Zoosyst. Evol. 100 (3) 2024, 1085-1097 | DOI 10.3897/zse.100.121396

> PENSUFT.

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BERLIN

Re-description of Xyliphius barbatus (Siluriformes, Aspredinidae),
with comments on osteology and distribution

Guillermo E. Teran**, Alejandro Méndez-Lopez"", Mauricio F. Benitez*, Wilson S. Serra>*,

Sergio Bogan°, Gastén Aguilera?

1 Fundacion Miguel Lillo — Unidad Ejecutora Lillo FML-UEL-CONICET, (4000), Miguel Lillo 251, San Miguel de Tucuman PC 4000, Tucuman,

Argentina

oa F W PP

https://zoobank. org/64E8 D409-0377-4629-90DC-946A2CB4BE61

Corresponding author: Gaston Aguilera (gaguilera@lillo.org.ar)

Instituto de Biologia Subtropical (UNaM-CONICET), Félix de Azara 1552, Posadas, Misiones, Argentina

Seccion Ictiologia, Departamento de Zoologia, Museo Nacional de Historia Natural, Montevideo, Uruguay

Centro Universitario Regional del Este (CURE) Sede Rocha, Rocha, Uruguay

Division Ictiologia, Museo Argentino de Ciencias Naturales “Bernardino Rivadavia”’, Av. Angel Gallardo 470, C1405DJR, Buenos Aires, Argentina

Academic editor: Nicolas Hubert # Received 22 February 2024 Accepted 15 July 2024 @ Published 1 August 2024

Abstract

The banjo catfish, Xyliphius barbatus, belongs to the Aspredinidae family and typically inhabits the main channels of medium to
large rivers in the La Plata River basin. The mimetic coloration with the substrate and the benthic lifestyle likely contribute to the
challenge of sampling this species, resulting in its underrepresentation in museums and ichthyological collections. In fact, the orig-
inal description of X. barbatus was based solely on two specimens. Consequently, little is known about its osteology, distribution,
and phylogenetic relations. In this work, these information gaps are filled and the distributional range for X. barbatus is extended

to northwestern Argentina.

Key Words

Banjo catfish, fossorial fishes, La Plata River basin, morphology, osteology

Introduction

The family Aspredinidae is composed of 13 genera and
A9 valid species (Fricke et al. 2023a), among which the
genus Xyliphius Eigenmann, 1912, include seven spe-
cies (Fricke et al. 2023b). According to Friel (1994) the
genus is distinguishable from all other aspredinids by
the following combination of characters: eyes highly
reduced, premaxillary toothless and displaced lateral to
mesethmoid, a row of fleshy papillae on lower lip, unculi
and unculiferous tubercles flattened, lamina of pterotic

* These authors contributed equality.

rounded, and lateral end of posterohyal expanded. Mem-
bers of this genus are distributed in different basins in
South America: X. sofiae Sabaj Pérez, Carvalho & Reis,
2017 in the Amazon River basin in Peru, X. melanopterus
Orcés, 1962 and X. /epturus Orcés, 1962 in the upper
Amazon and Orinoco River basins, _X. kryptos Taphorn &
Lilyestrom, 1983 in the Maracaibo basin, X. anachoretes
Figueiredo & Britto, 2010 in the Tocantins River basin,
X. magdalenae Eigenmann, 1912 in the Magdalena River
basin, and_X. barbatus Alonso de Aramburu & Aramburu,
1962 from La Plata River basin.

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

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Except for Xyliphius lepturus, all the species of the
genus were described based on one to three specimens
(X. lombarderoi, X. melanopterus, X. magdalenae and
X. sofiae based on a single specimen; X. barbatus and
X. anachoretes on two specimens; and X. kryptos on
three specimens). These fishes are rare in inventories
of fish fauna and consequently in museum collections.
This sparse representation is due to several factors,
including their mimetic coloration with the substrate,
their benthic lifestyle, the infaunal habits of many
species, and, most importantly, their specific habitat
preferences. Indeed, these species live in the main
channels of medium to large rivers, where sampling
is difficult (Carvalho et al. 2017). Xvliphius barbatus,
originally described from the Parana River in Rosario
(Alonso de Aramburu and Aramburu 1962), has a few
records along the La Plata River basin: Parana River in
Misiones, Santa Fe (Garcia 1992; Calvifio and Castello
2008) and Chaco provinces (type locality of Xyliphius
lombarderoi Risso & Risso, 1964, a synonym of Xy-
liphius barbatus) (Risso and de Risso, 1964); in the
Uruguay River in Uruguay (Loureiro et al. 2013) and,
more recently, in the Paraguay River basin, Pantanal,
Brazil (Giménes Junior and Rech 2022).

In Argentina, other aspedinids have been recorded: Am-
aralia oviraptor Friel & Carvalho, 2016, Bunocephalus
doriae Boulenger, 1902, Pseudobunocephalus iheringii
(Boulenger, 1891), Pseudobunocephalus rugosus (Eigen-
mann & Kennedy, 1903), and Pterobunocephalus depres-
sus (Haseman, 1911). Although the upper section of the
Bermejo River basin has many endemisms (e.g., Mirande
et al. 2004a, b, 2006; Casciotta and Almiron 2004; Teran
et al. 2016a, 2019; Alonso et al. 2018; Aguilera et al.
2019), it shares elements with the Paraguay-Parana Riv-
er basin (Alonso et al. 2016; Teran et al. 2016b, 201 6c;
Vanegas-Rios et al. 2019), and the Amazon River basins
(Littmann et al. 2015; Aguilera et al. 2022). The only re-
cord of aspredinids in this area is Bunocephalus doriae
Aguilera et al. (2016).

New inventories made in the Bermejo River basin
have revealed the presence of Xv/iphius barbatus, a spe-
cies not previously recorded for the area. This record 1s
the largest known batch regarding the species. The aim of
this contribution, is to provide an accurate re-description
of X. barbatus.

