmina slightly longer
than pronotum; dark markings on pronotum indistinct. Last ter-
gite terminally truncate or with broad and shallow emargination
(perhaps shrinkage artifact). Cerci with obtuse dorsal tip; below
that with curved and tapering inward-directed process, ending
with sharp and recurved spine, and above this with small and in-
conspicuous obtuse tip. Styli about twice as long as wide.

Measurements.—Pronotum 4.7 mm, tegmina 5.2 mm, hind
tibiae 8.4 mm.

Acanthacara incisa sp. nov.
https://zoobank.org/5B7E4485-BDD8-4EF1-A73F-86C6939C6954
Figs:3,.9R 10K 18319

(‘Gymnacoustes unizip’ Morris 1987, field name: Banos Blackface)

Material examined.—Holotype: ECUADOR e 4; Tungurahua; 25
Jul. 1985; G.K. Morris leg.; MLP. Paratypes: ECUADOR ¢ 1 3; Tun-
gurahua; 25 Jul. 1985; G.K. Morris leg.; SN-5, 85-5, Rec.; ANSP
e 2 $3; Tungurahua; 26 May 1983; G.K. Morris leg.; ANSP.

Etymology.—Referring to the significant midline emargination
of the posterior margin of abdominal tergite IX. In an excess of
caution, we are careful to avoid a species name relating to song—
e.g., unizip, as given in the ISV poster—for both the preceding
A. ortoni and A. incisa. The two sing in earshot of each other and
solitary vs. doubled zips easily distinguish their songs, but some
confusion in field naming might have led to misapplication of
song to these species.

Diagnosis.—Similar to previous species. Tegmina almost twice
as long as pronotum. Pronotum with blackish spot on prozona

H. BRAUN, G. K. MORRIS

and posteriorly diverging blackish spot on metazona, both spots
connected by more narrow dark coloration in between. Last ter-
gite with deep narrow cleft, wider in distal portion, and the lobes
formed by this division with inward-directed tips sporting tiny
teeth. Cerci with obtuse dorsal tip as in previous species; below
that, with curved inward-directed process; ending also sort of two-
tipped, with the lower tip developed as short spinule. Styli almost
twice as long as wide.

Measurements.—Pronotum 5.0 mm, tegmina 6.3 mm, hind
tibiae 8.4 mm.

Key to species of Acanthacara based on males

1 Cerci more or less uniformly bifurcate, with pointed dorsal branch
and more prominent pointed ventral branch, both branches directed
TASCA cari eallsa ht oracesaisrenswan tetra deve saneesravcdue tem A. acuta Scudder, 1869

- Cerci with obtuse or pointed dorsal tip and differently modified ven-

tal POPHON iri aceern abet Ataarn ating re euteemurtempans tenis Mlegedot ts 2
2 Cerci with more or less pointed dorsal tip and ventral branch ending
in a downward projecting and acuminate tip... eeeeeeeeseeteeeteees =)

- Cerci with obtuse or little developed dorsal tip, ventral process di-
rected medially; if there are downward-projecting processes, they are
clearly set apart from the rest of the ventral branches and much thin-

Memthan thedattete....5 mich cerca Pe Mca. thse TMs t tendo AOR 5
3 Mirror of left tegmen with venation network .........0..ccceceeeeeteeees
usd Msisuel susleas Seuosstateapuchemdvansamectsiaouslgnetenasies A. ridiculosa Gorochovy, 2015
- Mirror of left tegmen without reticulation. .........0c ce cceeeeeeeeeeeees 4

4 Cerci with small pointed inward-directed dorsal tip and long ven-
tral process, which is first directed medially and then turns into a
downward-projecting acute tip, the horizontal portion being longer
thansthe downward tps. .cliutesectsesuvecsloncegumsents A. brachycyma sp. nov.

