Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-22T23:27:07.683Z Has data issue: false hasContentIssue false

New contributions to the subfamily Polycerinae (Nudibranchia, Polyceridae): description of three new species and one new genus

Published online by Cambridge University Press:  26 September 2023

Marta Pola*
Affiliation:
Departamento de Biología, Facultad de Ciencias, Universidad Autónoma de Madrid; Campus de Excelencia Internacional UAM + CSIC, C/Darwin, 2, 28049 Madrid, Spain Centro de Investigación en Biodiversidad y Cambio Global (CIBC-UAM), Campus de Excelencia Internacional UAM + CSIC, Madrid, Spain
María Miguel-González
Affiliation:
Departamento de Biología, Facultad de Ciencias, Universidad Autónoma de Madrid; Campus de Excelencia Internacional UAM + CSIC, C/Darwin, 2, 28049 Madrid, Spain
Sofía Paz-Sedano
Affiliation:
Departamento de Biología, Facultad de Ciencias, Universidad Autónoma de Madrid; Campus de Excelencia Internacional UAM + CSIC, C/Darwin, 2, 28049 Madrid, Spain
*
Corresponding author: Marta Pola; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The subfamily Polycerinae includes eight genera, from the monospecific Lamellana and Lecithophorus to the diverse Polycera and Gymnodoris, with 33 and 26 valid species, respectively. The monophyly of the subfamily has been tested by molecular data although not all genera were included. To date, relationships within the subfamily are not supported. In the present paper, three new species of polycerid nudibranchs are fully described based on specimens collected in Marshall Islands and Australia: one Palio species (Palio gaeli sp. nov.), one Polycera species (Polycera nimbsi sp. nov.) and a new genus (Paliota galactica gen. and sp. nov.). The new genus is described based on its peculiar radular teeth and genetic divergence.

The internal anatomy was studied by dissections and scanning electron microscope photographs. Partial sequences of mitochondrial cytochrome oxidase c subunit I (COI) and 16S ribosomal RNA (16S) as well as nuclear histone H3 (H3) were also obtained. A phylogenetic framework for two of these three species is proposed, also including for the first time the species Paliolla templadoi and Polycera melanosticta.

Type
Research Article
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of Marine Biological Association of the United Kingdom

Introduction

Polycerinae Alder and Hancock, Reference Alder and Hancock1845 is one of the five subfamilies included in the family Polyceridae Alder and Hancock, Reference Alder and Hancock1845, together with Triophinae Odhner, Reference Odhner1941; Kalinginae Pruvot-Fol, Reference Pruvot-Fol1956; Nembrothinae Burn, 1967, and Kankelibranchinae Ortea, Espinosa & Caballer, 2005. Polycerinae includes eight genera: Polycera Cuvier, Reference Cuvier1816; Thecacera Fleming, 1828; Gymnodoris Stimpson, 1855; Palio Gray, Reference Gray1857; Polycerella Verrill, Reference Verrill1880; Lecithophorus Macnae, Reference Macnae1958; Paliolla Burn, Reference Burn1958, and Lamellana Lin, Reference Lin1992 (MolluscaBase, 2023a). The morphological diagnosis of the subfamily is not clear since they are mostly characterised by having a limaciform body which may have simple tentacular processes on the margin of the oral veil and, on the sides, the mantle is reduced to a few tentacular papillae that can be connected by a ridge (Cuvier, Reference Cuvier1816; Pola et al., Reference Pola, Sánchez-Benítez and Ramiro2014). However, they may have no oral tentacular or mantle processes, as in Lamellana, Lecithophorus, or Gymnodoris. Rhinophores are lamellated (except in Polycerella emertoni Verrill, Reference Verrill1880) but gills are often simply pinnate. They lack buccal pump and usually have a large chitinous labial cuticle with a wing-like accessory process. The radula is usually present but may be absent as in the genera Lamellana and Lecithophorus (Macnae, Reference Macnae1958; Lin, Reference Lin1992; Miller, Reference Miller1996; Palomar et al., Reference Palomar, Pola and García-Vazquez2014).

Some of the genera of this subfamily are difficult to assess. Lamellana gymnota Lin, Reference Lin1992 was described from Hong Kong. The author described the external anatomy and stated that the buccal mass did not have a radula, but no other anatomical details were given (Lin, Reference Lin1992) and nothing more is known beyond its original description. Another interesting monospecific genus was described for Lecithophorus capensis Macnae, Reference Macnae1958, also characterised by the lack of radular teeth. This species appears to be one of the most common subtidal nudibranchs on both sides of the Cape Peninsula, South Africa, and endemic to the Cape Province (Gosliner, Reference Gosliner1987). Paliolla is another small genus that includes only two species: Paliolla cooki (Angas, Reference Angas1864), distributed in Australia from central New South Wales to South Australia (Burn, Reference Burn1958, Reference Burn1975, Reference Burn2015) and Paliolla templadoi (Ortea, Reference Ortea1989), so far found in Cape Verde Island and São Tomé (Ortea, Reference Ortea1989; Ortea et al., Reference Ortea, Rolán and Valdés1992). Paliolla is characterised by an unusual radula with acicular teeth forming a tube (Burn, Reference Burn1958; Ortea, Reference Ortea1989; Ortea et al., Reference Ortea, Rolán and Valdés1992), which makes it unmistakable. To date, its phylogenetic affinities are unknown. The genus Palio, with six valid species (MolluscaBase, 2023b), includes species with a short bilobate veil bearing small tubercules along its edge, a ridge with a row of tubercles on each side of the back, 4 to 8 branched gills, and with more than one small tubercular exo-branchial appendage on each side (Gray, Reference Gray1857; Miller, Reference Miller1996). On the other hand, the genus Polycera is the most diverse within Polycerinae, with 33 species described worldwide to date (MolluscaBase, 2023c). Nimbs and Smith (Reference Nimbs and Smith2016) include five species in their inventory of New South Wales, with their Australian distribution; Polycera capensis Quoy and Gaimard, 1824, P. hedgpethi Er Marcus, 1964, P. janjukia Burn, 1962, P. melanosticta Miller, Reference Miller1996 and, P. risbeci Odhner, Reference Odhner1941. Burn (Reference Burn1958, Reference Burn2006) also cited P. parvula (Burn, Reference Burn1958) for south-eastern Australia. Today, the diagnosis of the genus Polycera is not entirely clear, with a mixture of features: the notum, or mantle, can be smooth, or covered, partially or totally, with papillae or tubercles, and with or without extra-branchial processes. The anterior margin of the head expands to form a frontal veil, which may or may not have tentacular filaments or projections. It has short, lobed oral tentacles. The rhinophores have up to 26 lamellae and are not retractile. The gills, up to 11, can be simple and pinnate to tripinnate, and arranged in a semicircle around the anus. They have paired jaws, the radula has up to 20 rows of teeth; the inner lateral teeth are hooked, the second lateral teeth being larger than the first, the outer laterals being small. They have a large prostate gland, and a penis armed with spines (Gray, Reference Gray1857; Pruvot-Fol, Reference Pruvot-Fol1954; Thompson, Reference Thompson1975; Palomar et al., Reference Palomar, Pola and García-Vazquez2014; Pola et al., Reference Pola, Sánchez-Benítez and Ramiro2014; Sørensen et al., Reference Sørensen, Rauch, Pola and Malaquias2020).