Materials and methods

Specimens were collected by electrofishing and hand
nets, euthanized by immersion in tricaine methanesulfon-
ate (MS222), fixed in 10% formalin solution, and trans-
ferred to individual batches in a 70% alcohol solution.
The material was deposited in ichthyological collections.
In some fresh individuals, a small tissue sample was tak-
en and immediately preserved in absolute ethanol for ge-
netic analysis. The tissue aliquots were deposited in the

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Teran, G.E. et al.: Re-description of Xyliphius barbatus

tissue collection of CIT-FML. The study complied with
the animal welfare laws, guidelines, and policies of the
Comité Nacional de Etica en la Ciencia y Tecnologia, Ar-
gentina. Collection permits were granted by the Ministe-
rio de Ambiente of Jujuy. (permits’ numbers: 1103-306-
M/2016, Res. N° 137/2016-MA).

Point to point measurements were taken with a digital
caliper to the nearest 0.1 mm and expressed as percent-
age of the standard length (SL), except for subunits of
head, expressed as percent of the head length (HL) (see
Table 1). Measurements follow Friel (1995) and Cardo-
so (2010), with the modifications proposed by Carvalho
et al. (2017). Nomenclature of anatomical structures fol-
lows that used by the three mentioned authors and Dahdul
et al. (2010), included in the Teleost Anatomy Ontolo-
gy of Uberon Ontology Documentation (Mungall et al.
2012, http://obophenotype. github.10/uberon/). Specimens
were cleared and stained (C&S) following Taylor and Van
Dyke (1985). An asterisk (*) indicates holotype counts.
Vertebral counts included the Weberian Complex (5 ver-
tebrae) plus all free vertebrae and the compound caudal
centrum (PU1 +U1) counted as one element.

Total genomic DNA was extracted from ethanol-pre-
served muscle tissue of specimen CI-FML 7944 (tissue
collection number: CIT-FML 00169), using a salt-based
protocol (Aljanabi and Martinez 1997). A 651pb frag-
ment of mitochondrial gene Cytochrome oxidase subunit
I (COI) was amplified by Polymerase Chain Reaction
(PCR) using the cocktail primers proposed by Ivanova
et al. (2007). The PCR protocol was the implemented
by Ward et al. (2005). PCR-amplified product was pu-
rified with 20% PEG . The product was sequenced with
automated sequencer (Macrogen, Korea) in both direc-
tions to check for potential errors. The Chromatogram
was processed and edited using Geneious (Technelysi-
um Pty Ltd) and deposited in GenBank under the ac-
cession number OQ539436. COI sequences of different
Xyliphius species from GenBank (http://www.ncbi.nim.
nih.gov/Genbank) were used to assess the relationships
between X. barbatus and the remaining species of the
genus, providing a preliminary phylogenetic hypothe-
sis. GeneBank codes and references for the employed
sequences are shown in Table 2. Pairwise genetic dis-
tances with K2P model and UPGMA analysis were per-
formed for 651 -pb fragments using MEGA11 (Tamura
et al. 2021). The Maximum likelihood tree was estimat-
ed employing RAXxML (Randomized Axelerated Maxi-
mum Likelihood) under GTR+FO+G4m model and 100
bootstrap replicates.

Collection’s acronyms: MACN-Ict Museo Argen-
tino de Ciencias Naturales, Buenos Aires, Argentina,
MG-ZV-P Museo Provincial de Ciencias Naturales “Dr.
Angel Gallardo”, Rosario, Argentina, MLP-Ict Museo
de la Plata, La Plata, Argentina, CFA-IC Fundacion de
Historia Natural Félix de Azara, Buenos Aires, Argen-
tina, CI-FML Fundacion Miguel Lillo, San Miguel de
Tucuman, Argentina.

Zoosyst. Evol. 100 (3) 2024, 1085-1097

Table 1. Morphometric data of Xyliphius barbatus. SD= standard deviation. Holotype (MLP 6798), Paratype (MLP 2799), Parana

River (MACN-Ict 6791. 5 ex.) Bermejo River specimens (CI-FML7944 and CFA-IC-12742 34 ex.).

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Holotype Paratype Bermejo River (N= 20) Parana River (N= 5)
mean range SD mean range SD
Standard length 90.3 87.2 91.3 79.6-111.3 83 66.2 44.6 - 93.6 1726
Percentage of SL
Body depth at dorsal — fin origin 15.9 14.1 14.9 12.3 - 16.9 l¥Z 72 15.6 - 19.9 LF
predorsal length 42.6 40.4 40.4 38.3 - 45.2 1A. @ Any? 40.0 - 43.0 Let
prepectoral length 26.6 25.6 25.8 23.6 - 28.4 1.1 DT? 25.8 — 28.9 TZ
prepelvic length 47.3 45.8 44.0 41.0-49.1 17 459 43.2-51.8 che!
preanal length 63.9 652 60.3 58.2 - 64.1 14 60.9 58.0 - 63.9 2.4
caudal peduncle length 26.2 so WY 27.7 25.0 - 31.1 158" "2626 24.4 - 29.6 2.0
caudal peduncle depth 7.3 8.1 7.4 6.8 -8.1 0.3 8.2 8.0 - 8.6 0.2
pelvic fin length 14.9 12.6 14.1 12.6 - 15.2 0.8 15.5 13.3 - 16.6 3
anal — fin base 1333 DIAG 14.3 12.7 - 16.6 1 1352 11.6-15.5 LS
caudal-fin length 2333 12 20.3 18.1 - 22.2 12 20-8 17.1-22:2 1.9
pectoral spine length 16.8 16.6 15.5 13.8-17.2 0.9 iz 15.0-19.5 2.0
humeral process length 10.6 Pit 9.8 8.2-12.4 1.1 8.0 5.5-11.6 2.2
posterior process of coracoid length 10.4 9.5 9.8 8.3-11.1 0.8 10.5 9.6-11.7 0.9
head length 28 28.5 28.2 26.0 - 31.0 14 34.9 33.4 - 35.4 0.8
width at pectoral — fin insertion 27.5 ZT 7 24.7 23.3 - 27.4 0.9 27.4 26.8 - 28.2 0.6
Percentage of HL
maximum head depth 51.4 55 46.9 42.2-51.8 Ade Wai, 24. 36.9 - 44.5 3.1
snout length 35.4 25.9 33.0 29.7 - 39.9 2A 25u. 21.8 - 29.2 2.8
eye diameter 3a 3t5 335 2.3-5.8 0.9 4.0 3.0-5.4 Ho)
interorbital width 30.1 24.9 30.6 27.3 - 35.8 22° 2217 19.7 - 23.8 1.8
maxillary barbel 95.2 94.9 86.9 71.6- 105.1 7.7 68.0 60.7 - 76.8 5.9
anterior to posterior nares distance lik? 8.4 10.7 7.6 - 16.5 21 LES 7.3 - 14.3 3:4
posterior nare to orbit 7.2 5.4 igs) 5.8 -9.9 1.0 4.8 4.1-6.4 0.9
anterior internareal distance 20.7 13.8 16.6 13.8 - 22.1 19 15:0 14.0 - 15.9 0.7
posterior internareal distance aoe, Pout 28.8 26.2 - 31 1.6 Zoty 22.8 — 30.2 37
Table 2. List of sequences, with accessions and vouchers employed for molecular analysis.
Species GenBank ID Catalog Basin