- Cerci with robust pointed inward-directed dorsal tip, the ventral pro-
cess first directed medially and slightly forward, and then sharply
bent perpendicularly downward, ending in an acute tip; the surface
of the horizontal portion with microscopic sclerotized toothlets and
downward portion longer than horizontal portion in caudal view...
PoP Re I Sea ae PER ae TROP RR eRe A Rah ae A. Zigzag Sp. NOV.

5 Tegmina as long or shorter than pronotum, cerci with broadly
rounded dorsal tip and distinctive ventral branch, consisting of a
sturdy and obtuse medially-directed process with a thin downward-
projecting appendage, the latter originating slightly before the ob-
tusextipporthe Tomer 250s: |e Ree oe els, A. dyonessa sp. nov.

- Tegmina longer than pronotum, dorsal tip of cerci indistinct, ventral
branch directed medially and tapering into two-tipped end, the ven-
tral tip developed as an acute spine (without downward projecting

a tetialyt Lone ak di ahi aahda tras Broa ucilat dara ait an tveh daughter tba heaPla A. ortoni sp. nov.
~ Last tergite with black anterior third and deep medial emargination
rikeeMiederestlenl ss Mebenel ate tube uont toed stun BAnakboes A. incisa sp. nov.

Cestrophorine signal structure

The mechanical basis of forewing stridulation by katydids is
a scraper contacting file teeth to make tegminal speculae oscillate
at ‘multiplied’ frequencies (e.g., Xiphelimum amplipennis Motris,
Braun & Wirkner, 2016). The diverse sound-pulse patterns thus
produced are usefully (for taxonomists) species diagnostic. For
each species, time-domain song structure resolves as a relatively
stereotyped series of discrete sound pulses, manifesting as distinc-
tive spectra in the frequency domain. Simple sinusoid pulses, sus-

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

H. BRAUN, G. K. MORRIS

tained in amplitude over several oscillations, will appear spectrally
as one to a few peaks of stronger central tendency, i.e., higher Q.
More complex transient pulses, grouped in trains, each rapidly de-
caying from a maximal onset, will appear spectrally as a band of
melded peaks tending to a band, i.e., to lower Q. Each transient
pulse in a train is surely the acoustic effect of one file-tooth scraper
interaction, but a more prolonged sinusoid pulse suggests driven
specular oscillators generating at one tooth per wave, coupled or
uncoupled (Montealegre-Z et al. 2006).

The call of C. paradoxus (Fig. 11) repeats as lisps paired in time
(Fig. 11A); each lisp is a train of ~30 very temporally discrete and
transient pulses (Fig. 11B). Each pulse is apparently the result of
a single tooth-scraper event (pluck or impact?). Close inspection
of these complex-wave transients (Fig. 11C) shows them to be re-
markably consistent in wave shape, each giving rise (via Fourier
analysis) to a low-Q spectral band with a species-characteristic
distribution of frequency peaks and subpeaks. (Even tiny spectral
subpeaks can be a stable feature of the singer, only shifting as an
effect of aspect: see Conocephalus nigropleurum Motris & Pipher,
1967.) In C. paradoxus, the lisp analyses as a band of sound energy
between 8 and 13 kHz, entirely within the audio range (Fig. 11D).
This species’ calls are readily heard by human ears and devoid of
effective ultrasonics (Fig. 11D, 12).

The song of C. ditachus (Fig. 13A) is also very audible and, like
that of C. paradoxus, has a time-domain pattern of stereotypic tran-
sients in trains. But it compares to C. paradoxus and to the other
five cestrophorine species songs as higher in duty cycle and unique
in complexity, i.e., there are two rates of transient pulses that pre-
sent as two different pulse trains to comprise a dual-pattern call.
The field-recorded insect of Fig. 13 called steadily from overhead,
perched in a sapling. His song pattern repeats every 2 s or so as 5 to
10 high-rate transient pulse trains interspersed with a single longer
train of markedly slower rate of pulse repetition (Fig. 13B, C). The
two different rates, readily apparent to a human listener, one rate
almost 5 times the other, result in only slight differences in high
resolution pulse waveforms (Fig. 13D, E) and spectral subpeaks
(Fig. 13E G). A dominant frequency peak for both song parts lies
near 7.8 kHz, and there is no sound energy in the high audio 10
-18 kHz. However, ultrasonics are still possible since this record
was made with equipment limited to the audio range.