Although the monophyly of the subfamily Polycerinae was supported by molecular data (Palomar et al., Reference Palomar, Pola and García-Vazquez2014) confirming its phylogenetic identity as revealed by morphological studies (Alder and Hancock, Reference Alder and Hancock1845; Odhner, Reference Odhner1941), unfortunately, the relationships within Polycerinae as well as the monophyly of Polycera were never recovered (Palomar et al., Reference Palomar, Pola and García-Vazquez2014; Sørensen et al., Reference Sørensen, Rauch, Pola and Malaquias2020; Knutson and Gosliner, Reference Knutson and Gosliner2022).

The objective of this study is to contribute to further increasing the knowledge about the diversity of this subfamily. A new genus of Polycerinae is described from Australian waters, based on another peculiar radula different from the one found in Paliolla, as well as on molecular data. One new species of Palio and one new Polycera are described from the Marshall Islands and Australia, respectively. An updated phylogenetic framework for Polyceridae including the first sequences for the species P. templadoi and Polycera melanosticta is presented.

Materials and methods

Taxon sampling

A total of 11 specimens belonging to three new species of the subfamily Polycerinae, as well as P. melanosticta, and P. templadoi were collected by SCUBA diving from 1992 to 2017 in Australia, the Marshall Islands, and the Cape Verde archipelago. Specimens from Australia were loaned by the Australian Museum (Sydney) and the Queensland Museum (Melbourne). Specimens from the Marshall Islands and Cape Verde were deposited in the Museo Nacional de Ciencias Naturales (Madrid, Spain). Molecular analyses included ten new specimens, in addition to 27 specimens belonging to 22 species of Polycerinae from GenBank. Seven further species of Nudibranchia were included as the outgroup (Table 1). Sequences from the Marshall Islands specimens were not obtained likely due to their originally storage conditions.

Table 1. Specimens used for molecular analyses, including species, museum voucher, locality, and GenBank vouchers

Newly sequenced specimens are highlighted in bold. Institutional acronyms: Australian Museum (AM), California Academy of Sciences (CASIZ), Cal Poly Pomona research collections (CPIC), Bureau Waardenburg BV, Aquatic ecology, the Netherlands (FD), Natural History Museum of Los Angeles County (LACM), Museo Nacional de Ciencias Naturales (MNCN), Queensland Museum (QMMO), Zoological Museum, Moscow Lomonosov State University (ZMMU).

Molecular study

DNA extraction, amplification, and sequencing

DNA was extracted from a piece of foot tissue at the University of Cádiz, using Qiagen DNeasy Blood and Tissue Kit samples (Qiagen, Valencia, CA, USA). Partial sequences of Cytochrome Oxidase c subunit I (COI), 16S ribosomal RNA (16S) and histone H3 (H3) were amplified by polymerase chain reaction (PCR) using universal primers for invertebrates LCO1490 and HCO2198 for COI (Folmer et al., Reference Folmer, Black, Hoeng, Lutz and Vrijenhoek1994), 16S ar-L and 16S br-H for 16S (Palumbi et al., Reference Palumbi, Martin, Romano, Owen Macmillan, Stice and Grabowski1991) and H3AD5′3′ and H3BD5′3′ for H3 (Colgan et al., Reference Colgan, Mclauchlan, Wilson, Livingston, Edgecombe, Macaranas, Cassis and Gray1998). All PCRs were performed in 25 μl volume reactions. Each PCR was prepared using 2.5 μl Qiagen buffer (10x), 2.5 μl dNTPs (2 mM stock each of dATP, dGTP, dCTP, dTTP), 5 μl ‘Q-solution’ (5×), a gene-dependent amount of magnesium chloride (25 mM stock), 1 μl of each forward and reverse primer (10 μM stock), 0.025 μl Taq polymerase (1.25 units/μl)-Apex, and 2 μl DNA template. COI amplifications were performed with an initial denaturation for 3 min at 94°C, followed by 40 cycles of 30 s at 94°C, 30 s at 46°C (annealing temperature), and 1 min at 72°C, with a final extension of 5 min at 72°C. 16S amplification was performed with an initial denaturation of 5 min at 95.0°C, followed by 35 cycles of 30 s at 94.0°C, 30 s at 44.0°C (annealing temperature) and 1 min at 72.0°C with a final extension of 7 min at 72.0°C. H3 amplification was performed with an initial denaturation of 3 min at 95.0°C, followed by 40 cycles of 45 s at 94.0°C, 45 s at 50.0°C (annealing temperature), 2 min at 72.0°C with a final extension of 10 min at 72.0°C. Successful PCR products obtained were sequenced by Macrogen, Inc. All new sequences obtained were deposited in GenBank (Table 1).

Phylogenetic analyses

Sequences were assembled and edited using Geneious 11.1.4 (http://www.geneious.com, Kearse et al., Reference Kearse, Moir, Wilson, Stones-Havas, Cheung, Sturrock and Drummond2012). All sequences were tested for similarity with BLAST algorithm and aligned using MEGA7 (Kumar et al., Reference Kumar, Stecher and Tamura2016). Evolutionary models 16S and each codon position of COI and H3 were obtained using jModelTest2 on XEDE, CIPRES Science Gateway (Miller et al., Reference Miller, Pfeiffer and Schwartz2010), under Akaike information criteria (AIC) (Akaike, Reference Akaike1974). The models TrN + I, TPM1uf, HKY + G, were selected for first, second, and third codon position for COI. The evolutionary model for 16S was TPM3uf + G. For gene H3, TIM2 + I was selected for first codon position, JC for second codon position, and GTR + I + G for third codon position. Bayesian inference (BI) and maximum likelihood (ML) phylogenetic analyses were carried out using a matrix of individual gene and concatenated sequences, including COI-16S, COI-H3 and, 16S-H3 including all available sequences, COI + 16S + H3 with at least two genes per specimen, and COI + 16S + H3 using all sequences. BI analyses were performed using MrBayes on XSEDE, CIPRES Science Gateway (Miller et al., Reference Miller, Pfeiffer and Schwartz2010), for ten million generations, four independent runs, and a sampling frequency of 1000. Nodes with posterior probabilities ⩾0.96 were considered supported (Alfaro et al., Reference Alfaro, Zoller and Lutzoni2003). ML analyses were performed using RAxML-NG (Kozlov et al., Reference Kozlov, Darriba, Flouri, Morel and Stamatakis2019), using a Bootstopping cut-off of 0.03 implemented. ML nodes were considered statistically significant by bootstraps values ⩾75 (Hillis and Bull, Reference Hillis and Bull1993). All trees were rooted using the species Crimora lutea. Gene pairwise uncorrected P-distances for COI (Table 2), 16S (Table 3), and H3 (Table 4) were obtained using MEGA7 (Kumar et al., Reference Kumar, Stecher and Tamura2016). The resulting tree was visualised using FigTree (Rambaut, Reference Rambaut2009) and edited in Adobe Photoshop CC 2014.

Table 2. COI gene pairwise uncorrected P-distances (%) within and between species for comparison

Numbers in bold are mentioned in the text.