Xyliphius barbatus 0Q539436 CI-FML 7944 Bermejo River. Argentina
Xyliphius barbatus KU288948 MG ZV-P 355 Parana River. Argentina
Xyliphius lepturus MF489386 AUM46757 Amazon River, Peru
Xyliphius magdalenae MF489382 ANSP192845 Magdalena River, Colombia
Xyliphius melanopterus MF489383 MUSM36715_AP12 Amazon River, Peru
Xyliphius melanopterus MF489384 MUSM36715_AP28 Amazon River, Peru
Xyliphius melanopterus MF489385 STRIO1784 Amazon River, Peru
Xyliphius sofiae KU736764 ANSP 182322 Amazon River, Peru

Results

Xyliphius barbatus Alonso de Aramburu &
Aramburu, 1962
Figs 1-6

Material examined. All from Argentina: MLP 6798.
Holotype. 90.3 mm SL. Parana River at Rosario, Santa Fe
province. Col. C. Vidal. MLP 2799. Paratype. 87.2 mm
SL. Parana River at Rosario, Santa Fe province. Col. R.
Ringuelet. MACN 6791. 5 ex, 44.6—93.6 mm SL. Parana
River near Curtiembre, border between Santa Fe and En-
tre Rios provinces. 31°27'18.34"S, 60°10'11.95"W. 35—
45 m depth 1961-1962 Col. N. Bellisio. MG-ZV-P 355
(LAR-254). 1 ex, 99.1 mm SL. Parana River in front of

Rosario, Entre Rios province, Argentina. 32°55'58.8"S,
60°37'58.8" W. 6 m depth. 04/03/2013 Col. Julian Aguilar.
CI-FML 7944, 29 ex (3 C&S), 79.6—111.3 mm SL. CFA-
IC-12742, 5 ex. 79,7—99,2 mm SL. San Francisco Riv-
er, Bermejo River basin, Jujuy province; 23°50'27.08"S,
64°37'24.70"W, ca. 370 m asl. 1-2 m depth. 30 Sep 2016.
G.E. Teran, G. Aguilera and D. Delgado.

Diagnosis. Xv/iphius barbatus is distinguishable from
the remaining species of genus by the following com-
bination of characters: (1) seven to 11 retrorse denta-
tions on posterior margin of pectoral-fin spine (vs. six in
X. anachoretes and four or five in X. magdalenae); (2)
24 to 30 dendriform papillae on inferior lip (vs. 20-22
in X. magdalenae, 30 in X. sofiae, and 22 to 27 trian-
gular papillae, with only the lateral ones branched in

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Teran, G.E. et al.: Re-description of Xyliphius barbatus

Figure 1. A, B. Holotype MLP 6798 of Xyliphius barbatus. 90.3 mm SL. C-D Paratype MLP 2799. 87.2 mm SL. Parana River at

Rosario, Santa Fe province, Argentina. Scale bar: 10 mm.

X. kryptos), (3) 1,3 or L4 dorsal-fin rays (vs. 1,5 in_X. lep-
turus and X. melanopterus); (4) absence of dorsal pale
band from snout tip to caudal-fin origin (vs. presence in
X. anachoretes, X. magdalenae and X. melanopterus),
(5) absence of a latero-dorsal band following the second
row of tubercles on anterior part of body (vs. present in
X. magdalenae and X. melanopterus), (6) eyes present
and reduced (vs. absent in X. sofiae); (7) five to eight anal-
fin rays (vs. nine in_X. /epturus).

The additional characters that distinguish Xv/iphius
barbatus from the remaining species of the genus are:
papillae dendriform on lower lip with large branches (vs.
papillae with minute branches on_X. anachoretes); three
dorsal procurrent rays (vs. two in X. anachoretes, four
to five in X. /epturus, and four in X. magdalenae), pel-
vic fin not reaching anal-fin origin (vs. just reaching in
X. magdalenae), maxillary barbel surpassing pectoral-fin
spine insertion (vs. not quite reaching pectoral in_X. mag-
dalenae), four branchiostegal rays (vs. five in_X. sofiae),
and two ossified proximal radials on pectoral fin (vs. one
in X. sofiae).

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Morphological description. Morphometric data is
summarized in Table 1. Head and anterior part of body
depressed, compressed from dorsal-fin origin to cau-
dal-fin insertion. Maximum depth at dorsal-fin origin.
Dorsal profile straight from snout tip to dorsal-fin origin,
relatively depressed along dorsal-fin base, and relatively
straight from this point to caudal-fin origin. Ventral pro-
file of body, straight from lower-jaw to pectoral-fin origin,
convex to pelvic-fin origin with the lowest point at the
origin of the pelvic bone, then slanted dorsally to anal-fin
origin and relatively straight form this point to caudal-fin
base. Greatest width just anterior to pectoral-fin origin.

