Zoosyst. Evol. 100 (2) 2024, 357-372 | DOI 10.3897/zse.100.117956

Gee
BERLIN

New species of Rockacestus (Cestoda, Phyllobothriidea) from skates of
the genus Bathyraja (Rajiformes, Arhynchobatidae) in the Southwestern
Atlantic Ocean with comments on the distribution of the genus

Guillermina Garcia Facal!*, Veronica A. Ivanov!:@*, Adriana Menoret!?

1 Universidad de Buenos Aires, Facultad de Ciencias Exactas y Naturales, Departamento de Biodiversidad y Biologia Experimental,
Laboratorio de Sistemdtica y Biologia de Pardsitos de Organismos Acudticos (SIBIPOA), Buenos Aires, Argentina
2 CONICET-Universidad de Buenos Aires, Instituto de Biodiversidad y Biologia Experimental (IBBEA), Buenos Aires, Argentina

https://zoobank. org/9ED1E923-03F'7-4EA2-906B-76A82848 1099

Corresponding author: Guillermina Garcia Facal (guillefacal@gmail.com); Adriana Menoret (menoret.a@gmail.com)

Academic editor: Pavel Stoev # Received 29 December 2023 Accepted 14 March 2024 Published 3 April 2024

Abstract

Three new species of Rockacestus Caira, Bueno & Jensen, 2021 were recovered from arhynchobatid skates taken between 37°S—55°S
in the Magellanic Province, Southwestern Atlantic Ocean. Rockacestus blasi sp. nov. was found in Bathyraja macloviana (Norman,
1937), whereas Rockacestus magellanicus sp. nov., and Rockacestus ottavianoi sp. nov. were found in Bathyraja magellanica
(Philippi, 1902). These species differ from their congeners in having a particular combination of anatomical features, including a
moderate to highly folded bothridia, presence of a uteroduct, and a seminal receptacle. Cross-sections of mature proglottids were
made for the first time in members of the genus. In addition, the microthrix pattern was described in detail, focusing on the distal bo-
thridial surface, including the apical sucker and marginal loculi resulting in a common microthrix configuration with filitriches and
small lanceolate, lingulate, and a particular kind of coniform spinitriches. The diagnosis of Rockacestus is revised to include several
features exhibited by the new species. The distribution data of the species currently assigned to Rockacestus are compiled and updat-
ed. The finding of R. b/asi sp. nov., R. magellanicus sp. nov., and R. ottavianoi sp. nov. not only increases the number of members
of Rockacestus in the Magellanic Province in the Southwestern Atlantic from one to four but also expands our knowledge of phyl-
lobothriideans and their association with the softnose skates of the genus Bathyraja Ishiyama, 1958 in the Southern Hemisphere.

Key Words

Bathyraja, genus distribution, MPA Namuncura/Burdwood Bank, Rockacestus blasi sp. nov., Rockacestus magellanicus sp. nov.,
Rockacestus ottavianoi sp. nov., Southern Hemisphere

Introduction

The genus Rockacestus Caira, Bueno & Jensen, 2021 was
recently erected to house phyllobothriidean species bear-
ing folded bothridia, with apical sucker and marginal lo-
culi, which parasitize rajiform skates (Caira et al. 2021).
The genus currently comprises ten species formally de-
scribed from Arhynchobatidae and Rajidae skates, most-
ly inhabiting temperate and cold waters in the Northern
and Southern Hemispheres (Kay 1942; Williams 1968a,

1968b; Schmidt 1986; Wojciechowska 1991; Caira et al.
2021). Rockacestus brittanicus (Williams, 1968) described
from Raja montagui Fowler, 1910, Rockacestus williamsi
(Schmidt, 1986) recovered from Leucoraja fullonica (Lin-
naeus, 1758), and Rockacestus piriei (Williams, 1968) found
in Leucoraja naevus (Miller & Henle, 1841) were reported
from the Northern European Seas Province sensu Spalding
et al. (2007) (see Williams 1968a, 1968b). Caira et al. (2021)
described Rockacestus carvajali Caira, Bueno & Jensen,
2021 from Dipturus chilensis (Guichenot, 1848) off Chiloé

* This paper was mostly discussed prior to the death of Veronica A. Ivanov in January 2020.

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

358 Garcia Facal, G. et al.: Three new Rockacestus species from the Southwestern Atlantic

between the limits of the Magellanic and the Warm Temper-
ate Southeastern Pacific Provinces, while Rockacestus ra-
dioductus (Kay, 1942) was found in Beringraja binoculata
(Girard, 1855) in the Cold Temperate Northeast Pacific (Kay
1942; Caira et al. 2021). Rockacestus conchai Caira, Bueno
& Jensen, 2021 was recovered from Bathyraja albomacula-
ta (Norman, 1937) off Malvinas Islands in the Magellanic
Province (Caira et al. 2021). The remaining four species of
Rockacestus registered from the southernmost latitudes to
date (1.e., Rockacestus arctowskii [Wojciechowska, 1991],
Rockacestus georgiensis |Wojciechowska, 1991], Rock-
acestus rakusai {Wojciechowska, 1991], and Rockacestus
siedleckii [Wojciechowska, 1991]) mostly parasitize skate
species of the genus Bathyraja Ishiyama, 1958 with records
in the Scotia Sea, and the Continental high Antarctic Prov-
ince (Wojciechowska 1991).

During fieldworks conducted between 2011-2016 off
Argentina in the Southwestern Atlantic Ocean (SWA),
skates of the genus Bathyraja were found to be parasitized
with cestodes of three new species of Rockacestus. The de-
scriptions of the new species include detailed morpholog-
ical features; cross-sections of mature proglottids are
presented for the first time for the genus. Likewise, more
information on microtriches of the genus 1s presented.

Materials and methods
Sampling

Tapeworms examined in this study were collected from a
total of ten skates belonging to two species of the genus
Bathyraja: five specimens of Bathyraja macloviana (Nor-
man, 1937) and five specimens of Bathyraja magellanica
(Philippi, 1902) (Rajiformes, Arhynchobatidae). The skates
were caught from different localities along the SWA. Three
specimens of B. macloviana were caught off Rio Grande,
Tierra del Fuego Province at 54°29.50'S, 65°3.16'W (as-
signed unique host number PD3-026), off Necochea, Bue-
nos Aires Province at 39°53.99'S, 57°0.64'W (PD3-255)
and 39°52.64'S, 56°38.72'W (PD3-257) all in March 2011.
Two specimens of B. macloviana were caught off Villa
Gesell, Buenos Aires Province at 37°33.10'S, 55°19.20"W
(PD5-205) in August 2012 and off the Marine Protect-
ed Area Namuncura/Burdwood Bank at 53°55.92'S,
61°31.93'W (PD12-430) in April 2016. Additionally, one
specimen caught off Buenos Aires Province at 39°34.28'S,
56°16.16"W was examined in March 2011 and showed no
signs of infection with phyllobothriideans. The specimens
of B. magellanica were caught off Rio Grande, Tierra
del Fuego Province at 53°26.35'S, 64°58.56'W (assigned
unique host number PD4-059) and 54°1.68'S, 67°6.81'W
(PD4-097) in April 2012, 53°51.36'S, 67°03.84'W (PD10-
039) in March 2014, 54°19.91'S, 64°14.26'W (PD12-479)
in April 2016, and off the Marine Protected Area Namun-
cura/Burdwood Bank at 54°32.60'S, 60°1.28'W (PD12-
045) in March 2016. Also, five uninfected specimens
were caught off Tierra del Fuego Province at 55°03.34'S,
66°07.82'W in March 2014. All hosts were obtained with

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bottom trawls on board the RV Puerto Deseado (CON-
ICET). All tapeworms were removed from the spiral intes-
tine of their respective host, relaxed in seawater, fixed in
10% formalin, and transferred to 70% ethanol for storage.