Table 3. 16S gene pairwise uncorrected P-distances (%) within and between species for comparison

Numbers in bold are mentioned in the text.

Table 4. H3 gene pairwise uncorrected P-distances (%) within and between species for comparison

Numbers in bold are mentioned in the text.

Morphological study

External morphology was studied at the Universidad Autónoma de Madrid using photographs of living animals and observations of preserved specimens under a stereomicroscope Nikon SMZ-1500 equipped with a camera lucida. Internal anatomy was studied by dissections. The animals were opened by a dorsal incision, and the reproductive system and buccal mass were removed. The buccal mass was dissolved in a 10% sodium hydroxide solution until the labial cuticle and radula had been cleaned from their surrounding tissue. These structures were then rinsed with water and examined and photographed under a light microscope using the Life Sciences Imaging software cellSense (v. 1.18). The reproductive system was drawn using a camera lucida, and the penis was isolated and opened so that it could be examined and photographed using the light microscope. The penises were not prepared for scanning electron microscope (SEM) due to their tiny sizes. The labial cuticles were critical point dried using hexamethyldisilazane. The radulae and labial cuticles were mounted on metallic stubs for SEM, and sputter coated with gold-palladium. Observations were made with a Hitachi S-3000 SEM-machine. This work has been registered under ZooBank Accession: urn:lsid:zoobank.org:pub:977248D2-B20F-414D-A4C4-44B5D0BA2D50.

Results

Phylogenetic analysis and species delimitation analysis

The molecular phylogenetic analysis included a total of 37 sequences for COI, 34 for 16S, and 19 for H3 (Table 1). The concatenated COI + H3 + 16S with all sequences included 44 taxa, while the same concatenated but with a minimum of two genes per specimen included 34 taxa (not shown because it does not include Paliota galactica). Since most of the newly sequenced specimens were only successful for a single gene, we provide the individual phylogenetic tree obtained with COI (Figure 1), and the single 16S, H3, concatenated COI-16S, and complete concatenated COI + H3 + 16S phylogenetic trees are shown as supplementary material (Figures S1, S2, S3, S4). Figure 1 and concatenated trees (Figures S3, S4) indicate high support of the monophyly of the family Polycerinae but the relationships between the genera remain unresolved. The genus Polycera was never rendered monophyletic; however, all the specimens of Polycera nimbsi sp. nov. clustered together with maximum support (PP = 1/BS = 100) (Figures 1, S3, S4), with a range of intraspecific variability for COI uncorrected pairwise genetic distance between 0.3 and 1.2% (Table 2). Paliolla templadoi is included in a clade containing L. capensis and Gymnodoris spp. (Figures 1, S3, S4). COI uncorrected pairwise genetic distances showed 18.43% difference between P. templadoi and P. galactica sp. nov., and 19.39‒19.47% between Palio dubia and Paliota gen. nov. (Table 2). A small clade containing Polycera quadrilineata, the type species of the genus, gathers P. norvegica Sørensen, Rauch, Pola & Malaquias, 2021, P. kernowensis Korshunova, Driessen, Picton & Martynov, 2021, and P. faeroensis Lemche, 1929 as sister to P. aurantiomarginata García-Gómez & Bobo, 1984 and P. capensis (Figures 1, S3, S4). COI uncorrected pairwise genetic distances among these species varies between 12.61‒13.37% (P. quadrilineata vs P. kernowensis) and 11.70‒12.75% (P. quadrilineata vs P. faeroensis) (Table 2).

Figure 1. Phylogenetic relationships (BI/ML) based on the mitochondrial COI gene marker. The family Polycerinae is highlighted with an orange spot. The newly sequenced specimens are in bold.

Systematics

Nudibranchia Cuvier, Reference Cuvier1817
Family POLYCERIDAE Alder and Hancock, Reference Akaike1845
Genus Palio Gray, Reference Gray1857
Palio gaeli sp. nov. (Figures 2A‒C, 3A, B, 4)
LSID urn:lsid:zoobank.org:act:99C9BE0D-E682-4E5C-9837-2929479A0B6D
Polycera sp. 8 in Gosliner et al. (Reference Gosliner, Valdés and Behrens2018): 29.

Diagnosis

Body ground translucent with numerous tubercles on the notum and the margins of the body. Numerous brown and black spots. Dense white pigmentation. Four small tuberculate velar processes. Three tripinnate trident-shape gill branches. Three small extra-branchial processes. 5‒7 rhinophoral lamellae. Many spicules embedded in the mantle. Radular formula 9 × 2(3).2.0.2.2(3). Very large prostate. Armed penis.

Figure 2. Photographs of living animals. A–C Palio gaeli sp. nov. A, C. MNCN 15.05/200208H; B. MNCN 15.05/200208P; photographs by S. Johnson. D–E Polycera nimbsi sp. nov. D, C.547846; photograph by M. Nimbs. E, C.547849; photograph by S.D.A. Smith.

Figure 3. Drawings of internal anatomy. A,B, buccal bulb and reproductive system of Palio gaeli sp. nov. C, D, buccal bulb, and reproductive system of Polycera nimbsi sp. nov. E, F, buccal bulb, and reproductive system of Paliota galactica sp. nov. Abbreviations: am, ampulla; bb, buccal bulb; bc, bursa copulatrix; fgm, female gland mass; hd, hermaphroditic duct; oe, oesophagus; pr, prostate; ra, radular sac; rs, receptaculum seminis; sgl, salivary gland; va, vagina; vd, vas deferens. Scale bars = 1 mm.

Figure 4. Scanning electron micrographs (SEM) and light microscope photographs (LMP) of Palio gaeli sp. nov. A, labial cuticle (MNCN 15.05/200208H) (LMP); B, detail of labial cuticle (MNCN 15.05/200208H) (LMP); C, complete radula (MNCN 15.05/200208H) (SEM); D, detail of inner and outer lateral teeth (MNCN 15.05/200208P) (SEM); E, detail of marginal teeth (MNCN 15.05/200208P) (SEM); F, detail of penial spines (MNCN 15.05/200208H) (LMP). Scale bars: A, 50 μm; B, 10 μm; C, 300 μm; D, 100 μm; E, 50 μm; F, 10 μm.

Material examined

Holotype. MNCN 15.05/200208H. Marshall Islands, Kwajalein Atoll, Eller U pinnacle, under dead coral with eggs, 9 mm alive, 16 September 2013, col. by S. Johnson. Originally preserved in 70 isopropyl. Dissected (SEM: radula, labial cuticle). Paratype. MNCN 15.05/200208P. Marshall Islands, Kwajalein Atoll, Eller U pinnacle, under dead coral with eggs, 9 mm alive, 16 September 2013, col. by S. Johnson. Originally preserved in 70% isopropyl alcohol. Dissected (SEM: radula, labial cuticle).

Etymology

The species is named after Gael Pola, nephew of the first author of this paper. Also, in the Celtic language, ‘gaelico’ means ‘from the islands’.