Head triangular with a rounded snout. Eyes reduced
(Fig. 3), located closer to snout tip than to supraoccipi-
tal protuberance, and covered with skin less pigmented
than surroundings areas. Two nares, anterior nostril tu-
bular, posterior one smaller and located closer to eyes
than to anterior nostril. Maxillary barbel on side of snout,
inserted just above rictus. Maxillary barbel reaching pec-
toral-fin base. Two pairs of mental barbels smaller than
maxillary ones and located close to the mouth gape.

Zoosyst. Evol. 100 (3) 2024, 1085-1097

1089

Figure 2. Lateral, dorsal and ventral views of Xyliphius barbatus. CI-FML 7944. San Francisco River, Bermejo River basin, Jujuy

province. Scale bar: 10 mm.

The external one just before the vertical line through eye,
reaching mouth gape when adpressed; inner mental bar-
bels smaller, reaching outer barbels origin, surpassing the
lower lip and reaching end of papillae when adpressed.
Mouth subterminal, much wider than snout, with 20
to 30 dendritic papillae. Anterior margin of snout with
a groove at middle line in dorsal view. Gill slits small,
located ventrally on head, before pectoral-fin origin; gill
membranes united to isthmus. Small genital papillae just
posterior to anus.

Head, trunk, and fins are all covered by thick skin,
while the skin in the ventral area and at the fin insertions
is thinner. Trunk covered by unculiferus tubercles, which
are more concentrated in the head. Five lateral rows of
large tubercles extending from post-cephalic region to
caudal-fin base, and concentrated in mid-dorsal line.

Dorsal-fin I,2,1 (1) or 13,1 (33*), spine feeble. Dor-
sal-fin insertion on anterior half of body, closer to snout
tip than to caudal-fin insertion, anterior to pelvic-fin
insertion; shape triangular, rays elongated beyond the
membrane. Anal fin 1,3,1(1), 11,3,1(6), 11-3,1(7), 11-4,1(16* ),

111-4,1(1), 11-5,1(3), ovoid, first branched anal-fin ray lon-
gest. Anal-fin insertion on the posterior half of body, clos-
er to caudal-fin insertion than to snout tip. Pectoral-fin
1,4,1 (34*), its origin almost at half way between snout
tip and dorsal-fin origin, and its distal tip reaching pel-
vic-fin origin. Distal tips of branched rays elongated be-
yond membrane. Pectoral spines thick, with seven to 11
developed retrorse serrae along posterior margin; spine
capped by a fleshy elongation. Pelvic fin 1,3,1 (1) or 14,1
(33*), origin just posterior to vertical through dorsal-fin
origin. The tip of pelvic-fin rays elongated throughout
the membrane. Caudal fin 1,4/4,1 (34*), The ventral-most
three branched caudal-fin rays longer.

Osteology (Figs 4-6).

Mesethmoid deep, slightly longer (anteroposteriorly)
than wide, with an anterior notch separating two anterior
wings. Premaxillae articulating on a ventrolateral con-
cavity of mesethmoid, not visible in dorsal view due to
a dorsal lamina. Two diverging laminae articulating dor-
sally with frontals by interdigitations. Lateral ethmoids
articulate with frontals through a dorsal interdigitated

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Figure 3. Head detail of Xyliphius barbatus. CI-FML 7944. San
Francisco River, Bermejo River basin, Jujuy province. Scale
bar: 5 mm.

process and medially with orbitosphenoid by cartilage;
the latter covered ventrally by a laminar extension of the
same bone articulating with parasphenoid; projecting lat-
eral process joined to autopalatine at its middle length;
ventrally flattened and extensively articulating with
parasphenoid posteromedially. Frontals about 3.5 times
longer than wide, their posterior wing articulating with
supraoccipital, and lateral posterior margins enclosed
by anterior extension of sphenotic. Anterior fontanel
about 1.4 times larger than posterior one, synchondral
articulation between lateral ethmoids and mesethmoid
completely visible through fontanel. Supraoccipital en-
closing almost half of posterior fontanel. Epiphyseal bar
with a strong suture, its length equal to or greater than
that of posterior fontanel. Supraoccipital a little longer
than wide, extensively articulating with pterotic laterally,
and with epioccipital posterolaterally; a notch in posteri-
or region receiving the ascending process of posttempo-
ral-supracleithrum; posterior process wide and short, in
contact with dorsal portion of complex vertebrae. Sphe-
notic pitted; ventral surface with greater pores, sutured
to pterotic laterally, leaving a posterior space with same
bone in ventral view, with extensive anterior synchon-
dral articulation with hyomandibula, sutured medially to
parasphenoid and posteriorly to anterior lamina of proot-
ic. Dorsal prootic covering lateral surface of frontals and
with posterior articulation with supraoccipital. Pterotic
with anterior lamina sutured to sphenotic, a concavi-
ty after its contact with suprapreopercle, and a lateral
rounded expansion reaching opercle ventrally; contact-
ing posttemporal-supracleithrum lateral arm at its poste-
riormost region. Epioccipital articulating anterolaterally
with pterotic, medially with supraoccipital and dorsally
with posttemporal-supracleithrum. The latter bone with
dorsal process reaching lateral surface of supraoccipi-
tal over epioccipital; a ventral pointed process contact-
ing posterior expansion of pterotic and posterior arm of
the bone sutured to complex vertebra. Wider portion of
parasphenoid at its articulation with sphenotic, extended
to middle bassioccipital at its posterior end. Prootic vis-
ible only in ventral view, anterior lamina over sphenotic
cartilage, extensively contacting parasphenoid medially,