Preparation of specimens for light microscopy
and scanning electron microscopy

Methods for preparing specimens as whole mounts for
descriptive work using light microscopy and scanning
electron microscopy (SEM) followed Menoret and Ivanov
(2021). The terminal proglottid of one specimen of Rock-
acestus from B. macloviana, one tapeworm of Rockacestus
from B. magellanica, and one detached mature proglottid
of a specimen of Rockacestus from B. magellanica were
embedded in paraffin, and serial cross-sections were cut
at a thickness of 8 um. Sections were stained with Harris’
haematoxylin, counterstained with eosin, and mounted in
Canada balsam. Whole mounts and histological sections
were examined and measured using Olympus BX 51 and
Zeiss Axioscope compound microscopes. Micrographs of
whole mounts and histological sections were taken using
Olympus LC30 camera; drawings were made with the aid
of a drawing tube, both attached to the Olympus BX 51
compound microscope. Measurements are expressed as the
range, followed in parentheses by the mean, standard devi-
ation (when n >3), and the number of worms from which
the measurements were taken. Measurements of genitalia
and reproductive structures were taken from mature pro-
glottids of mature and gravid worms. All measurements are
in micrometres unless otherwise stated.

Mapping and geographic sites

Geographic coordinates in degrees and minutes of type
locality and additional localities of the species ofthe spe-
cies of Rockacestus were extracted from the original de-
scriptions. Estimated coordinates were assigned to those
records that lacked such information in the original pub-
lication. The geographic distribution of the Rockacestus
species was charted using the PANMAP software v.0.9.6
(Diepenbroek et al. 2002).

Terminology

Terminology of microtriches follows Chervy (2009). Val-
id species of Rockacestus follow Caira et al. (2021). Val-
id host names follow Froese and Pauly (2023). Marine
bioregions follow Spalding et al. (2007) for a global scale
and Sabadin et al. (2020) for regionalization in the SWA.

Material examined and museum abbreviations

The museum material examined includes light mi-
crographs of one paratype of R. carvajali (USNM No.

Zoosyst. Evol. 100 (2) 2024, 357-372

1638652), and two paratypes of R. conchai (USNM Nos.
1638654 and 1638655), provided by Anna Phillips from
the Smithsonian National Museum of Natural History—In-
vertebrate Zoology Collection, Washington, D.C., USA.
Museum abbreviations are as follows: MACN-Pa, Museo
Argentino de Ciencias Naturales, Coleccion Parasitoldgi-
ca, Buenos Aires, Argentina; MLP-He, Museo La Plata,
Coleccion Helmintolégica, Buenos Aires, Argentina.

Results

Order Phyllobothriidea Caira, Jensen, Waeschenbach,
Olson & Littlewood, 2014
Genus Rockacestus Caira, Bueno & Jensen, 2021

Rockacestus blasi sp. nov.
https://zoobank.org/E014EFBD-32EB-489A-9449-B 1ESB4D45A9D
Figs 1A, 2, 3, 7AC, 8

Type material. Holotype whole mature worm, off Villa
Gesell, Buenos Aires Province, Argentina (37°33.10'S,
55°19.20'W), 98.7 m, 06 Aug. 2012, A. Menoret leg.,
MACN-Pa No. 783.

Paratypes 1 whole mature worm, 1 whole gravid
worm, | detached gravid proglottid, same data as holo-
type, MACN-Pa Nos. 784/1—3. One detached gravid pro-
glottid, same data as for preceding, MLP-He No. 8097.
One whole mature worm, | detached gravid proglottid,
off Rio Grande, Tierra del Fuego Province, Argentina
(54°29 .50'S, 65°3.16'W), 133 m, 16 Mar. 2011, V. A. Iva-
nov & A. Menoret leg., MACN-Pa Nos. 786/1—2. Nine
whole gravid worms, cross-section of 2 attached mature
proglottid, off Necochea, Buenos Aires Province, Argen-
tina (39°52.64'S, 56°38.72'W), 91.3 m, 27 Mar. 2011, V.
A. Ivanov & A. Menoret leg., MACN-Pa Nos. 785/1-9,
785/11—24. Three whole gravid worms, same data as
for preceding, MLP-He No. 8096. One whole gravid
worm, off Necochea, Buenos Aires Province, Argentina
(39°53.99'S, 57°0.64'W), 94 m, same data as for preced-
ing, MACN-Pa No. 785/10. One whole immature worm,
off the Marine Protected Area Namuncura/Burdwood
Bank, Argentina (53°55.92'S, 61°31.93'W), 184 m, 19
Apr. 2016, A. Menoret leg., MACN-Pa No. 787.

Description. Based on 18 specimens (14 whole grav-
id worms, 3 whole mature worms, 1 immature worm), 3
detached gravid proglottids, cross-sections of 1 mature
proglottid, and 3 scoleces examined with SEM. Worms
apolytic, proglottids craspedote. Specimens possessing
mature proglottids, 26.8-45.2 (35.7 + 9.2, n=3) mm long,
140-204 (163 + 36, n = 3) proglottids per worm. Speci-
mens possessing gravid proglottids, 22.3—50.9 (36.1 + 7.6,
n= 14) mm long, 106-162 (128 + 18, n= 14) proglottids
per worm (Fig. 1A). Maximum width at level of scolex
or immature proglottid. Scolex composed of 4 bothridia,
400-830 (621 + 127, n= 17) long, 580—1,220 (891 + 193,
n = 17) wide. Bothridia folded, 375—685 (506 + 100, n=
8) long, 425—750 (571 + 113, n = 8) wide when folded,
sessile anteriorly, free posteriorly; with apical sucker and

399

C *®

=
N

Figure 1. Light micrographs of whole worms of Rock-
acestus from the Southwestern Atlantic Ocean. A. Rock-
acestus blasi sp. nov. (holotype MACN-Pa No. 783) from
Bathyraja macloviana; B. Rockacestus magellanicus sp.
nov. (holotype MACN-Pa No. 789) from Bathyraja mag-
ellanica, C. Rockacestus ottavianoi sp. nov. (holotype
MACN-Pa 793) from Bathyraja magellanica.

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360 Garcia Facal, G. et al.: Three new Rockacestus species from the Southwestern Atlantic

Figure 2. Line drawings of Rockacestus blasi sp. nov. from Bathyraja macloviana. A. Scolex (holotype MACN-Pa No.
783); B. Terminal mature proglottid (holotype MACN-Pa No. 783); C. Detail of terminal genitalia, terminal mature
proglottid (holotype MACN-Pa No. 783).

marginal loculi (Figs 2A, 3A, 8B). Posterior part of each
bothridium with weak depression surrounded by circular
band of muscle (Fig. 2A). Apical sucker, 80-123 (107 +
14, n= 13) long, 85-135 (113 + 13, n= 13) wide (Figs 2A,
3A, B). Cephalic peduncle, absent. Neck 8.8—-18.5 (14.0 +
3.0, n= 17) mm long.