Each call of C. amplitenuis is a sinusoidal sustained pulse
(Fig. 14A, B), a steady series of identical lisps well-separated by >2
s. The amplitude envelope of this pulse wave-train varies, giving it
a ragged appearance (Fig. 14B). In keeping with a strongly simple
sinuosity, the spectral energy is concentrated in a relatively narrow
high-Q peak at about 11 kHz (Fig. 14D). Ultrasonics in the song
are trivial. The big difference between the songs of C. amplitenuis
and C. paradoxus may be understood as the tooth interaction rate:
in the former species, there is no down time between tooth con-
tacts, so the speculae are sustained in amplitude as an ongoing
sinusoid (Fig. 14C). C. paradoxus, by contrast, engages its scraper
such that each energy transfer has time to completely dissipate
before the next tooth is met. Presumably, the sound-radiating
speculum of C. amplitenuis makes a prolonged-pulse sinusoid by
contacting one tooth for each emitted wave.

The three Cestrophorus spp. call loudly in the audio and lack any
appreciable ultrasonic spectral component. But songs of the three
Acanthacara all have significant ultrasonic spectral components.
A. brachycyma has its most intense output at 30 kHz (Fig. 15D).
This species groups short sinusoidal sustained pulses (Fig. 15B, C)
into brief 4 or 5-pulse trains (Fig. 15A). Calculation from the sine

153

+h

A
1000 ms

B | |

20 ms

mi \ i. ill

10 20 30 40 50 60 70 kHz

Fig. 11. Song of C. paradoxus is an ongoing sequence of lisp pairs.
A. Sequence at low time resolution showing two complete pairs;
B. A lisp at higher resolution reveals its composition as a long
train of >25 discrete rapid-decay pulses; C. Three pulses showing
stereotyped waveform detail; D. Power spectrum of C. paradoxus
with frequencies confined to the audio range in a narrow band
8-13 kHz.

AL
FSS] eS SS
— =

l

|

i
|

—f —— fF —}
i—>

—— se

OO —— —

— ——

——F —j —F

_ EE
a

6) 20 40 80 KHz

Fig. 12. Waterfall record of one C. paradoxus 60-ms pulse train/lisp
indicating absence of ultrasonics.

wave yields (of course) a frequency of just about 30,000 Hz. (In
1 millisecond there are 12/.4 waves; in 1 second 1000 X (12/.4)
= 30,000 waves). As with C. amplitenuis, this might be an instance
of contacting one file tooth per each sinusoid wave to create each
sustained pulse, i.e., tooth touch rate matches carrier frequency.
The call of A. ortoni is heard by a human listener as a se-
quence of double zips produced at a call rate of 2.2/s at 20.8°C
(Fig. 16A). Each double-zip call lasts about 40-50 ms. The first
zip begins as a short pulse train of transient pulses (Fig. 16B) fus-
ing into a sustained high-intensity pulse that time-resolves into
a characteristic two-cusped sinusoid waveform (Fig. 16C) that is

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

H. BRAUN, G. K. MORRIS

ii Midi,
24 6 8 10 12 14 16 18 20 kHz

Mii
2 4 6 8 10 12 14 16 18 20kHz

Fig. 13. Field-recorded song (Sony Walkman, audio range only)
of C. ditachus: trains of pulses characterized by two different pulse
rates, slower (SPR) and faster (FPR). A. Two complete calls taken
from an ongoing sequence. Single SPR train prefaces a 9 FPR-train
sequence; B, D. FPR trains at higher time resolutions showing
waveform of rapid-decay pulses; C, E. SPR train at higher time
resolution showing waveform of rapid-decay pulses; FE, G. Audio-
limited spectra of FPR and SPR respectively; spectra unaffected by
scraper speed, peaking at 6-10 kHz.