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Teran, G.E. et al.: Re-description of Xyliphius barbatus

pmx mes den

Figure 4. Skull of Xvliphius barbatus CI-FML 7944. A. Ventral
view; B. Dorsal view. ach: anterior ceratohyal; ang: anguloar-
ticular; anp: anterior nuchal plate; br: branchiostegal rays; cl:
cleithrum; co: scapulocoracoid; den: dentary; dfr: dorsal fin rays;
epo: epioccipital; ex: extrascapular; fro: frontal; gch: gas bladder
chamber; hyo: hyomandibula; 101: infraorbital 1; iop: interoper-
cle; 1ot: infraorbital tubules; lal: lateral line tubules; let: lateral
ethmoid; mc: mandibular canal tubules; mes: mesethmoid; max:
maxilla; na: nasal; op: opercle; pal: autopalatine; pch: posterior
ceratohyal; pfr: pectoral-fin rays; pmx: premaxilla; pnp: pos-
terior nuchal plate; po: preopercle; ps:pectoral-fin spine; pto:
pterotic; pv5: parapophysis of vertebra five; qua: quadrate; rad:
pectoral-fin radial; rb1: first rib; soc: supraoccipital; sc: post-
temporal-supracleithrum; spo: sphenotic; sup: suprapreopercle;
uh:urohyal; vh: ventral hypohyal. Scale bar: 1 mm.

and sutured to pterotic posterolaterally, leaving to an an-
terior space with the same bone. Exoccipital bearing two
projections enclosing posterior parasphenoid, strongly
sutured to posteromedial edge of prootic, to exoccipital
laterally and with complex vertebra by interdigitations.
Basioccipital sub triangular, with a large foramen on its
posterior half, a conspicuous pore anteromedially and
additional ones laterally.

Zoosyst. Evol. 100 (3) 2024, 1085-1097

Figure 5. Dorsal view of the neurocranium of Xyliphius bar-
batus CI-FML 7944. mes: mesethmoid; 101: infraorbital 1; na:
nasal; max: maxilla; fro: frontal; spo: sphenotic; soc: supraoc-
cipital; pto: pterotic; epo: epioccipital; sc: supracleithrum; cv:
weber camara; gch: gas bladder chamber; pv5: parapophysis of
vertebra five. Pores of the cephalic sensory lateral system s1 to
s6 represent the pores from the supraorbital canal and i1 to 16
from the infraorbital canal. Scale bar: 2 mm.

1091

Premaxillaries dorsomedially flattened and oval, in con-
tact with ventrolateral notches of mesethmoid and separat-
ed by the latter. Premaxillary teeth absent. Maxillary tubu-
lar, with furrowlike opening on ventral surface; 1ts condyle
attached to anterior palatine cartilage. Dentary long and
slender, laminar posterior region overlapping anterior face
of angular; teeth conical and pointed inwards, arranged in
two rows, the outer one with 3 to 5 teeth near the symphy-
sis, and the inner row with 11—12 teeth; coronomeckelian
absent. Meckel’s cartilage somewhat conical, wider later-
ally from its origin at angular, and slender medially at its
joining with the dentary, which is located ventral to (or a
little displaced medially) dentary dorsolateral notch.

Hyomandibula in dorsoventrally oblique position with
respect to neurocranium; dorsalmost edge under anterior
extension of sphenotic, followed by a synchondral artic-
ulation with the same bone; anterior cartilage contacting
quadrate and extended to lateral portion of metapterygoid.
Preopercle on lateral portion of hyomandibula, sutured to
quadrate on its synchondral articulation with the same bone.
Quadrate condyle anteroventrally oriented, to anguloartic-
ular. Metapterygoid square, a little larger than endoptery-
goid, with a posterior concavity for the anterior lamina of
hyomandibula. Endopterygoid ventral to posterior third of
autopalatines, at posteroventral concavity of lateral eth-
moids after its projecting lateral process, bearing a lateral
pointed projection reaching autopalatine middle cartilage.

Autopalatines with expanded anterior and posterior
edges, its narrower portion anterior to lateral ethmoids
cartilage. Opercle medially articulated with lateral arm of
hyomandibula, anteriorly expanded and sutured with in-
teropercle; posterior pointed projection reaching ventral
expansion of pterotic. Interopercle accompanying ven-
tralmost edge of opercle, its anterior pointed projection
over posterior ceratohyal, covering the interhyal articula-
tion from lateral view.

Figure 6. Anal, caudal and pelvic fins of Xyliphius barbatus CI-FML 7944. A. Anal-fin and pterygiophores; B. Caudal complex and
fin; C. basipterygium. afr: anal-fin rays; apt: anal-fin pterygiophores; cfr: caudal-fin rays; dlw: dorsolateral wing of basipterygium;
dpr: dorsal procurrent rays; nsp: neural spines of vertebrae 15 to 18; pcb: posterior cartilage of basipterygium; pfr: pelvic-fin rays;

vpr: ventral procurrent rays. Scale bar: 1 mm.

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Urohyal subtriangular, with a medial longitudinal cleft
on anterior corner and posterolateral developed wings.
Two basibranchials, the anterior one about twice larg-
er, contacting first hypobranchial anteriorly and second
hypobranchial cartilage posterolaterally; posterior one
reached by third hypobranchial. Only the first hypobran-
chial ossified with wider distal portion. Hypohyals squar-
ish, narrow in its proximal region, and articulated to cer-
atohyal synchondrally. Ceratohyals with posteroventrally
expanded lamina at the articulation with banchiostegal
rays; dorsal and ventral extensions over cartilage with
posterior ceratohyal sutured to anterior extensions of
same bone. Posterior ceratohyal rectangular, with a notch
anterior to posterodorsal corner at the articulation with in-
terhyal. Branchiostegal rays four, lateral ones thicker and
with more developed lamina, first one (medial) between
posterior urohyal and lateral to corner of ceratohyal ex-
panded lamina, the remaining ones associated with ante-
rior ceratohyal cartilage, lateral-most at the articulation
cartilage of ceratohyals. Interhyal present, articulated to
posterodorsal ceratohyal, with lateral portion of hyoman-
dibular and quadrate.

Ceratobranchials five, first two and last one (fifth) with
a single series of small gill rakers, third and fourth with
two series; fifth ceratobranchial bearing a dorsal drop-
shaped plate with conical teeth, posterior portion long
and slender, with four or five gill rakers. Five gill rakers
on the anterior border of first and second ceratobranchi-
als, one in the cartilage with first epibranchial; only epi-
branchials one to three with gill rakers, first with single
row and the remaining two with double row of one or two
gill rakers restricted to proximal portion. Epibranchials
four, an uncinated process on the third one. Third pharyn-
gobranchial thicker at its articulation with cartilage of
third epibranchial; fourth pharyngobranchial about half
of the latter and located dorsal to an oval tooth plate.