Apex of scolex proper covered with acicular fili-
triches. Proximal bothridial surface covered with acic-
ular filitriches (Fig. 31). Distal bothridial surface cov-
ered with acicular filitriches interspersed with lingulate
spinitriches, lingulate spinitriches increasing in density
posteriorly (Fig. 3F, J). Distal surface of apical sucker
covered with acicular filitriches interspersed with lingu-
late spinitriches; posterior half of external rim of apical
sucker with small lanceolate spinitriches (Fig. 3B—E).
Distal surface of marginal loculi covered with papilli-
form to acicular filitriches interspersed with short co-
niform spinitriches (Fig. 3G, H). Capilliform filitriches

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on neck and strobila arranged in scutes (Fig. 3K). Cilia
not observed.

Specimens possessing mature proglottids with 133-—
202 (158 + 38, n = 3) immature proglottids and 2-7
(5 + 3, n= 3) mature proglottid per worm. Mature pro-
glottids becoming longer than wide posteriorly (Fig. 1A).
Terminal mature proglottid, 940—-1,360 (1,180 + 216,
n = 3) long, 600—800 (727 + 110, n = 3) wide, length-to-
width ratio, 1.6-1.7 (1.6 + 0.1): 1. Specimens possessing
gravid proglottids with 99-146 (120 + 17, n= 14) imma-
ture proglottids, 4-8 (7 + 1.5, n= 14) mature proglottids,
and 1-2 (1 + 0.4, n = 14) gravid proglottids per worm.
Gravid proglottids longer than wide. Terminal gravid pro-
glottid, 1,180-1,820 (1,591 + 203, n= 14) long, 620-970
(783 + 97, n = 14) wide, length-to-width ratio, 1.4-2.9
(2.1 0.4): 1 (Fig. 2B).

Testes spherical to slightly oblong, 75-96 (86 + 9,
n = 4) in total number, 55—88 (78 + 10, n= 17) long, 54—

Zoosyst. Evol. 100 (2) 2024, 357-372

361

Figure 3. Rockacestus blasi sp. nov. from Bathyraja macloviana, scanning electron micrographs. A. Scolex, small
letters indicate the location of details shown in Fig. 3B, 3F—G, 31, 3K; B. Apical sucker, small letters indicate location
of detail shown in Fig. 3C—D; C. Distal surface of apical sucker, acicular filitriches and lingulate spinitriches; D. Sur-
face of the external apical sucker rim, lanceolate spinitriches; E. Detail of distal surface of the apical sucker, acicular
filitriches; F. Distal bothridial surface, lingulate spinitriches; G. Distal surface of marginal loculi, acicular filitriches
and short coniform spinitriches; H. Detail of distal surface of marginal loculi; I. Proximal bothridial surface, acicular
filitriches; J. Distal bothridial surface, detail of lingulate spinitriches; K. Scutes on surface of neck.

93 (77 10, n= 17) wide, extending from anterior mar-
gin of proglottid to anterior quarter of the ovary; arranged
in 6—8 columns anteroposteriorly and 3—4 layers deep in
cross-section observed in anterior portion of proglottid
(Figs 2B, 7A). Postvaginal testes present. Cirrus sac oval,
curved anteriorly, 276-450 (379 + 42, n= 16) long, 115-
175 (148 + 19, n = 16) wide. Cirrus coiled, armed with
minute spinitriches. Vas deferens highly coiled, anterior
and adjacent to medial margin of cirrus sac, entering cir-
rus sac through anterior margin (Figs 2B, C, 7B).

Ovary lobulated, H-shaped in frontal view, X-shaped
in cross-section at level of isthmus, 230-580 (350 +
79, n = 17) long, 250-610 (456 + 83, n = 17) wide
(Figs 2B, 7C). Vagina thick-walled, extending anteri-
orly from ootype region forming a seminal receptacle,
then running laterally along vas deferens bulk to ante-
rior quarter of proglottid, recurving posteriorly to enter
genital atrium anterior to cirrus sac (Figs 2B, C, 7C).
Vagina and cirrus open into a small common genital
atrium, 40-85 (66 + 14, n= 16) deep. Genital pores al-

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362 Garcia Facal, G. et al.: Three new Rockacestus species from the Southwestern Atlantic

ternate irregularly, 54-73% (61 + 5, n= 17) of proglot-
tid length from posterior margin of proglottid. Vitellar-
ium follicular, follicles irregular in shape, 31-52 (41 +
9,n=17) long, 50-80 (70 + 10, n= 17) wide, arranged
in 2 lateral bands almost reaching midline in anterior
third of proglottid, each band consisting of multiple
columns (5 columns of follicles anterior to cirrus sac),
extending throughout the length of proglottid, uninter-
rupted by ovary, partially interrupted by genital atrium
(Figs 2B, 7A—C). Uterus saccate, restricted to region
between ovary and cirrus sac, running anteriorly up to
genital pore level; uterine duct not observed (Fig. 2B).
Mehlis’ gland, 80-115 (101 + 8, n= 15) long, 60-110
(94 + 13, n= 15) wide, posterior to the ovarian isthmus
(Fig. 2B).

Detached gravid proglottids, 2,300—2,525 (2,392 + 118,
n = 3) long, 725-775 (758 + 29, n = 3) wide, length-to-
width ratio, 3.0-3.3 (3.2 + 0.1): 1.

Host. Bathyraja macloviana (Norman, 1937), Pata-
gonian skate (Rajiformes, Arhynchobatidae) (type host).
Prevalence of infection, 83% in B. macloviana (5 hosts
infected out of 6 examined).

Etymology. This species is named in memory of the
first author’s father, Blas Garcia Mallarine for his invalu-
able love, support, and encouragement over the years.

Distribution. This species is widespread along the
continental shelf of Argentina occurring from waters off
Buenos Aires Province to southeast Patagonia including
the Marine Protected Area Namuncura/Burdwood Bank,
Argentina (Fig. 9).

Remarks. Specimens of R. blasi sp. nov. can easi-
ly be distinguished from five valid species in the genus
by the total length. Rockacestus blasi sp. nov. is lon-
ger than R. carvajali and R. conchai (22.3—50.9 mm vs.
13.1-14.5 mm and 9.9-16.9 mm, respectively), and is
shorter than R. brittanicus, R. georgiensis and R. wil-
liamsi (22.3-50.9 mm vs. 170-250 mm, 60-170 mm,
and 90 mm, respectively). Rockacestus blasi sp. nov.
differs from R. piriei, R. radioductus, and R. rakusai
in possessing fewer testes (75-96 vs. 137-165, =100,
and 120-165, respectively). Rockacestus blasi sp. nov.
can also be distinguished from R. radioductus in the
distribution of testes (arranged in 6—8 columns in an-
teroposterior view vs. more than 15), the distribution
of the vitelline follicles in the anterior third of the pro-
glottid (reaching almost the midline of the proglottid
vs. restricted to lateral bands), and in the position of the
genital pore (54-73% from the posterior margin of the
proglottid vs. equidistant from the anterior and posteri-
or margin of the proglottid). Rockacestus blasi sp. nov.
can be distinguished from R. arctowskii by the number
of proglottids (140-204 vs. 24-98, respectively). Rock-
acestus blasi sp. nov. 1s different than R. siedleckii in
the length of the scolex (400-830 vs. 840—960, respec-
tively) and in the size of the apical sucker (80-135 vs.
185-220, respectively). Finally, R. blasi sp. nov. can be
distinguished from 9 members in the genus by being
apolytic instead of euapolytic.