External morphology (Figure 2A‒C)

Body elongated, limaciform. Body surface smooth but apparently rough in texture due to presence of differently sized tubercles located on dorsal and lateral parts of body. Medium-sized tubercles mark mantle edge, from anterior part of head to behind gill, where they join and run as a ridge to end of tail. Large tubercles also form a longitudinal line on either side of body. Four frontal veil processes short, rounded; two larger in central area and two smaller on each side. Elongated and cross-shaped spicules evenly distributed throughout body, within mantle. Rhinophores perfoliate with 5‒7 lamellae, lacking sheaths. Oral tentacles not clearly observed. Gill non-retractile into pocket, with three long tripinnate gill branches that surround anterior part of anus. Gill semi-circular and large compared to body, characterised by trident shape. Three small lobed extra-branchial process on each side of gill, the closer to gill larger than the others. Foot long, narrow, slightly widened anteriorly, with two propodial tentacles in its anterior end. Genital opening on right side, closer to rhinophores than to gills.

Colour pattern (Figure 2A‒C)

Translucent body with small, pale brown and black spots dispersed evenly throughout. Black spots mostly arranged on tubercles, while gill branches and rhinophores bare mostly pale brown spots. Dense white pigmentation observed in most tubercles and outer rachises of gill branches. This colouration delimits edge of notum accompanying tubercles from cephalic part to end of tail. Dense white pigmentation also forms diamond-shaped patch behind rhinophores on middorsal line.

Internal anatomy (Figures 3A, 4A‒E)

Oral tube slightly larger than buccal bulb. Pair of elongate, granular salivary glands attached at each side of oesophagus where it enters buccal bulb (Figure 3A). Labial cuticle large, robust, with two large elongated lateral wings; inner part of wings and central area with delicate rods and striations (Figure 4A, B). Radular formula 9 × 2(3).2.0.2. 2(3). Rachidian tooth absent (Figure 4C). All laterals elongated, hamate, with strong prominent distal cusp; inner lateral smaller, with narrow base and triangular, spatulate distal cusp. This distal cusp has a small protrusion on its outer margin (Figure 4C, D), outer laterals larger, more than twice size of inner laterals; both laterals with hook-shaped wing-like expansion which is sharper on inner laterals. Marginal teeth smaller, flat, plate-like, pseudo-rectangular, decreasing in size outward (Figure 4E). Last marginal very small, only visible in some rows (Figure 4E).

Reproductive system (Figures 3B, 4F)

Triaulic; hermaphroditic duct elongate, thin. Ampulla small, sausage-shaped; post-ampullary duct not seen. Prostate gland very large, narrowing towards distal vas deferens. Penis armed with numerous hooked-shaped spines (Figure 4F). Vaginal duct elongated, bent, same length as vas deferens but wider, ending in large oval bursa copulatrix. Bursa copulatrix connects to small, rounded receptaculum seminis by a very long and conspicuous duct, emerging from approximately the halfway point of the length of the vagina. Short uterine duct emerging close to vagina, entering female gland.

Distribution

Marshall Islands (present study) and the Philippines (Gosliner et al., Reference Gosliner, Valdés and Behrens2018).

Remarks

This species is very easy to distinguish from any other described Palio by its external morphology and colour pattern (Sars, Reference Sars1829; Pease, Reference Pease1871; O´Donoghue, Reference O'Donoghue1924; Baba, Reference Baba1960; Behrens, Reference Behrens1991; Picton and Morrow, Reference Picton and Morrow1994; Martynov et al., Reference Martynov, Sanamyan and Korshunova2015). The background colour of Palio amakusana Baba, Reference Baba1960 and P. dubia (Sars, Reference Sars1829) is yellowish brown, while it is pale cream ornamented with small orange yellow papillae in P. gracilis (Pease, Reference Pease1871), greenish black varied with chestnut and green and covered with irregular spots of a pale -yellow or fawn-colour in P. nothus (G. Johnson, 1838), translucent with microscopic brown specks sometime sparse but usually quite dense in P. zosterae (O´Donoghue, Reference O'Donoghue1924), and olive green or pale brown in P. ionica Korshunova, Sanamyan & Martynov, 2015. In addition, P. amakusana, P. dubia, P. zosterae, and P. nothus have five tripinnate gill branches, P. ionica has four or five, and P. gracilis has eight very small arborescent branches. However, our specimens only have three large gill branches, and with a very characteristic trident shape. The number and shape of the frontal papillae are also different among species, being small lobes in P. amakusana (12‒14), P. dubia (8), P. nothus (several), P. zosterae (several), and P. gaeli sp. nov. (4), while they are quite long in P. gracilis (8). They are unknown in P. ionica since the description is very incomplete and there is no photograph or drawing of the specimen (Martynov et al., Reference Martynov, Sanamyan and Korshunova2015). Finally, the number of extra-branchial appendages on each side of the gill is also important. There are four to six in P. amakusana, five in P. dubia, two or three in P. nothus and five or six in P. zosterae., The extra-branchial processes are not described or drawn in the original work of P. gracilis although there is a large number of tentacular processes in the margin and dorsal areas. This feature is also unknown for P. ionica. Our specimens have three lobed appendages, the one closest to the gill larger than the others. These appendages are difficult to distinguish due to the colouration and the rest of the tubercles that are present on the notum and margins. Regarding internal anatomy, it is very difficult to compare species since most lack this information (Sars, Reference Sars1829; Pease, Reference Pease1871; O´Donoghue, Reference O'Donoghue1924; Baba, Reference Baba1960; Martynov et al., Reference Martynov, Sanamyan and Korshunova2015). Unfortunately, we were not able to obtain sequences for these specimens from Marshall Islands, likely because of its original fixative. However, all these features described above make Palio gaeli sp. nov. be very easy to differentiate from the other species of Palio and the remaining genera of the subfamiliy Polycerinae.

Genus Polycera Cuvier, Reference Cuvier1816
Polycera nimbsi sp. nov. (Figures 2D, E, 3C, D, 5)
LSID urn:lsid:zoobank.org:act:39988A8E-BF43-4D7B-BC2A-038A37FDBA19

Diagnosis

Different colour morphs. Notal margin with medium-sized pointed tubercles. 4‒6 velar processes elongated. No extra-branchial appendages. Large, robust labial cuticle with lateral wings and stretch marks. Typical Polycera radula. Cup-shaped structure indicating end of prostatic section. Penis armed with two types of spines.

Figure 5. Scanning electron micrographs (SEM) and light microscope photographs (LMP) of Polycera nimbsi sp. nov. A, labial cuticle (MNCN 15.05/200210); B, detail of labial cuticle (AM C.547846) (SEM); C, section of radula at rows 3–7 (MNCN 15.05/200210) (SEM); D, detail of a row of teeth (AM C.547846) (SEM); E, penial spines located more proximal to base (AM C.547848) (LMP); F, penial spines located distally (AM C.547848) (LMP); Scale bars: A, 500 μm; B, 50 μm; C, 200 μm; D, 100 μm; E, 50 μm; F, 50 μm.