Nasal separated in two tubular ossifications by supra-
orbital sensory pore s2, posterior tubular ossifications of
the supraorbital canal enters frontal just lateral to its artic-
ulation with mesethmoid posterior projection. Antorbital
present, small, its canal piercing base of dorsal projection
of infraorbital 1 and exiting posteriorly. First infraorbital
over anterior cartilage of autopalatine, with notch border-
ing maxillary condyle; anteromedial projection pointed
and curved, limiting the anterolateral portion of nares.
Posterior infraorbitals as a small series of ossicles enter-
ing sphenotic canal laterally; ventral branches of 15 and
16 ossified.

Supraorbital sensory canal with pores sl-s2 and s2-
s3 separating nasal in two tubular ossifications. Pore S4
opening at anterior frontal fontanel, s5 is missing and s6
opening at posterior frontal fontanel. Infraorbital sensory
canal composed of six pores, the first and second ones
opening at inner margin of infraorbital 1, and the third at
outer margin. Pores 14 to 16 arranged in an arch reaching
up close to anterior half of sphenotic.

Tubular series of preopercle mandibular canal initiat-
ing below posterior portion of dentary and separated by

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Teran, G.E. et al.: Re-description of Xyliphius barbatus

those joined to preopercle by a gap just lateral to quadrate
condyle. Suprapreopercle as a small tubular canal be-
tween hyomandibula and pterotic, with dorsal and ventral
laminae present. Extrascapular present. Lateral line com-
plete, beginning at posterolateral exit of posttemporal-su-
pracleithrum canal.

Dorsal lamina of Weber apparatus reaching dorsal sur-
face, with flattened and slender process almost reaching
nuchal plate posteriorly. The latter rhomboid in dorsal
view, with a ventral lamina reaching neural processes of
sixth vertebra. Posterior nuchal plate with two slender
and pointed anterolateral projections joined to first rib
by a ligament, ventrally contacting anterior plate. Gas
bladder chamber evident from dorsal view, posteroven-
tral portion partially enclosed by an anteriorly directed
ventral lamina. Parapophyses of fifth vertebra reaching
lateral wall of body, continuous with posterolateral edge
of cleithrum; extensively joined to posterior region of
complex vertebrae and covering its lateral border. Ribs
Six, first pair on sixth vertebra. Vertebrae 35, fist 30 or 31
bearing transversal lateral processes.

Pectoral spine retrorse serrations larger distally; first
branched ray reaching end of spine or slightly beyond.
Two proximal radials associated with the three proximal
most rays; first branched ray associated with scapulocora-
coid cartilage. Cleithrum dorsomedial pointed projection
entering cavity formed by ventral posttemporal-supra-
cleithrum and lateral lamina of complex vertebra; dor-
solateral arm with a proximal pointed projection lateral
to posttemporal-supracleithrum and rounded edge; medi-
al arm anteriorly concave, bearing an extensive contact
scapulocoracoid posteriorly, and sutured to contralater-
al cleithrum in larger C&S specimen (102.58 mm SL).
Coracoids strongly interdigitated medially, their posterior
processes passing base of last pectoral-fin rays and reach-
ing vertical through dorsolateral arm of cleithrum. Pelvic
fins not reaching anal-fin origin. Basipterygia with de-
veloped dorsolateral wings and lateral cartilage present:
medial cartilage not reaching posterior medial margin
of bone, which bear jagged borders; posterior cartilage
short. First anal-fin pterygiophore reaching posterior por-
tion of vertebra 15 and posterior anal-fin pterygiophore
at posterior portion of vertebra 21. Caudal fin with five
principal rays on both lobes, three dorsal and four or five
ventral procurrent rays.

Coloration (Fig. 7).

Ground of body dark brown to black, head light
brown, pectoral region lighter than dorsal region. A bare-
ly evident light brown middorsal stripe on head from
snout tip to the middle of caudal peduncle, interrupted at
dorsal-fin base. Lateral rows of tubercles brown, lighter
than the background. Maxillary barbels dark brown with
lighter tips; the remaining barbels light brown. Pectoral
fins black with whitish tips; anal fin black with distal half
whitish; all the other fins black with the distal third whit-
ish. After the fixation process, the color tends to become
paler brown, and the white portions on the fins are less
noticeable (Figs 1-3).

Zoosyst. Evol. 100 (3) 2024, 1085-1097

1093

Figure 7. CI-FML 7944. Xyliphius barbatus. Live specimen, 92.4 mm SL. San Francisco River, Bermejo River basin, Jujuy. Scale

bar: 10 mm.

Molecular analysis. Molecular comparison employ-
ing the COI sequence (see Table 2) shows no difference
between Xyliphius barbatus specimen from lot CI-FML
7944 and Xyliphius sp. reported by Diaz et al. (2016) from
Parana River Basin in Rosario, Argentina, herein identified
as Xyliphius barbatus. The estimated evolutionary diver-
gence (number of base substitutions per site from between
sequences) is quite small (D=0.0031) between_X. barbatus
and X. melanopterus, but greater with specimens of X. mag-
dalenae, X. sofiae and X. lepturus (D=0.1092; 0.1414 and
0.1558). Comparisons with X. anachoretes and X. kryptos
were not possible due the lack of available COI sequences
for these species. Moreover, the tree topology for UPGMA
and Maximum Likelihood analysis was similar (Fig. 8).

Distribution. Including the new record from the San
Francisco River, upper Bermejo River basin, Jujuy prov-
ince and the previous records from the Parana River, in
Rosario (Santa Fe province), and in Chaco province (lo-
cality of X. Jombarderoi), together with the records from
the Paraguay River basin in Paraguay reported by Carval-
ho et al. (2017) and from the Pantanal in Brazil (Giménes
Junior and Rech 2022), the species exhibit a broad distri-
bution in the Parana-Paraguay system. The new record of
specimens from the San Francisco River, Upper Bermejo
River basin, Jujuy province, is approximately 750 km in
a straight line from the closest record in Tragadero River,
Parana River basin in Chaco Province (Fig. 9).