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Rockacestus magellanicus sp. nov.
https://zoobank.org/E935F2CC-AFED-490F-98B7-C426CC919F07
Figs 1B, 4A-C, 5, 7D-F

Type material. Holotype whole mature worm; off
Rio Grande, Tierra del Fuego Province, Argentina
(53°51.36'S, 67°03.84'W), 58 m, 31 Mar. 2014, A.
Menoret leg., MACN-Pa No. 789.

Paratypes | whole mature worm, | mature strobila, 2
detached mature proglottid, cross-section of 1 detached
mature proglottid, off Rio Grande, Tierra del Fuego Prov-
ince, Argentina (54°19.91'S, 64°14.26'W), 122 m, 22
Apr. 2016, A. Menoret leg., MACN-Pa Nos. 790/1-14.
One strobila, 1 detached mature proglottid, same data
as preceding, MLP-He No. 8098. One whole mature
worm, off Rio Grande, Tierra del Fuego Province, Ar-
gentina (53°26.35'S, 64°58.56'W), 130 m, 1 Apr. 2012,
A. Menoret leg., MACN-Pa No. 792. One whole mature
worm, off the Marine Protected Area Namuncura/Burd-
wood Bank (54°32.60'S, 60°1.28'W), 98 m, 30 Mar. 2016,
A. Menoret leg., MACN-Pa No. 791. One whole mature
worm, same data as preceding, MLP-He No. 8099.

Description. Based on 7 specimens (5 whole mature
worms and 2 strobilae without scoleces), 5 detached ma-
ture proglottids, 3 detached gravid proglottids, cross-sec-
tions of 1 detached mature proglottid, and 3 scolec-
es examined with SEM. Worms euapolytic, 9.9-19.5
(14.4 + 4.0, n= 5) mm long, 61-115 (90.3 + 23, n= 7)
craspedote proglottids per worm (Fig. 1B). Maximum
width at level of scolex or immature proglottids. Scolex
composed of 4 bothridia, 520-810 (631 + 113, n = 5)
long, 779-1,050 (944 + 116, n= 5) wide (Figs 4A, 5A).
Bothridia folded, 450-471 (n = 2) long, 411-550 (n = 2)
wide when folded, sessile anteriorly, free posteriorly, with
apical sucker and marginal loculi. Posterior part of each
bothridium with weak depression surrounded by circu-
lar band of muscle (Figs 4A, 5A). Apical sucker, 70—105
(84 + 17, n=4) long, 70-100 (85 + 17, n= 4) wide (Figs
4A, 5A, B). Cephalic peduncle, absent. Neck, 3.6-8.3
(5.4 + 2.0, n=5) mm long.

Apex of scolex proper covered with acicular filitriches
(Fig. 5H). Proximal bothridial surface covered with acic-
ular filitriches (Fig. 5G). Distal bothridial surface covered
with acicular filitriches interspersed with lingulate spini-
triches, lingulate spinitriches increasing in density poste-
riorly (Fig. 5E, F). Distal surface of apical sucker covered
with acicular filitriches interspersed with lingulate spini-
triches; posterior half of external rim of apical sucker with
lanceolate spinitriches (Fig. SB—D). Distal marginal loc-
uli surface covered with papilliform to acicular filitriches
interspersed with short coniform spinitriches (Fig. 5I, L).
Capilliform filitriches on neck and strobila arranged in
scutes (Fig. 5J, K). Cilia observed in proximal and distal
bothridial surfaces, including apical sucker and marginal
loculi (Fig. 5G, L).

Immature proglottids wider than long, 59-109 (84 + 23,
n= 7) in number. Mature proglottids wider than long, be-
coming longer than wide with maturity, 2-7 (4+ 2, n=7)

Zoosyst. Evol. 100 (2) 2024, 357-372 363

200 um

Figure 4. Line drawings of species of Rockacestus from the Southwestern Atlantic. A-C. Rockacestus magellanicus
sp. nov. from Bathyraja magellanica, A. Bothridium (paratype MLP-He No. 8099); B. Detail of ootype region, mature
proglottid (paratype MACN-Pa No. 790/4); C. Terminal mature proglottid (paratype MLP-He No. 8098); D-E. Rock-
acestus ottavianoi sp. nov. from Bathyraja magellanica; D. Bothridium (paratype MACN-Pa No. 794/1); E. Terminal

mature proglottid (holotype MACN-Pa No. 793).

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364 Garcia Facal, G. et al.: Three new Rockacestus species from the Southwestern Atlantic

Figure 5. Rockacestus magellanicus sp. nov. from Bathyraja magellanica, scanning electron micrographs. A. Scolex, small
letters indicate the location of details shown in Fig. 5B, 5E-I; B. Apical sucker, small letters indicate the location of details
shown in Fig. 5C—D; C. Surface of the external apical sucker rim, acicular filitriches and lanceolate spinitriches; D. Distal
apical sucker surface, acicular filitriches and lingulate spinitriches; E—F. Distal bothridial surface, acicular filitriches and
lingulate spinitriches; G. Proximal bothridial surface, acicular filitriches, and cilium (white arrow); H. Apex of scolex,
acicular filitriches; I. Distal surface of marginal loculi, acicular filitriches and coniform spinitriches; J. Scutes on surface
of neck; K. Detail of scutes, capilliform filitriches; L. Detail of microtriches in marginal loculi and ciltum (white arrow).

in number (Fig. 1B). Terminal mature proglottid longer
than wide, 925—1,430 (1,115 + 201) long, 376-680 (502
+ 111) wide, length-to-width ratio, 1.4-2.7 (2.3 + 0.4,
n=6): 1 (Fig. 4C).

Testes oblong, 67—89 (76 + 8, n=6) in total number, 51-—
67 (62+ 6, n=6) long, 44-57 (49 + 5, n=6) wide, extend-
ing from anterior margin of proglottid to anterior quarter
of ovary; arranged in 5—6 columns anteroposteriorly and
2 layers deep in cross-section observed in anterior por-

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tion of proglottid (Figs 4C, 7D). Cirrus sac oval, curved
anteriorly, 200-340 (269 + 58, n= 6) long, 95-140 (118
+ 18,n=6) wide. Cirrus coiled, armed with minute spini-
triches. Vas deferens highly coiled, extending anteriorly
to vagina bend, overlapping medial margin of cirrus sac,
entering cirrus sac through ventral margin (Figs 4C, 7E).