Material examined

Holotype. AM C.547846, Australia, New South Wales, Nelson Bay, Port Stephens, 6 mm preserved, 12 September 2015, col. by M. Nimbs. Dissected (SEM: radula, labial cuticle) and sequenced (COI, 16S). Paratypes. AM C.547847, Australia, New South Wales, Nelson Bay, Port Stephens, 6 mm preserved, 12 September 2015, col. by M. Nimbs. Dissected and sequenced (H3). AM C.547848, Australia, New South Wales, Nelson Bay, Port Stephens, 5 mm preserved, 12 September 2015, col. by M. Nimbs. Dissected (SEM: radula, labial cuticle) and sequenced (COI). QM MO 86041. Australia, New South Wales, Fly Point, 4 mm preserved, 11 March 2017, col. by M. Nimbs. Dissected (SEM: radula, labial cuticle) and sequenced (COI, H3). AM C.547849, Australia, New South Wales, Low Reef, 4 mm preserved, 04 December 2014, col. by S.D.A. Smith. Dissected (SEM: radula, labial cuticle) and sequenced (COI). All the specimens preserved in 96% EtOH.

Etymology

The species is named after Matt Nimbs, who collected and photographed this species, in gratitude for always being willing to help.

External morphology (Figure 2D, E)

Body elongated, limaciform, wrinkled due to presence of numerous small conical tubercles all over body. Notal margin with low crest that enlarges anteriorly into oral veil. Notal margin with medium-sized pointed tubercles. Anterior margin of head expanded with frontal veil bearing 4–6 elongated velar processes. Small oral tentacles. Rhinophores perfoliate with nine lamellae, lacking sheaths, tips smooth. Gill non-retractile into pocket, surrounding anus in semi-circle. Five or six bipinnated gill branches, central branch longer than posteriors. Genital opening on right side of body.

Colour pattern (Figure 2D, E)

Two different colour morphs may be present. (1) Beige with brownish marbled pattern, including velar processes, oral tentacles, and gill branches. Dark lamellae, yellowish on the upper part. Notum with dense bright white spots (Figure 2D). (2) Orangish to pale brownish with dense minute bright white spots scattered on notum and notal margin, also on velar processes and gill branches. Velar processes, oral tentacles, outer side of gill branches, most of lamellae and tip of rhinophores black, and all these structures with yellowish in some upper areas (Figure 2E). There is probably also a third colour morph, as in the photograph taken by M. Nimbs at Serenity Bay (Solitary Islands Marine Park), NSW, Australia, in 2016, (https://www.flickr.com/photos/128938954@N03/31440861523/in/photostream/) that shows a specimen very similar to ours but with olive colouration and much more white pigment dorsally.

Internal anatomy (Figures 3C, 5A–D)

Oral tube smaller than buccal bulb. Pair of elongate, granular salivary glands attached at each side of oesophagus where it enters buccal bulb (Figure 3C). Labial cuticle large, robust with two large and elongated lateral wings, with stretch marks (Figure 5A, B). Radular formula 12 × 3.2.0.2.3, rachidian tooth absent (Figure 5C). Outer lateral larger, thicker than inner; all laterals with hook-shaped wing-like expansion; wing-like expansion less prominent on inner laterals. Outer lateral elongated, hamate, with strong prominent distal cusp; inner lateral with narrow base and triangular, spatulate distal cusp (Figure 5C, D). Marginal teeth smaller, flat, plate-like, pseudo-rectangular, decreasing in size outward (Figure 5C, D).

Reproductive system (Figures 3D, 5E, F)

Triaulic; hermaphroditic duct elongate, thin. Ampulla small, kidney-shaped; post-ampullary duct bifurcating into short oviduct leading to large female gland mass and vas deferens through prostrate portion. Prostate small, kidney-shaped narrowing towards distal vas deferens. In its original position, prostate surrounds bursa copulatrix. Inside vas deferens a cup-shaped structure indicates end of prostatic section. Vas deferens short, narrow. Penial bulb reduced. Penis armed with two types of chitinous spines; spines closest to prostate more elongate; spines closest to genital opening hook-shaped (Figure 5E, F). Vaginal duct elongated, slightly bent, longer and wider than vas deferens. Vagina ends in large oval bursa copulatrix. Bursa copulatrix connects to large, oval receptaculum seminis by a very long, and thin duct, emerging from about half length of vagina. Long and thin uterine duct emerging past length of duct, entering female gland.

Distribution

New South Wales, Australia (present study).

Remarks

In our phylogenetic analysis, the genus Polycera is not supported as monophyletic, as was the case in analyses previously carried out by other authors (Palomar et al., Reference Palomar, Pola and García-Vazquez2014; Sorensen et al., Reference Sørensen, Rauch, Pola and Malaquias2020; Knutson and Gosliner, Reference Knutson and Gosliner2022). However, although Polycera is not supported, P. nimbsi sp. nov. always appears in clades containing other Polycera species (Figures 1, S1‒S4), and its morphological features agree with the mix of characters known for other species described to date (Miller, Reference Miller1996). In Figure S2 (H3 single gene) the new genus described below (Paliota gen. nov.) also falls within a cluster with other Polycera species. This could be explained because it is an artefact of having too few sequences included in this analysis. But looking at Table 4, the H3 uncorrected pairwise genetic distance between P. nimbsi sp. nov. vs P. galactica sp. nov. is 8.54%, which is less than the percentages found between P. nimbsi sp. nov. and P. alabe (9.76), and P. abei and P. atra (10.67). However, these three Polycera spp. never cluster with the clade containing the type species P. quadrilineata, which in fact could mean that they need to be transferred to another genus. At this point, we need a more robust and complete phylogeny to make this taxonomic decision. COI uncorrected pairwise genetic distance between P. nimbsi sp. nov. and P. galactica sp. nov. is 19.89‒20.55 (Table 2), higher than with any other Polycera spp. A comparison of the uncorrected pairwise genetic distances for each gene is shown in Tables 24 (COI, 16S, and H3, respectively).

Thus, until the phylogeny of the Polycerinae is better resolved, including the maximum number of species and the largest number of genes possible, we will always be left wondering if we are not making mistakes when assigning this species to the genus Polycera. In this study, we have decided to make that decision based on the presence of long velar appendages, a diagnostic character at this time for the genus. That, together with the radula, its union with other Polycera species in the phylogenetic trees, and the comparison of the uncorrected pairwise genetic distances of all three genes, makes us think that we are making the right decision. Regarding the two-colour forms described here, the range of intraspecific variability for COI uncorrected pairwise genetic distance is between 0.3 and 1.38, allowing us to be confident in our description (Table 2).

Of all the Polycera species recorded throughout the Indo-Pacific and Australia in particular, none are similar to P. nimbsi sp. nov. P. capensis, P. hedgpethi, P. janjukia, P. melanosticta, P. risbeci, and P. parvula all differ in colouration from the two described colour morphs of P. nimbsi sp. nov. Additionally, the new species lacks extra-branchial processes present in P. capensis and P. hedgpethi. Regarding P. melanosticta, Miller (Reference Miller1996: 445) described its colouration as ‘white, translucent, grey or greyish brown all over subepidermally, sometimes very dense, opaque white spherules within bases of papillae; black pigment, evenly and widely spaced over surface of body, on terminal knob, lamellae of rhinophores, outer face of gills at tip and base, lightly on inner face, tip of tail and middle section of foot angles; orange pigment in between base of velar processes and subterminally on tail, i.e. anterior of black patch, on lower rhinophore lamellae and stalk, middle section of outer face of gills, upper surface of base of foot angles, anterior foot groove; sole of foot pigmentless; viscera showing through yellowish brown.’. Clearly, although with a few similarities, this description differs from P. nimbsi sp. nov. Internally, the radulae are very similar, but there are substantial differences in the reproductive system; the bursa copulatrix and, above all, the seminal receptacle of P. melanosticta are very small compared to those of P. nimbsi sp. nov. Also, the vagina and oviduct are very short in P. melanosticta (Miller, Reference Miller1996), while in the species described here those ducts are much longer. Moreover, P. melanosticta lacks the spherical thickening of the vas deferens characteristic of P. nimbsi sp. nov. Figure S1 shows that these two species are closely related, but with an uncorrected pairwise genetic distance of 2.4 between them for 16S (Table 3). As shown in Table 3 for 16S, the differentiation between species in this gene can be considered from 1.55 (P. capensis vs P. aurantiomarginata).