A
0.4s
B
__5ms__
G
“ 1. ene leah pad
—__ 0O4ms
D
9)
Acanthacara
-10 brachycyma
-20
-30
dB ull i |

|
10 20 30 40 50 60. 70 80 kHz
Fig. 15. Song of A. brachycyma. A. Two calls from an ongoing se-
quence of paired lisps; each lisp of 5 or so pulses; B. One complete
lisp at higher time resolution; C. High resolution of a single sound
pulse shows it to be highly sinusoidal; D. Spectrum dominated by

ultrasonic peak at 30 kHz.

dominated by harmonics (Fig. 16D). The second zip of Fig. 16B
shows two of these sustained sinusoids, the second of much
longer duration. The carrier fundamental at 12.6-13.2 kHz is
subequal in intensity to its second harmonic at 25.4—26.0 kHz.
The harmonically related frequencies (Fig. 16D) repeat well
into the ultrasonic (13 X 2 = 26, X3 = 39, X4 = 52, X5 = 65,
X6 = 78 kHz).

D 2ms

-40
dB

Mi |
LA Ie l | I

40 50
Fig. 14. ee SFG: taicsale A. Regular well-spaced call series;
B. C. The same call at two levels of time resolution; each emis-
sion a prolonged sinusoid wavetrain of quite variable amplitude
envelope falling-away; D. Audio peak near 11 kHz, spectrum
almost without ultrasonics; the sinusoid-tending call is also ap-
parent in the relatively high peakedness, of the spectrum. Lab
recording at 21.3°C.

IRIN dara aaah
; |

-30
dB |
10

j=}

N

id Mj Whi i IM fl hn! h Mk. ih

Hz

Fig. 16. Song of A. ortoni. A. Four double-zip emissions; B. Higher
resolution of first call of record above; C. Cusped waveform char-
acteristic of the interplay of two nearly equal harmonics; time sam-
ple taken from the prolonged pulse that ends each zip. This wave
feature is the basis of the stillborn name ‘isoharmonicus’ as used by
GKM in his 1987 ISV Poster in Denmark; see Fig. 17 below; D. Spec-
trum shows subequal first (13.5 kHz) and second (27 kHz) har-
monic peaks and then lower intensity harmonic peaks that occur
well into the ultrasonic. A broad peak around 31 kHz is not part
of the harmonic series. The academic editor expressed concern that
the A. ortoni signal shown here may be slightly overloaded; we think
rather that trace C shows the effect of the sampling rate failing to
characterize the wave train smoothly at high time resolution. The re-
cording in Fig. 17 is not subject to any possible overload distortion
and shows the same harmonic interplay giving a cusped waveform.

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

H. BRAUN, G. K. MORRIS

46ms

TORTS Fe Te Tee
TCO COUR it att
MPTP Meee TT hr
eee

155

1.2 2ms

1.6

Stacked spectra and waveform of G. isoharmonicus during a double zip.

Fig. 17. Figure from 1987 ISV meeting abstract booklet showing a different A. ortoni specimen’s song analysis; the waveform shown at
high resolution is characteristic of subequal harmonics. There remains the possibility that this call is not properly associated with A.

ortoni but is the call of A. incisa; see below.

A ns

40 50 60 70

20 80 kHz

Fig. 18. Song of A. incisa. A. Two single-lisp calls, seconds apart,
taken from a sustained sequence; B. At higher time resolution,
each call is seen to be a train of 5-6 pulses of fading intensity;
C. A single pulse at very high resolution reveals its sinusoidal na-
ture; D. The power spectrum suggests higher Q generator compo-
nents with a strongly high-Q peak near 13 kHz and some lesser
but significant ultrasonics of 20-28 kHz.