Ovary lobulated, H-shaped in frontal view, X-shaped
in cross-section at level of isthmus, 255-615 (418 + 135,
n= 6) long, 163-375 (246 + 75, n= 6) wide (Figs 4B, C,

Zoosyst. Evol. 100 (2) 2024, 357-372

7F). Vagina thick-walled, extending anteriorly from oo-
type region forming a seminal receptacle to bulk of vas
deferens, then descending laterally along anterior mar-
gin of cirrus sac to enter genital atrium anterior to cirrus
(Figs 4C, 7F). Vagina and cirrus sac join into genital atri-
um, 40-60 (53 + 12, n= 3) deep. Genital pores alternate
irregularly, 62-75% (68 + 5, n = 6) of proglottid length
from posterior margin of proglottid.

Vitellarium follicular, follicles irregular in shape,
15-34 (26 + 7, n = 6) long, 38-55 (47 + 6, n = 6) wide,
arranged in 2 lateral bands almost reaching midline in an-
terior third of proglottid, each band consisting of multiple
columns (4 columns of follicles anterior to cirrus sac),
extending throughout proglottid length, uninterrupted by
ovary, partially interrupted by genital atrium (Figs 4C,
7D-F). Uterus saccate, restricted to region between ovary
and cirrus sac, running anteriorly up to genital pore lev-
el; uterine duct observed (Figs 4C, 7F). Mehlis’ gland,
55-110 (77 + 20, n= 5) long, 55—75 (71 + 9, n= 5) wide,
posterior to ovarian isthmus (Fig. 4B, C).

Detached mature proglottids, 1,650—2,075 (1,875 +
207, n= 5) long, 550-770 (654 + 99, n=5) wide, length-
to-width ratio, 2.7-3.2 (2.9 + 0.2, n = 5): 1. Detached
gravid proglottids, 2,300—2,525 (2,392 + 118, n=3) long,
725-775 (758 + 29, n = 3) wide, length-to-width ratio,
3.0-3.3 (3.2£0.1): 1.

Host. Bathyraja magellanica (Philippi, 1902), Ma-
gellan skate (Rajiformes, Arhynchobatidae) (type host).
Prevalence of infection, 40% in B. magellanica (4 hosts
infected out of 10 examined).

Etymology. The specific name refers to the species
distribution along the Magellanic Province in the Argen-
tine Sea, SWA.

Distribution. This species is known from southern
waters off Tierra del Fuego Province, Argentina including
the Marine Protected Area Namuncura/Burdwood Bank,
Argentina (Fig. 9).

Remarks. Rockacestus magellanicus sp. nov. 1s short-
er than R. blasi sp. nov., R. brittanicus, R. georgiensis,
R. piriei, R. radioductus, R. rakusai, R. siedleckii, and
R. williamsi (9.9-19.5 vs. 22.3—250 mm in total length,
respectively). Specimens of R. magellanicus sp. nov.
have fewer testes than those of R. carvajali (67-89 vs.
46-55, respectively). Moreover, R. magellanicus sp.
nov. has lingulate spinitriches and acicular filitriches on
the distal surface of the bothridia whereas R. carvajali
has only papuilliform filitriches. Rockacestus magellani-
cus sp. nov. differs from R. conchai in the scolex width
(779-1,050 vs. 1,122—1,775, respectively), size of both-
ridia (450-471 long by 411-550 wide vs. 478-624 long
by 600-830 wide, respectively). Additionally, R. magel-
lanicus sp. nov. has acicular filitriches and small lingulate
spinitriches on the distal surface of apical sucker whereas
R. conchai only has acicular filitriches. Rockacestus mag-
ellanicus sp. nov. is different from R. arctowskii in the
size of the cirrus sac (200-340 long by 95—140 wide vs.
370-480 long by 154-215 wide, respectively) and in the
size of the apical sucker (70-105 long by 70-100 wide vs.
212-250 in diameter, respectively).

365

Rockacestus ottavianoi sp. nov.
https://zoobank. org/75E09CF2-DC8D-470D-97EA-1ACEA43C6644
Figs 1C, 4D, E, 6, 7G-I

Type material. Holotype whole mature worm, off Rio
Grande, Tierra del Fuego Province, Argentina (54°1.68'S,
67°6.81'W), 193 m, 2 Apr. 2012, A. Menoret leg., MACN-
Pa No. 793.

Paratypes 1 whole mature worm, 1 whole mature
strobila (SEM voucher), cross-section of 1 attached ma-
ture proglottid, same data as holotype, MACN-Pa Nos.
794/1—13. One whole mature worm, same data as for pre-
ceding, MLP-He No. 8100.

Description. Based on 4 specimens (3 whole mature
worms, and | strobila without scolex), cross-sections of
1 mature proglottid, and 2 scoleces examined with SEM.
Worms euapolytic, 23.1-53.1 (39.1 + 13.8, n = 4) mm
long, 124-195 (156 + 36, n = 3) craspedote proglottids
per worm (Fig. 1C). Maximum width at level of scolex.
Scolex composed of 4 bothridia, 590-750 (648 + 70,
n=4) long, 978—1,250 (1,133 + 36, n= 4) wide (Figs 4D,
6A). Bothridia folded, 530-600 (570 + 36, n = 3) long,
520-720 (613 + 101, n=3) wide when folded, sessile an-
teriorly, free posteriorly, consisting of apical sucker and
marginal loculi. Posterior part of each bothridium with
weak depression surrounded by circular band of muscle
(Figs 4D, 6A). Apical sucker 100-130 (113 + 15, n= 3)
long, 110-140 (125 + 13, n = 3) wide (Figs 4D, 6A, B).
Cephalic peduncle, absent. Neck 11.6—25.3 (19.4 + 6.0,
n=4) mm long.

Apex of scolex proper covered with acicular to capilli-
form filitriches (Fig. 6E). Proximal bothridial surface cov-
ered with acicular filitriches (Fig. 6H). Distal bothridial
surface covered with acicular filitriches interspersed with
lingulate spinitriches, lingulate spinitriches increasing in
density posteriorly (Fig. 6F, G). Distal surface of apical
sucker covered with acicular filitriches interspersed with
small lingulate spinitriches; posterior half of external rim
of apical sucker with lanceolate spinitriches (Fig. 6B—D);
cilia found throughout distal surface of apical sucker.
Distal surface of marginal loculi covered with acicular
filitriches interspersed with short coniform spinitriches
(Fig. 61, L). Capilliform filitriches on neck and strobila
arranged in scutes (Fig. 6J, K).

Immature proglottids wider than long, 123—179 (150 +
28, n= 3) in number (Fig. 1C). Mature proglottids wider
than long, becoming longer than wide with maturity, 2-16
(6 + 7, n= 4) in number (Fig. 1C). Terminal mature pro-
glottid longer than wide, 970—1,460 (1,220 + 207) long,
570-760 (663 + 81) wide, length-to-width ratio, 1.4—2.3
(1.9+0.4,n=4): 1 (Fig. 4B).

Testes oblong, 92-152 (108 + 39, n = 3) in total num-
ber, 55-68 (60 + 5, n = 4) long, 43-52 (46 + 4, n = 4)
wide, extending from anterior margin of proglottid to an-
terior quarter of ovary; arranged in 6—7 columns antero-
posteriorly and 2 layers deep in cross-section observed
in anterior portion of proglottid (Figs 4E, 7G). Cirrus sac
oval, curved anteriorly, 350-395 (365 + 26, n = 3) long,
125-165 (138 + 23, n=3) wide. Cirrus coiled, armed with

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366 Garcia Facal, G. et al.: Three new Rockacestus species from the Southwestern Atlantic

minute spinitriches. Vas deferens highly coiled, extend-
ing anteriorly to vagina bend, overlapping medial portion
of cirrus sac, anterior to cirrus sac (Fig. 4E).