Paliota gen. nov.

Diagnosis

Body elongated, limaciform, with distinct marginal ridge and tubercles. Medium size digitate velar processes, rhinophores perfoliate lacking rhinophoral sheaths; gill branches bipinnate and not retractile; extra-branchial processes absent. Prominent jaws. Labial cuticle with wing-like processes. Radula tubiform in its original position, teeth forming an enclosed structure. Inner lateral teeth scythe-shaped, smooth, elongated, and wide, tapering to tip. Prostate very well developed. Penis armed.

Etymology

The generic name Paliota is a play on words to highlight the resemblance to related genera such as Palio, Paliolla, and Polycera, within the Polycerinae.

Paliota galactica sp. nov. (Figures 3E, F, 6A–C, 7)

LSID urn:lsid:zoobank.org:act:5EF65DF5-AEC9-4C4B-BF27-5739532CDFB1

Figure 6. Photographs of living animals. A-C. Paliota galactica sp. nov. A, B, AM C.547850; C, AM C.547851; photographs by D. Harasti. D. Paliolla templadoi (MNCN 15.05/94863); photograph by M. Pola.

Figure 7. Scanning electron micrographs (SEM) and light microscope photographs (LMP) of Paliota galactica sp. nov. A, labial cuticle (AM C.547850); B, detail of labial cuticle (MNCM 15.05/200209) (SEM); C, view of radula (AM C.547851) (SEM); D, detail of lateral teeth (AM C.547851) (SEM); E, detail of marginal teeth (MNCM 15.05/200209); F, penial spines (AM C.547851) (LMP). Scale bars: A, 500 μm; B, 100 μm; C, 100 μm; D, 50 μm; E, 50; F, 10 μm.

Polycera sp. in Coleman (Reference Coleman2008): 360

Material examined

Holotype. AM C.547850, Australia, New South Wales, Nelson Bay, 7 m depth, 4 mm preserved, November 2014, col. by D. Harasti. Dissected (SEM: radula, labial cuticle) and sequenced (16S). Paratypes. AM C.547850, Australia, New South Wales, Nelson Bay, 7 m depth, 4 mm preserved, 05 October 2014, col. by D. Harasti. Dissected (SEM: radula, labial cuticle) and sequenced (COI). QM MO 86040, Australia, New South Wales, Nelson Bay, 7 m depth, 3 mm preserved, 05 October 2014, col. by D. Harasti. Dissected (SEM: radula, labial cuticle) and sequenced (H3). All specimens preserved in 96% EtOH.

Etymology

The specific epithet refers to a galaxy due to the colour pattern of the species.

External morphology (Figure 6A‒C)

Body elongated, limaciform, with distinct marginal ridge; highest at middle length: slightly constricted laterally between head and mid-region; notum with uneven appearance due to presence of tubercles. Ten tubercles aligned along mantle rim, larger than those dispersed all over remaining body. Anterior margin of head expanded with frontal veil bearing six digitate medium-size velar processes. Rhinophores perfoliate with eight lamellae, lacking sheaths. Gill non-retractile into pocket, with eight bipinnate branches surrounding anus in semi-circle. Foot forms two propodial tentacles at its anterior end. Inner side of notum covered by long spicules. Numerous small white or orangish granules arranged irregularly in this area, constituting in some parts circle-shaped concentrations. Genital pore darkly pigmented and located on the right side, very close under rhinophore.

Colour pattern (Figure 6A–C)

Notum translucent to pale cream or orange; dark brown stains all over body creating an irregular pattern. Tubercles translucent white; many tiny bright white dots scattered all over the mantle. Rhinophores stalks same colour pattern as notum with banded yellow, black, and yellow lamellae with a translucent tip. Outer rachises of the gill branches dark brown with yellow tips, inner plumes whitish. Oral tentacles and end of tail coloured dark and yellow as rhinophores and gill.

Internal anatomy (Figures 3E, 7A–D)

Oral tube very short, not muscular. Buccal bulb much larger than oral tube, with two very prominent brownish jaws that project back to sides of buccal bulb (Figure 3E). Granular droplet-shaped salivary glands at each side of oesophagus where it enters buccal bulb (Figure 3E). Labial cuticle with two elongated downwards wing-like processes; fine striations present at edges (Figure 7A, B). Peculiar radula, tubiform in its original position. At first view, number and shape of rows make it impossible to formulate a normal radula. Teeth form a closed structure, all facing inward, overlapping each other (Figure 7C, D). Radular formula approximately 19 × (2)1.2.0.2.1(2). Rachidian teeth absent (Figure 7C, D). Two lateral teeth with scythe-shape, being smooth, elongated, and wide, tapering to tip (Figure 7C, D). Both laterals very similar in size; second inner tooth appears to have a small cusp near its base. Marginal teeth are one or two small plates. First one easy to locate (Figure 7C, D), but second is not appreciated in all rows and specimens due to its small size (Figure 7E).

Reproductive system (Figures 3F, 7F)

Triaulic. Long, thin, hermaphroditic duct connects with hazelnut-shaped ampulla. Short post-ampullary duct emerges from ampulla, which branches on one side into prostate, and on other side into small duct that enters female gland. Prostate very well developed, long and wide narrowing to vas deferens (Figure 3F). End of vas deferens with small penis, armed with four longitudinal rows of small hook-shaped spines (Figure 7F). Vagina long, narrow, ending in bursa copulatrix large and rounded. From vagina, before reaching bursa copulatrix, a large and conspicuous duct leads into pyriform seminal receptacle, smaller than bursa copulatrix. Finally, uterine duct leaves seminal receptacle to enter female gland.

Distribution

Australia: New South Wales (present study) and Victoria (Coleman, Reference Coleman2008).