A waterfall display of the double zip of A. ortoni, together
with its cusped subequal harmonic waveform, is shown for a sec-
ond specimen of A. ortoni (Fig. 17). This latter record formed
part of the Insect Sound and Vibration (ISV) poster given in Den-
mark in 1987. At the ISV meeting, the species was designated as
Gymnacoustes isoharmonicus, now a nomen nudum. The same sort
of patterned time domain is characteristic of the Costa Rican ka-
tydid Copiphora rhinoceros (Morris 1980). The stridulatory basis
of these higher harmonics would seem to involve oscillation of
tegminal speculae with only the fundamental coinciding with
each tooth interaction.

|
|

|
|

|

|
|
|
|
|
|

|
|
|
|
|
|
|
|

HY) We
0 ‘—J

Fig. 19. One call of A. incisa; 7 pulses in a waterfall display.

The call of A. incisa is a train of a half-dozen short sinu-
soid pulses successively falling in intensity, given as a single lisp
every few seconds (Fig. 18A-C, Fig. 19). A single high-Q (nar-
row) spectral peak dominates the audio near 13 kHz. Low-fre-
quency and weak ultrasonics, 20 dB down, exist at 20-25 kHz
(Figs 18D, 19).

The species-distinctive songs of these cestrophorine species
are a typical mix of the familiar frequency domain and time
domain physical features that recur in most tettigoniid genera:
high-Q, broadband, audio, ultrasound, harmonic, inharmonic,
pulses sustained, and pulses transient. But these typical cono-

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)

156

H. BRAUN, G. K. MORRIS

Gorochov AV (2015) Systematics of the American katydids (Orthoptera:

cephalid songs are listened to with unusual conocephalid ears:

foreleg eardrums that are superficial and unoccluded and an
acoustic spiracle (stigma) that is very small. Among conocepha-
loids, a naked ear is apparently unique to Cestrophorini and
contrasts with the diverse tympanal coverings—“slits, resona-
tors, pinnae” (Bailey 1990)—of other conocephaloids. So why
don’t Acanthacara and Cestrophorus have pretympanal pinnae
(sensu lato)?

Beyond mechanical protection, a suggested acoustic func-
tion of these pretympanal structures is as ultrasonic wave guides,
adding precision to the pressure gradient localization of short-
wavelength—ultrasonic—sounds (Bailey 1990, Gwynne 2001).
A publication in train (Montealegre-Z, pers. comm.) reports that
pinnae of the conocephaloid Copiphora gorgonensis are structured
to provide enhanced sound detection at high ultrasonic frequen-
cies (>60 kHz), matching the echolocation range of co-occurring
insectivorous bats. Perhaps the absence of tympanal coverings of
Cestrophorini reflects much reduced bat predation for these small
montane species.

It remains puzzling why the unoccluded tympana are com-
bined with such small auditory spiracles. A narrow ear canal re-
duces sound velocity and, along with its asymmetric bifurcation
near the individual tympana, creates different sound paths for
each ear, all of which could help to pinpoint the direction of
the sound (Veitch et al. 2021). Interestingly, the same rare com-
bination of naked tympana and tiny spiracles is found in two
species of Hexacentrinae (genus Nubimystrix), known also exclu-
sively from the Andes of Ecuador and living in similar habitat
(Braun 2016).

Acknowledgements

The authors thank Dita Klimas for her photography,
translation, and for confronting the Extranjeria bureaucrat in her
cage. Others to whom we are indebted are Roberta Fulthorpe,
James Fullard, George Glenn, Andrew Mason, Piotr Naskrecki,
Fernando Montealegre-Z, Giovanni Onore, Dan Otte, and Peter
Wall. We acknowledge the constructive criticism of two referees.

References

Bailey WJ (1990) The ear of the bushcricket. In: Bailey WJ, Rentz DCF
(Eds) The Tettigoniidae: Biology, Systematics and Evolution. Craw-
ford House Press, Bathurst, 217-247. https://doi.org/10.1007/978-3-
662-02592-5_12

Braun H (2016) Two mysterious tiny katydids from the Ecuadorian Andes
(Orthoptera: Tettigoniidae: Hexacentrinae). Journal of Orthoptera
Research 25(2): 97-106. https://doi.org/10.1665/034.025.0209

Cigliano MM, Braun H, Eades DC, Otte D (2022) Orthoptera Species File
Online Version 5.0/5.0. http://Orthoptera.SpeciesFile.org [accessed
on 30/03/2022]

Tettigoniidae). Communication 5. Proceedings of the Zoological
Institute of the Russian Academy of Sciences 319(4): 480-503.
https://doi.org/10.31610/trudyzin/2018.322.4.398

Gumey AB (1972) The South American katydid genus Acanthacara:
descriptive notes and subfamily position (Orthoptera: Tettigoniidae,
Agraeciinae). Journal of Washington Academy of Science 62: 32-35.