Ovary lobulated, H-shaped in frontal view, X-shaped
in cross-section at level of isthmus, 345—500 (408 + 81, n
= 3) long, 235-355 (292 + 60) wide (Figs 4E, 71). Vagina
thick-walled, extending anteriorly from the ootype region
forming a seminal receptacle, to bulk of vas deferens de-

scending laterally along anterior margin of cirrus sac to
enter genital atrium anterior to cirrus (Figs 4E, 71). Vagi-
na and cirrus sac join into genital atrium, 50-60 (55 + 7,
n = 2) deep. Genital pores alternate irregularly, 68—74%
(71 + 2, n=4) of proglottid length from posterior margin
of proglottid. Vitellarium follicular, follicles irregular in
shape, 28-55 (39 + 12, n= 4) long, 43-50 (46 + 3, n= 4)
wide, arranged in 2 lateral bands almost reaching the mid-

Figure 6. Rockacestus ottavianoi sp. nov. from Bathyraja magellanica, scanning electron micrographs. A. Scolex,
small letters indicate the location of details shown in; B. Apical sucker, small letters indicate the location of details
shown in Fig. 6C, D; C. Surface of the external apical sucker rim, acicular filitriches and small lingulate spinitriches;
D. Detail of distal apical sucker surface, lingulate spinitriches; E. Apex of scolex, acicular to capilliform filitriches; F,
G. Distal bothridial surface, acicular filitriches and lingulate spinitriches; H. Proximal bothridial surface, acicular fili-
triches; I. Distal surface of marginal loculi, acicular filitriches and short coniform spinitriches; J, K. Scutes on surface
of neck; L. Detail of microtriches on marginal loculi.

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Zoosyst. Evol. 100 (2) 2024, 357-372

vt

367

Figure 7. Light micrographs of cross-sections of mature proglottids of species of Rockacestus off Argentina. A—C. Rock-
acestus blasi sp. nov.;, A. At the level of the testes, anterior to the cirrus sac; B. At the level of the cirrus sac; C. At the
level of ovarian isthmus; D—F. Rockacestus magellanicus sp. nov.; D. At the level of the testes, anterior to the cirrus
sac; E. At the level of the cirrus sac; KF. At the level of ovarian isthmus; G—I. Rockacestus ottavianoi sp. nov, G. At
the level of the testes, anterior to the cirrus sac; H. At the level of the cirrus sac; I. At the level of ovarian isthmus; ¢s
— cirrus sac; oc — ovicapt; ov — ovary; sr — seminal receptacle; t — testes; u — uterus; ut — uteroduct; vd — vas
deferens; vf — vitelline follicle; vg — vagina; vod — ventral osmoregulatory duct.

line in anterior third of proglottid, each band consisting
of multiple columns (5—6 columns anterior to cirrus sac)
of follicles, extending throughout the length of proglottid,
uninterrupted by ovary, interrupted partially by genital
atrium (Figs 4E, 7G—I). Uterus saccate, restricted to region
between ovary and cirrus sac running anteriorly up to gen-
ital pore level, uterine duct observed (Figs 4E, 7H). Meh-
lis’ gland, 90-110 (99 + 9, n=4) long, 63-100 (76+ 17, n
= 4) wide, posterior to ovarian isthmus (Fig. 4E).

Host. Bathyraja magellanica (Philippi, 1902), Ma-
gellan skate (Rajiformes, Arhynchobatidae) (type host).
Prevalence of infection, 10% in B. magellanica (1 host
infected out of 10 examined).

Etymology. This species is named in honor of Juan
Manuel Ottaviano for his genuine and loyal friendship
over the years.

Distribution. This species is known from its type lo-
cality, off Rio Grande, Tierra del Fuego Province, Argen-
tina (54°1.68'S, 67°6.81'W).

Remarks. Rockacestus ottavianoi sp. nov. can be dis-
tinguished from R. arctowskii, R. carvajali, R. conchai,

and R. magellanicus sp. nov. by having more testes (92—
152 vs. 60-80, 46-55, 51-73, and 67-89, respectively)
and a greater number of proglottids (124-195 vs. 24-98,
75-81, 64-105, and 61-115, respectively). Rockacestus
ottavianoi sp. nov. is easily distinguished from three of
its congeners by the worm length by being shorter than
R. brittanicus, R. georgiensis, and R. williamsi (23.1—
53.1 vs. 170-250, 60-170, and 90 mm, respectively).
Rockacestus ottavianoi sp. nov. can be distinguished
from three species in the genus by having different size
of apical sucker. In R. rakusai and R. siedleckii, it is big-
ger than in R. ofttavianoi sp. nov. (250-310 and 185—220
in diameter vs. 100—130 long by 110—140 wide, respec-
tively), whereas in R. piriei it is smaller (90 in diam-
eter vs. 100-130 long by 110-140 wide, respectively).
Rockacestus ottavianoi sp. nov. has a narrower scolex
(978—1,250 in scolex width) and bigger testes (43-52
long by 55-68 wide) than R. radioductus (1,800—2,000
in scolex width; 40 in testes diameter). Finally, R. otta-
vianoi Sp. nov. is euapolytic and has testes distributed in
2 layers deep in cross-section, whereas R. blasi sp. nov.

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368

is apolytic and has testes arranged in 3-4 layers deep in
cross-section.

Update of generic diagnosis and distribution of valid
species of Rockacestus

The diagnosis of Rockacestus sensu Caira et al. (2021)
is revised to include the three species described below
from the skates of the genus Bathyraja from continental
shelf waters off Argentina. The generic diagnosis 1s up-
dated as follows: worms euapolytic or apolytic; scolex
spinitriches lingulate, lanceolate, coniform, filitriches
papilliform or acicular; genital pores lateral, in midhalf
or anterior half of proglottid, irregularly alternating; tes-
tes arranged in 2-4 rows in cross-section; vagina with

Garcia Facal, G. et al.: Three new Rockacestus species from the Southwestern Atlantic

seminal receptacle present or absent; uteroduct present
or absent.

The valid species now include, Rockacestus arctowskii
(Wojciechowska, 1991), Rockacestus blasi sp. nov., Rock-
acestus brittanicus (Williams, 1968), Rockacestus carva-
jali Caira, Bueno & Jensen, 2021, Rockacestus conchai
Caira, Bueno & Jensen, 2021, Rockacestus georgiensis
(Wojciechowska, 1991), Rockacestus magellanicus sp.
nov., Rockacestus ottavianoi sp. nov., Rockacestus piriei
(Williams, 1968), Rockacestus radioductus (Kay, 1942),
Rockacestus rakusai (Wojciechowska, 1991), Rockaces-
tus siedleckii (Wojciechowska, 1991), and Rockacestus
williamsi (Schmidt, 1986).

Figure 8. Light micrographs of scoleces of Rockacestus blasi sp. nov. A. Bothridia fixed while still attached to the host
tissue (paratype MACN-Pa No. 787); B. Bothridia properly relaxed and fixed (paratype MACN-Pa No. 784/2).