Ecological notes. Most of the records of this species
are from the main channel of big rivers and were col-
lected by trawl nets from the bottom of Parana River at
35—40 m depth (MACN 6791). The specimens from the
San Francisco River (Fig. 10) were collected (1 to 4 m
depth) using cast nets, and hand nets. Other informal
captures made by anglers, supported by photographical
evidence (see Suppl. material 1), include one record from
the Parana River in Misiones province (6 to 8 m depth),
and another record in Mision, in the Bermejo River, Salta
province (about 4 m depth). In both cases, captures were
made using earthworm as bait (Julio Endler and Roberto
Toval), see appendix 1. Although speculative, based on
available records, this species seems to exhibit fossorial
habits, regardless of the substrate depth.

Conservation status. The global conservation status of
Xyliphius barbatus was evaluated in 2021, being consid-
ered as Near Threatened under criteria B2a by the IUCN

0Q539436_X. barbatus
MF489384_X. melanopterus
MF489385_X. melanopterus

-- MF489383_X. melanopterus

MF489382_X. magdalenae

MF489386_X. lepturus

KU736764_X. sofiae

KT820070_Amaralia oviraptor

0.04

Figure 8. Maximum likelihood tree based on available COI se-
quences. Bootstrap values are shown next to each node. The
boxes highlight the close relation between X. barbatus and
X. melanopterus.

Red List of Threatened Species (Vera-Alcaraz 2023). When
the species was evaluated, there was registers for only three
specific locations at the Parana and Paraguay rivers, with an
estimate of the Extent Of Occurrence (EOO) of 21,366 to
143,190 km”, and an estimate of Area Of Occupancy (AOO)
between 48 km? and 1,999 km’. According to these values,
the species belongs to threat categories (criterion B2), but
without meeting sufficient conditions to be considered as a
species threatened with extinction. Since its evaluation, four
new localities have been found, three in Mato Grosso de
Sul, almost 600 km farther north from the nearest locality
(Giménes Junior and Rech 2022), and the locality reported
in the present work, more than 650 km to the west of the
nearest locality, which significantly expands the known dis-
tribution of the species. A preliminary exploration of the data
indicates an EOO of about 600,000 km?, which greatly ex-
ceeds previous estimates. A detailed reassessment of the spe-
cies’ threat status under IUCN criteria is necessary, which
will likely result in a recategorization to Least Concern (LC).

However, evaluations for this species should be made
with caution because it has relatively few records and
inhabits areas that are difficult to sample. Additionally,
there is no information available on its population struc-
ture or density throughout its range.

Comparative material examined. See Suppl. material 2.

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1094

Figure 9. Geographical distribution of Xvliphius barbatus.
Square: type locality of Xvliphius barbatus; rhombus: type lo-
cality of Xyliphius lombarderoi, Circules: other published re-
cords; star: new record from Bermejo River.

Discussion

In this contribution we report the northwesternmost re-
cord of Xyliphius barbatus in Argentina, more than 750
km from the previously distribution record of the species.
According to Carvalho et al. (2017) species of Xv/iphius
are commonly found in the main channel of large rivers
and most records are restricted to the upland portions of
Andean piedmont rivers. Conversely X. barbatus and_x.
sofiae occur in relatively lowland stretches. Records of
these species and their presence in museum collections
are scarce, mainly due to the depth at which they occur,
making them difficult to sample. Additionally, their fos-
sorial habits and mimetic coloration contribute to this
scarcity. Xvliphius barbatus was also recorded in the Uru-
guay River basin by Loureiro et al. (2013), but this record
is indeed a miss-identification of Bunocephalus doriae
(Loureiro Pers. Comm., 2022). Garcia (1992) includes
X. barbatus in a list of species from the Parana River ba-
sin in Misiones, but the accuracy of this record cannot be
confirmed because the reference specimen is missing; in
addition, this record is part of the environmental impact
report and is not a formal publication. Nevertheless, the
information provided by Garcia (1992) was subsequently
repeated (Liotta 2006; Calvifio and Castello 2008; Rosso
and Liotta 2021).

The scarcity of material has led to biased descriptions,
since variations in morphology and meristic counts have
not been considered, making it difficult to establish com-
parisons among species. This situation was also high-
lighted by Figuereido and Britto (2010) in the description
of Xyliphius anachoretes, the authors considered that any
inferences concerning the direction of change in the num-
ber of papillae from lower-lip is speculative and prema-
ture due to the absence of comparative material.

The specimens of Xyliphius barbatus collected in the
upper Bermejo River represent the largest known batch
for the species and one of the largest for the genus. Oth-
er numerous collections of aspredinids were made under

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Teran, G.E. et al.: Re-description of Xyliphius barbatus

Figure 10. San Francisco River, Jujuy province at 23°50'27.08"S,
64°37'24.70"W.

special conditions. For example, when a river section
was dried 70 exemplars of Hoplomyzon sexpapilostoma
Taphorn and Marrero 1990 were collected, and when a
dam was closed more than 100 exemplars of Xvliphius
cf. Jepturus were collected (Taphorn and Marrero 1990).
This suggests the low efficacy of conventional fishing
methods due to the distinct habitat use by members of the
genus (Carvalho et al. 2017). The new Xyliphius barba-
tus material obtained has allowed us to make an accurate
re-description for a species which, despite its wide distri-
bution in the Parana-Paraguay River basins, is poorly rep-
resented in fish collections in museums. The inclusion of
new material for the re-description of Xvliphius barbatus
has led to an objective assessment of inter-specific vari-
ation of characters useful for distinguishing the species
from the remaining members of the genus. Among these
characters, we found that the lower limit of papillae on
lower lip ranges from 24 to 30 instead of the previously
reported 28 to 30; the anal-fin rays now range from 5 to 8
instead of 6 to 8; the number of retrorse serrae along the
posterior border of the pectoral-fin spine now ranges from
6 to 11 instead of 6 to 8; and the extension of lower limit
range of vertebral count to 35.