Remarks

The new genus described here has a unique and different anterior part of the digestive system from the other Polyceridae genera. Since Paliolla is the only other Polycerinae genus with an unusual pharynx (Burn, Reference Burn1975; Ortea, Reference Ortea1989; Ortea et al., Reference Ortea, Rolán and Valdés1992), we first thought that we had found a third species belonging to that genus. However, there are several significant differences. In our specimens, the oral tube is much smaller than the buccal bulb and the latter is surrounded by two very prominent brown jaws (Figure 3E). These jaws are large, elongate, and very difficult to miss if present, as they surround the bulb on both sides, and are very robust and dark brown in colour. For the two species of Paliolla described, the presence of jaws is not mentioned (Angas, Reference Angas1864; Burn, Reference Burn1958; Ortea, Reference Ortea1989; Ortea et al., Reference Ortea, Rolán and Valdés1992), while for Palio, Baba (Reference Baba1960) and Miller (Reference Miller1996) describe them as triangular. However, we think, based on the drawing by Baba (Reference Baba1960: Pl. VI, Figure 2B) that the author was referring to the labial cuticle. This nomenclatural confusion also occurs in Polycerella, where jaws are described as oval for P. glandulosa by Behrens and Gosliner (Reference Behrens and Gosliner1988) but, in fact, the authors refer to the labial cuticle. Polycera species also lack distinct jaws (Sørensen et al., Reference Sørensen, Rauch, Pola and Malaquias2020). Additionally, the salivary glands are much smaller than those described to P. cooki by Burn (Reference Burn1975). Regarding teeth, Burn (Reference Burn1958, Reference Burn1975: 109, Figures 2, 3) described them as ‘needle-like in shape with slender compressed base. Each tooth rising from a separate socket and not connected by or joined to a chitinous odontophoral ribbon’. This description and the one by Ortea (Reference Ortea1989) do not match with our specimens since although at first sight the teeth appear as a closed structure, after careful observation rows can be seen (Figure 7C, D). Inner laterals are elongate but far from being needle-like, and instead they are very wide and blade-like. Moreover, one or two small outer plates can be distinguished, which are absent in P. cooki (Burn, Reference Burn1975) and they are very different from the ones described by Ortea et al. (Reference Ortea, Rolán and Valdés1992) for P. templadoi. There are also some differences in the reproductive systems as described by Burn (Reference Burn1975) and Ortea et al. (Reference Ortea, Rolán and Valdés1992). Ortea et al. (Reference Ortea, Rolán and Valdés1992) described a vestibular gland that is not present in the new genus, and in Burn´s description, the position of the receptaculum seminis appears much closer to the prostate than to the vagina. Finally, COI pairwise distances between the new genus and P. templadoi is 18.43 (Table 2). For all the reasons mentioned above, we are confident that this species belongs to a new genus herein described, for which the major synapomorphies are the large brown jaws and the peculiar tubiform radula with scythe-shaped lateral teeth.

Discussion

The family Polycerinae clearly needs to be studied in more depth. Although its monophyly was confirmed by Pola et al. (Reference Pola, Sánchez-Benítez and Ramiro2014) and Sørensen et al. (Reference Sørensen, Rauch, Pola and Malaquias2020), it is true that not all the genera or species that constitute it were included. In fact, when Knutson and Gosliner (Reference Knutson and Gosliner2022) included an undescribed species of Vayssierea Risbec, 1928 (currently included in Okadaiidae Baba, 1930) in their phylogenetic study of Gymnodoris, it appeared within Polycerinae, albeit with a very long branch. We also included it in the preliminary analysis, but since it is not described (not confirmed morphologically) and with such a distant branch, we decided not to include it in our analysis. Once again, in Knutson and Gosliner (Reference Knutson and Gosliner2022), some other genera and most of the species in the subfamily were not studied. For example, Lamellana has never been included in a phylogenetic framework, since it has never been found since its original description, and just recently, Lecithophorus Macnae, Reference Macnae1958 was sequenced for their study (Knutson and Gosliner, Reference Knutson and Gosliner2022). In our study, for the first time we include a species of Paliolla in the phylogeny (Figure 1), as well as the first colour photograph of an individual of P. templadoi alive (Figure 6D). In all previous studies, the relationships between the genera were not defined and, it should be repeated that Polycera was never recovered as monophyletic.

There are some morphological characteristics that can help us to separate the genera: starting with the easiest, Lamellana and Lecithophorus both lack a radula and have a smooth body, the mantle is reduced, and there are no processes. However, L. gymnota was described from Hong Kong with ‘yellowish, back flecked black and yellow around the branchiae’ (Lin, Reference Lin1992: 182), while L. capensis is ‘translucent white and the internal organs may be seen shining through as brownish areas. Pale lemon-yellow patches indicate the position of the buccal mass and gonad’ (Macnae, Reference Macnae1958: 362). Whereas Lecithophorus has many spicules embedded in its skin, there is no mention of spicules in Lamellana (Macnae, Reference Macnae1958; Lin, Reference Lin1992). Gymnodoris is easy to distinguish from species of other Polycerinae genera by its predatory trophic behaviour. Its species prey upon other nudibranchs and thus, its radula has many more outer lateral teeth than in the other genera (Knutson et al., Reference Knutson, Gosliner and Williams2011). Regarding ‘Polycera’, Palio, Polycerella, and Thecacera, they all have quite similar radular teeth and formulae, but there are some features that allow us to differentiate between some of them. Thus, Thecacera species are very easy to distinguish since they have well-developed rhinophoral sheaths (Baba, Reference Baba1960; Fischer, Reference Fischer2006). Species of Palio are small and do not have elongated appendages either on the oral veil or as extra-branchial processes. Instead, their velar processes are small and tuberculate, and the extra-branchial processes are small and lobed, these being the main differences with Polycera (Gray, Reference Gray1857; Baba, Reference Baba1960; Rudman, Reference Rudman2003). Additionally, Rivest (Reference Rivest1984) argued that the differences in reproductive anatomy support the case for considering Palio to be a genus distinct from Polycera. Polycerella species have more rows of teeth than Polycera, despite its radula being smaller. Both radulae also differ in the shape of their teeth (Verrill, Reference Verrill1880; Behrens and Gosliner, Reference Behrens and Gosliner1988; Miller, Reference Miller1996). Finally, Paliolla, as stated in the introduction, is unmistakable by its unusual radula with acicular teeth forming a tube (Burn, Reference Burn1958; Ortea, Reference Ortea1989; Ortea et al., Reference Ortea, Rolán and Valdés1992) but, as discussed under Remarks, clearly different from Paliota gen. nov. The main problem continues to be the genus Polycera, as the combination of traits within the genus and the lack of support for its monophyly make the species difficult to diagnose. However, one interesting fact is that the species clustering in Figure 1 (that includes the type species) are those having large and elongated oral veil and extra-branchial processes.

Conclusions

The biodiversity of the subfamily Polycerinae, as well as the phylogenetic relationships within the family Polyceridae, need further studies. One new species of Palio, one new species of Polycera, and a new genus are described in this work based on external and internal features, supported by molecular analysis. More fresh specimens and taxonomical studies are necessary to fully understand the richness and evolution of this diverse and poorly studied family of nudibranchs.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0025315423000607

Acknowledgements

We are very grateful to Scott Johnson, Matt Nimbs, Dave Harasti, Tom Davis, and Stephen Smith, without whose invaluable help collecting specimens, this and many other works that help describe the planet's biodiversity would not have been possible. We are also grateful to Mandy Reid and Alison Miller from the Australian Museum and Darryl Potter from Queensland Museum for lending us the specimens for study. We are also indebted to the three referees who helped us improve our manuscript.

Authors’ contributions

M. P. designed and carried out the study, analysed data, interpreted the results, and wrote the manuscript. M. M. G. analysed data and helped write and format the manuscript. S. P. S. analysed data, helped to carried out the study, interpreted the results, and helped write the manuscript.