Atlantic
Ocean

___ MPA Namuncura/
Burdwood Bank
. e z ty
RM

-70° -60°

Weddell Sea

South Georgia

-50° -40°

Figure 9. Geographic distribution of the valid species of Rockacestus from the Southern Hemisphere. Symbols: red dot:
new records; blue dot: previous records; Rar — Rockacestus arctowskii; Rbl — Rockacestus blasi sp. nov.; Rea — Rock-
acestus carvajali; Reo — Rockacestus conchai;,; Rge — Rockacestus georgiensis, Rma — Rockacestus magellanicus sp.
nov.; Rot — Rockacestus ottavianoi sp. nov.; Rra — Rockacestus rakusai; Rsi— Rockacestus siedleckii.

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Zoosyst. Evol. 100 (2) 2024, 357-372

The genus is widespread among temperate waters of
the East Pacific and Atlantic Oceans, with R. brittani-
cus, R. piriei, and R. williamsi inhabiting the Northeast
Atlantic Ocean; R. radioductus in the Northeast Pacific
Ocean, R. carvajali from off Chiloé Island in the South-
east Pacific Ocean, and R. conchai off Malvinas Islands
in the SWA. A subset of Rockacestus species also inhabits
sub-Antarctic and Antarctic waters, with R. georgiensis
from off South Georgia Island, R. rakusai registered off
the Antarctic Peninsula, and records of R. arctowskii and
R. siedleckii off the Antarctic Peninsula and the Weddel
Sea. Rockacestus blasi sp. nov., R. magellanicus sp. nov.
and R. ottavianoi sp. nov. are restricted to the Magel-
lanic Province sensu Sabadin et al. (2020) in the SWA.
The finding of the new species increases the species
richness from two to five in marine waters around South
America. Thus, the known latitudinal range of the genus
in the Northern Hemisphere covers from 48°N to 58°N
whereas in the Southern Hemisphere Rockacestus now
ranges between 37 to 74°S (Fig. 9).

Discussion
Scolex

A well-relaxed tapeworm scolex represents a challenge,
as it often results in a contracted material, making diffi-
cult a proper characterization of the actual shape of the
bothridia. For example, among members of the Phyllobo-
thriidea, specimens of Guidus show a marked bothridial
projection, and those of R. piriei exhibits highly folded
bothridia when attached to the gut mucosa of their hosts
(figs 13, 14 in Williams [1968b], fig. 4E in Menoret and
Ivanov [2021]).

Among the scoleces herein described, R. magellanicus
sp. nov. and R. ottavianoi sp. nov. exhibit bothridia with
a higher degree of folding than R. blasi sp. nov. A few
specimens of R. blasi sp. nov. were fixed while still at-
tached to the host, appearing to have significantly folded
bothridia (Fig. 8A). However, the typical scolex of these
specimens is obtained once removed from the host and
properly relaxed (Fig. 8B).

Rockacestus conchai was originally described as hav-
ing a scolex with highly folded bothridia, however, it re-
sembles the contracted scoleces of R. piriei and R. blasi
sp. nov. (see Fig. 8A). Therefore, the degree of the both-
ridial folding would be a useful character to distinguish
between species, as long as it is verified that this variabil-
ity is not given by an artifact of the fixation technique.

Ultrastructure of the scolex (SEM)

The surface of the scolex has been analyzed with SEM in
five of the now 13 valid species of Rockacestus. Among
the five species, R. carvajali and R. conchai were par-
tially studied, with R. carvajali mostly characterized by

369

papilliform filitriches (see fig. 8B, D, E in Caira et al.
[2021]). The new species of Rockacestus from off Argen-
tina, in addition to R. conchai, exhibit a common micro-
thrix pattern, with acicular filitriches distributed along
the bothridial surfaces, capilliform filitriches arranged in
scutes on the neck, and lingulate spinitriches in most of
the distal bothridial surface. Both the apical sucker and
the marginal loculi are novel results of the present study
and characterize R. blasi sp. nov., R. magellanicus sp.
nov., and R. ottavianoi sp. nov. by the presence of small
lingulate and lanceolate spinitriches on the distal surface
of the apical sucker and coniform spinitriches with round-
ed tips covering the distal surface of the marginal loculi
(Fies3C2DxG7 5B. Dal L6Be Da ky

Given that most of these species studied with SEM ex-
hibit a variety of spinitriches, it is likely that the scolex
of R. carvajali has been based on micrographs with a
low resolution or magnification. It would be important to
complete the study all along the distal bothridial surface
in R. carvajali and R. conchai, such as the apical sucker
and the marginal loculi, to verify if they are similar in the
type and distribution of microtriches and cilia to those ob-
served in the new species of Rockacestus off Argentina.
The majority of spinitriches found in Rockacestus belong
to morphotypes rarely observed among the phyllobothri-
ideans. For example, lingulate-like spinitriches were re-
ported in the phyllobothriid Crossobothrium laciniatum
Linton, 1889 (see Ruhnke 2011) but they actually are
trullate spinitriches sensu Chervy (2009). In contrast, the
lanceolate spinitriches exhibited by the new species and
described in this study have not yet been reported among
members of the order. Additionally, the particular kind of
short coniform spinitriches with rounded tips observed in
the marginal loculi of these three new species (Figs 3G,
SI, L, 61, L) is reported for the first time among cesto-
des, showing an increasing variety of microtriches as new
cestode taxa are discovered. Therefore, the diversity of
spinitriches in the genus should be extended to include
coniform and lanceolate morphotypes rather than only
lingulate (not gladiate) as mentioned in the original diag-
nosis of Rockacestus.

Proglottid and terminal genitalia characters

Among the diagnostic features of the genus, Caira et al.
(2021) characterized Rockacestus by being euapolytic
and lacking a seminal receptacle.

Specimens of R. brittanicus were originally described
by Williams (1968a) as euapolytic, however, this author
showed a uterus filled with eggs in the terminal proglottids
(see fig. 13 in Williams [1968a]). This discrepancy, also
noticed by Ruhnke (2011), could be resolved once the type
material of R. brittanicus is examined. To date, R. blasi sp.
nov. remains the only apolytic species in the genus. Kay
(1942) described R. radioductus having a seminal recep-
tacle and provided ink drawings of its morphology (fig. 5
in Kay [1942]), being the first report of this structure in the

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370

genus. Furthermore, Wojciechowska (1991) mentioned an
enlarged vagina in the proximal portion between the ova-
ry lobes in R. arctowskii, R. georgiensis, R. rakusai, and
R. siedleckii (see fig. 1B in Wojciechowska [1991 ]). In ad-
dition, a vagina enlarged in a seminal receptacle near the
ovary isthmus is observed in whole mounts and confirmed
in cross-sections of mature proglottids of R. blasi sp. nov.,
R. magellanicus sp. nov. and R. ottavianoi sp. nov. (Fig.
7C, F, I). Therefore, the genus now consists of apolytic
and euapolytic specimens and a seminal receptacle 1s pres-
ent in some species. In addition, some information such as
the size of the Mehlis’ gland, the presence or absence of an
uteroduct, and the entrance site of the vas deferens in the
cirrus sac were described for the first time for the Argen-
tinian species of Rockacestus.