From a genetic perspective, maximum likelihood
analysis identified two main groups: one comprising Xy-
liphius lepturus and X. sofiae, and the other including X.
magdalenae, X. barbatus, and X. melanopterus. This tree
topology aligns with the morphological inferences made
by Carvalho et al. (2017). They suggested that X. sofi-
ae and X. /epturus shared enough features to support a
sister-group relationship. These characters include snout
morphology, lack of median notch, fifth ceratobranchi-
al morphology, branchial apertures separation, anal-fin
rays’ modal number; and lateral line extension. Carvalho
et al. (2017) also proposed a close relationship between
X. anachoretes, X. barbatus, and X. melanopterus who
share a relatively long and narrow fourth parapophysis
and fifth parapophysis deflected anteriorly (vs. short and
broad fourth parapophysis and fifth directed laterally in
the remaining species of Xyliphius). Despite the lack of

Zoosyst. Evol. 100 (3) 2024, 1085-1097

X. anachoretes sequences, our ML tree recovers a very
close relationship between X. barbatus and X. melan-
opterus. The low genetic distance between Xyliphius
barbatus and X. melanopterus is noteworthy, since the
distance to other species and between the other species 1s
almost 50 times that value. In fact, one of the sequences of
X. melanopterus (MF489383) differs only in 1 nucleotide
from the X. barbatus sequence. It is evident that this com-
parison (based in one mitochondrial marker and a few se-
quences) is not enough to make inferences about the tax-
onomy of these two species (which have morphological
differences, such as ray counts and coloration, and inhabit
different basins), but it highlights the need for a complete
morphological and molecular revision of the group in or-
der to complement its definition and species diagnosis.

Additional similarities in the complex vertebra be-
tween Xyliphius melanopterus and X. barbatus were pre-
viously indicated by Carvalho et al. (2017); a narrow and
long fourth parapophyses vertebra (observed in examined
specimens), and anteriorly deflected fifth parapohyses,
perpendicular in the examined X. barbatus. The same au-
thors discuss the possible independent acquisition of gas
bladder encapsulation in Xyliphius due to its absence in
X. magdalenae and X. kryptos (see also Carvalho et al.
2018, Fig. 3), and the presence in the remaining conge-
ners (with the polymorphism in X. /epturus). Our results
also suggest the reduction of this feature in_X. magdale-
nae instead of two independent events of gas bladder en-
capsulation (Fig. 6A). Nonetheless, these characters must
be tested and optimized in a morphological analysis to
support any conclusive hypothesis.

Neither Friel (1994) nor Cardoso (2008) includ-
ed specimens of Xyliphius barbatus in their works.
Xyliphius barbatus bears the eight synapomorphies
proposed by the former author and the additional six
synapomorphies for the subfamily Xyliphiinae pro-
posed by the latter author: (1) lateral surface of fron-
tal lacking orbital concavity; (2) antero-dorsal process
of lacrimal-antorbital (first infraorbital) developed;
(3) supra-preopercle present Friel (1994: Ch.28);
(4) expanded proximal margin of posterior ceratohyal
(Friel 1994: Ch.34); (5) more than 30 gill filaments on
first epibranchial and ceratobranchial (Britto 2002: Ch.
126); (6) four to eight dorsal plus ventral procurrent
rays on caudal-fin. We also observed the bony bulge
on ventral surface lateral ethmoid possibly housing the
olfactory bulb as suggested by Carvalho et al. (2017),
as an additional synapomorphy of the genus.

Conclusions

In this work, an accurate re-description of Xyliphius bar-
batus based on osteological observations, morphometry,
meristic counts and molecular data 1s provided. The dis-
tributional range of this species is widened to the upper
Bermejo River basin in northwestern Argentina, more
than 750 km in straight line from the previously known

1095

record of the species in the country. A provisional phy-
logenetic molecular hypothesis is provided in which the
close relation with X. me/anopterus is observed.

Acknowledgements

We extend our gratitude to Tiago Carvalho for review-
ing the manuscript and making invaluable comments
on Xyliphius species, which significantly enhanced the
quality and accuracy of this paper. Pablo Pereyra (FML)
made figures 4 and 6. We thank Gustavo Chiaramonte
(MACN), James Anyelo Vanegas-Rios (MLP), Diego
Nadalin (MLP), German Saigo (MG), Eugenia Montani
(MG) and Adrian Giacchino (CFA, UMAI) for the sup-
port provided and for making available the ichthyolog-
ical collections of the respective institutions. GET and
GA thank Diego Delgado for help in sampling trips. Julio
Endler and Roberto Toval, for the photograph of speci-
mens (Suppl. material 1). We thank Jorgelina Brasca for
english review and Florencia Brancolini, Pablo Calvino,
Miguel Angel Cortés Hernandez for valuable comments.
Felipe Alonso and Marcos Mirande for permanent sup-
port. This manuscript benefited from the comments and
revisions of Nicolas Hubert, Lucas Medeiros, and two
anonymous reviewers

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1097

Supplementary material |

Informal records by anglers, with
photograph evidence. Speciemens colleced
with earthworm bait

Authors: Guillermo E. Teran, Alejandro Méndez-Lopez,
Mauricio F. Benitez, Wilson S. Serra, Sergio Bogan,
Gaston Aguilera

Data type: docx

Explanation note: The information provided here repre-
sent records of Xyliphius barbatus capture by anglers
in two localities algon the Parana river, also including
a map of these localities.

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

Link: https://doi.org/10.3897/zse.100.121396.suppl1

Supplementary material 2

Comparative material examined

Authors: Guillermo E. Teran, Alejandro Méndez-Lopez,
Mauricio F. Benitez, Wilson S. Serra, Sergio Bogan,
Gaston Aguilera

Data type: docx

Explanation note: In this file all reference material con-
sulted in this work is listed.

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

Link: https://do1.org/10.3897/zse.100.121396.suppl2

zse.pensoft.net