Gwynne DT (2001) Katydids and Bush-crickets, Reproductive Behavior
and Evolution of the Tettigoniidae. Comstock Publishing, Cornell
University Press, Ithaca, 317 pp.

Jonsson T, Chivers B, Robson Brown KA, Sarria-S FA, Walker M,
Montealegre-Z F (2017) Chamber music - an unusual Helmholtz
resonator for song amplification in a Neotropical bush-cricket
(Orthoptera, Tettigoniidae). Journal of Experimental Biology 220:
2900-2907. https://doi.org/10.1242/jeb.160234

Karny HH (1912) Orthoptera, Fam. Locustidae Subfam. Agraeciinae.
Genera Insectorum 141: 1-47.

Miller RR (1982) James Orton: a yankee naturalist in South America, 1867-
1877. Proceedings of the American Philosophical Society 126: 11-25.

Montealegre-Z FE Morris GK, Mason AC (2006) Generation of extreme
ultrasonics in rainforest katydids. Journal of Experimental Biology
209: 4923-4937 https://doi.org/10.1242/jeb.02608

Morris GK, Pipher RE (1967) Tegminal amplifiers and spectrum
consistencies in Conocephalus nigropleurum (Bruner), Tettigoniidae.
Journal of Insect Physiology 13: 1075-1085. https://doi.
org/10.1016/0022-1910(67)90109-6

Morris GK (1980) Calling display and mating behaviour of Copiphora
rhinoceros Pictet (Orthoptera: Tettigoniidae. Animal Behaviour 28:
42-51. https://doi.org/10.1016/S0003-3472(80)80006-6

Morris GK (1987) Acoustic morphology in a new katydid genus from the
Ecuadorean Andes (Orthoptera: Tettigoniidae: Conocephalinae).
Poster Abstract. VI International Meeting on Insect Sound and
Vibration at Odense, Denmark.

Morris GK, Mason AC (1995) Covert stridulation: novel sound generation
by a South American katydid. Naturwissenschaften 82: 96-98.
https://doi.org/10.1007/BF01140151

Morris GK, Braun H, Wirkner CS (2016) Stridulation of the clear-wing
meadow katydid Xiphelimum amplipennis, adaptive bandwidth.
Bioacoustics 25: 225-251. https://doi.org/10.1080/09524622.2016.1
138883

Orton J (1870) The Andes and the Amazon or, Across the Continent of
South America. Harper & Brothers, New York, 200 pp. https://doi.
org/10.5962/bhl.title.30246

Orton SR (1916) A sketch of James Orton. Vassar Quarterly 1: 1-8.

Redtenbacher J (1891) Monographie der Conocephaliden. Verhandlungen
der Kaiserlich-Koniglichen Zoologisch-Botanischen Gesellschaft in
Wien 41: 315-562.

Scudder SH (1869) Notes on Orthoptera collected by Prof. James Orton
on either side of the Andes of Equatorial South America. Proceedings
of the Boston Society of Natural History 12: 330-345.

Veitch D, Celiker E, Aldridge S, Pulver C, Soulsbury CD, Jonsson T,
Woodrow C, Montealegre-Z F (2021) A narrow ear canal reduces
sound velocity to create additional acoustic inputs in a microscale
insect ear. Proceedings of the National Academy of Sciences
118(10): e2017281118. https://doi.org/10.1073/pnas.2017281118

JOURNAL OF ORTHOPTERA RESEARCH 2022, 31(2)