Host associations and host-specificity

Previous records of Rockacestus include a total of nine o1-
oxenous species found in marine skates belonging to the
families Rajidae (1.e., R. brittanicus, R. carvajali, R. geor-
giensis, R. piriei, R. radioductus, and R. williamsi), and
Arhynchobatidae (1.e., R. arctowskii, R. conchai, and R. ra-
kusat) (Kay 1942; Williams 1968a, 1968b; Schmidt 1986;
Wojciechowska 1991; Caira et al. 2021). The exception
is R. siedleckii, which parasitizes two different species of
Bathyraja (see Wojciechowska 1991; Rocka and Zditow-
iecki 1998). The finding of the three species described in
this study, not only increases the number of oioxenous spe-
cies of the genus, but also brings the total number of spe-
cies of Rockacestus as parasites of arhynchobatid skates to
seven. This study comprises the first report of Rockacestus
species in B. macloviana and B. magellanica. Furthermore,
it is the second record of a single softnose skate species
harboring several species of Rockacestus (Wojciechowska
1991; Rocka and Zditowiecki 1998; this paper).

To date, a total of seven species of Bathyraja skates
were registered as hosts of phyllobothriideans (Franzese
et al. 2023; this work). Among them, Rockacestus most
resembles Guidus Ivanov, 2006 since both exhibit a tight
association with Bathyraja skates from the SWA and off
Antarctica (Menoret and Ivanov 2021). Although B. mac-
caini and B. magellanica host several phyllobothriideans,
more surprising is that a single individual of B. magellan-
ica became a suitable host for a complex of phylloboth-
riidean species. Particularly, our individual PD4-097 was
found to host simultaneously R. ottavianoi sp. nov., Gui-
dus francoi Menoret & Ivanov, 2021, and Guidus magel-
lanicus Menoret & Ivanov, 2021.

Beer et al. (2019), relying only on sequencing, identi-
fied several species of a new genus of phyllobothriids re-
covered from seven species of Bathyraja from the Malvi-
nas Islands Shelf. Their specimens not deposited into any
museum were later considered by Caira et al. (2021) as
members of Rockacestus. It would be interesting to iden-
tify these specimens at specific level in order to estimate
more precisely the richness of the genus in the SWA.

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Garcia Facal, G. et al.: Three new Rockacestus species from the Southwestern Atlantic

Geographic distribution

Species of Rockacestus are closely associated with tem-
perate, sub-Antarctic, and Antarctic waters. The Northern
Hemisphere is represented only by a few species, includ-
ing R. brittanicus, R. piriei, R. radioductus, and R. wil-
liamsi, as parasites of rajid skates (Kay 1942; Williams
1968a, 1968b; Schmidt 1986). In contrast, the remaining
nine species occur in the Southern Hemisphere, mostly
parasitizing arhynchobatid skates of the genus Bathyra-
Ja (Wojciechowska 1991; Caira et al. 2021; this paper).
Ten species (1.e., R. brittanicus, R. carvajali, R. conchai,
R. georgiensis, R. magellanicus sp. nov., R. ottavianoi
sp. nov., R. piriei, R. radioductus, R. rakusai, and R. wil-
liamsi) are restricted to their type locality and surround-
ing areas. In contrast, R. arctowskii, R. blasi sp. nov.,
and R. siedleckii do not show this pattern. Rockacestus
arctowskii and R. siedleckii were recorded off the Antarc-
tic Peninsula and in the eastern part of the Weddell Sea,
whereas R. blasi sp. nov. is, to date, the species with the
broadest latitudinal range (37°S—54°S) occurring from
waters off Buenos Aires Province to southeast Patagonia
(Fig. 9). The southern distribution of R. magellanicus sp.
nov. and R. oftavianoi sp. nov. resembles members of
G. francoi and G. magellanicus as they remain locally
restricted to the Magellanic Province in the SWA despite
the wider distribution of their host. Although reports in
the SWA have increased in the recent years due to fo-
cused sampling efforts in the area (Menoret and Ivanov
2009, 2012a, 2012b, 2014, 2015, 2021, 2023; Mutti and
Ivanov 2016; Menoret et al. 2017; Franzese and Ivanov
2018, 2020a, 2020b, 2021; Franzese et al. 2022, 2023),
it would be interesting to see if the composition of the
Rockacestus fauna which is currently restricted to the
type locality changes as the sampling area of host con-
tinues to expand.

Recently, Sabadin et al. (2020) proposed a bioregion-
alization scheme of the SWA, based on chondrichthyan
assemblages, and showed that eight species of Bathyraja,
including B. magellanica, are dominant species of batoids
in the Magellanic Province. Regarding the tight associa-
tion of the genera Rockacestus and Guidus with the genus
Bathyraja in the SWA and considering that the nine new
geographic records of Rockacestus herein reported are in
the Magellanic Province, we, therefore, expect that as the
sampling spectrum increases among Bathyraja species in
the region, the discovery of new species of Rockacestus
and Guidus will also increase. Finally, R. blasi sp. nov.
and R. magellanicus sp. nov. are new reports of phyllo-
bothriideans after Guidus argentinense Ivanov, 2006, off
a marine protected area (see Menoret and Ivanov 2021).
The discovery of new species of Rockacestus from skates
of the genus Bathyraja from off Argentina increases the
number of species from one to four in the SWA and the
number of valid species in the genus from ten to 13, ex-
panding its geographical range and bringing the percent-
age of phyllobothriideans inhabiting the Southern Hemi-
sphere to 39%.

Zoosyst. Evol. 100 (2) 2024, 357-372

Acknowledgements

Special thanks are due to Juan M. Diaz de Astarloa,
Ezequiel Mabragafia, Gabriela Delpiani, and Diego M.
Vazquez from Laboratorio de Biotaxonomia Morfologi-
ca y Molecular de Peces (Universidad Nacional de Mar
del Plata-CONICET) for their help in the identification of
hosts collected on board of the RV Puerto Deseado. The
authors are indebted to Sebastian Franzese and Alejandro
Martinez for sorting part of the material studied in the
laboratory. Special thanks are due to Anna Phillips from
the Smithsonian National Museum of Natural History for
providing us with the digital micrographs of the type ma-
terial of species of Rockacestus. We are also very grate-
ful to Consejo Nacional de Investigaciones Cientificas y
Técnicas (CONICET) for allowing us to work on board
the RV Puerto Deseado. Also special thanks to Pavel Sto-
ev, Editor of Zoosystematics and Evolution, and to the
reviewers for their helpful and insightful suggestions.
This work was supported by the Universidad de Buenos
Aires (UBACyT 20020130100617BA), CONICET (PIP
11220150100705), the Agencia Nacional de Promocion
Cientifica y Tecnologica-ANPCyT (grant number PICT
2014-2358 to VAI and PICT 2016-3672 to AM), and the
American Museum of Natural History (Lerner-Gray Me-
morial Fund for Marine Research 2018 to GGF). This
study was conducted under collecting permits No. 39 and
No. 260 from the Direccion Provincial de Pesca-Ministe-
rio de Asuntos Agrarios de la Provincia de Buenos Aires,
Argentina. This work is the contribution No. 75 to the
MPA Namuncura (Law 26.875).

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