Financial support

The molecular work was performed at the University of Cádiz, supported by the research project CGL2010-17187/BOS funded by the Spanish Ministry of Economy to Juan Lucas Cervera (and Marta Pola as collaborator). This work was also partially supported by Research Grant of the Department of Biology 2020, Universidad Autónoma de Madrid (BIOUAM04-2020).

Competing interest

None.

References

Akaike, H (1974) A new look at the statistical model identification. IEEE Transactions on Automatic Control 19, 716723.CrossRefGoogle Scholar
Alder, J and Hancock, A (1845) Notice of a new genus and several new species of nudibranchiate Mollusca. Annals and Magazine of Natural History 16, 311316.CrossRefGoogle Scholar
Alfaro, ME, Zoller, S and Lutzoni, F (2003) Bayes or bootstraps? A simulation study comparing the performance of Bayesian Markov chain Monte Carlo sampling and bootstrapping in assessing phylogenetic confidence. Molecular Biology and Evolution 20, 255266.CrossRefGoogle ScholarPubMed
Angas, GF (1864) Description d'espèces nouvelles appartenant à plusieurs genres de Mollusques Nudibranches des environs de Port-Jackson (Nouvelle-Galles du Sud), accompagnée de dessins faits d'après nature. Journal de Conchyliologie (3e série—Tome IVe) 12, 4370, pls. IV-VI.Google Scholar
Baba, K (1960) The genera Polycera, Palio, Greilada and Thecacera from Japan (Nudibranchia-Polyceridae). Publications of the Seto Marine Biological Laboratory 8, 7578.CrossRefGoogle Scholar
Behrens, DW (1991) Pacific Coast Nudibranchs: A Guide to the Opisthobranchs, Alaska to Baja California, vi + 107 pp., 217 Photos, 2nd Edn., Monterey, California: Sea Challengers.Google Scholar
Behrens, DW and Gosliner, TM (1988) The first record of Polycerella Verrill, 1881, from the Pacific, with the description of a new species. Veliger 30, 319324.Google Scholar
Burn, R (1958) Further Victorian Opisthobranchia. Journal of the Malacological Society of Australia 1, 2036.CrossRefGoogle Scholar
Burn, R (1975) Notes on Paliolla cooki (Angas, 1894) from Southern Australia (Opisthobranchia: Gymnodorididae). Journal of the Malacological Society of Australia 3, 107110.CrossRefGoogle Scholar
Burn, R (2006) A checklist and bibliography of the Opisthobranchia (Mollusca: Gastropoda) of Victoria and the Bass Strait area, south-eastern Australia. Museum Victoria Science Report 10, 142.CrossRefGoogle Scholar
Burn, R (2015) Nudibranchs and Related Molluscs. Melbourne: Museum Victoria.Google Scholar
Coleman, N (2008) Nudibranchs Encyclopedia. Springwood, Queensland: Neville Coleman's Underwater Geographic, 360 pp.Google Scholar
Colgan, DJ, Mclauchlan, A, Wilson, GD, Livingston, SP, Edgecombe, GD, Macaranas, J, Cassis, G and Gray, MR (1998) Molecular phylogenetics of the Arthropoda: relationships based on histone H3 and U2 snRNA DNA sequences. Australian Journal of Zoology 46, 419437.CrossRefGoogle Scholar
Cuvier, G (1816 [“1817”]) Le règne animal distribué d'après son organisation, pour servir de base à l'histoire naturelle des animaux et d'introduction à l'anatomie comparée. [Work generally dated 1817; published before 2 December 1816 according to Roux. Journal of the Society for the Bibliography of Natural History 8, 31, Tome 1, 540 pp.; Tome 2, 528 pp.; Tome 3, 653 pp.; Tome 4, 255 pp., 15 pl. Deterville, Paris.Google Scholar
Fischer, MA (2006) Opistobranchs From the Chilean Coast. Santiago, Chile: Universidad de Nijmegen.Google Scholar
Folmer, O, Black, M, Hoeng, W, Lutz, R and Vrijenhoek, R (1994) DNA primers for amplification of mitochondrial cytochrome c oxidase subunit I from diverse metazoan invertebrates. Marine Biotechnology 3, 294299.Google ScholarPubMed
Gosliner, TM (1987) Nudibranch of Southern Africa. A Guide to Opisthobranch Molluscs of Southern Africa. Monterey, California: Se Challengers.CrossRefGoogle Scholar
Gosliner, TM, Valdés, A and Behrens, DW (2018) Nudibranch and Se Slug Identification Indo-Pacific. Nudibranch and Se Slug Identification Indo-Pacific. Jacksonville, Florida: New World Publications Inc.Google Scholar
Gray, JE (1857) Guide to the Systematic Distribution of Mollusca in the British Museum. London: Cornell University Library.Google Scholar
Hillis, DM and Bull, JJ (1993) An empirical test of bootstrapping as a method for assessing confidence in phylogenetic analysis. Systematic Biology 42, 182192.CrossRefGoogle Scholar
Kearse, M, Moir, R, Wilson, A, Stones-Havas, S, Cheung, M, Sturrock, S, Buxton S, Cooper A, Markowitz S, Duran C, Thierer T, Ashton B, Meintjes P and Drummond, A (2012) Geneious basic: an integrated and extendable desktop software platform for the organization and analysis of sequence data. Bioinformatics (Oxford, England) 28, 16471649.Google ScholarPubMed
Knutson, VL and Gosliner, TM (2022) The first phylogenetic and species delimitation study of the nudibranch genus Gymnodoris reveals high species diversity (Gastropoda: Nudibranchia). Molecular Phylogenetics and Evolution 171, 107470.CrossRefGoogle ScholarPubMed
Knutson, VL, Gosliner, TM and Williams, GC (2011) Three new species of Gymnodoris Stimpson, 1855 (Opisthobranchia: Nudibranchia) from Philippines. The Coral Triangle, 129142.Google Scholar
Kozlov, AM, Darriba, D, Flouri, T, Morel, B and Stamatakis, A (2019) RaxML-NG: a fast, scalable, and user-friendly tool for maximum likelihood phylogenetic inference. Bioinformatics (Oxford, England) 25, 44534455.Google Scholar
Kumar, S, Stecher, G and Tamura, K (2016) MEGA7: molecular evolutionary genetics analysis version 7.0 for bigger datasets. Molecular Biology and Evolution 33, 18701874.CrossRefGoogle ScholarPubMed
Lin, G-Y (1992) Three new species of Opisthobranchia from Hong Kong. In: B. Morton, ed. Proceedings of the fourth international Marine Biological Workshop: The marine flora and fauna of Hong Kong and southern China III, Hong Kong, 11–29 April 1989. Volume 1: Introduction, Taxonomy and Ecology: 181–186. Hong Kong University Press.Google Scholar
Macnae, W (1958) The families Polyceridae and Goniodorididae (Mollusca, Nudibranchiata) in Southern Africa. Transactions of the Royal Society of South Africa 35, 341372.CrossRefGoogle Scholar
Martynov, A, Sanamyan, N and Korshunova, T (2015) [in Russian] review of the opisthobranch mollusc fauna of Russian far eastern seas: Pleurobranchomorpha, Doridida and Nudibranchia. Bulletin оf Kamchatka State Technical University 34, 6287.CrossRefGoogle Scholar
Miller, MC (1996) A new species of the Dorid nudibranch genus Polycera Cuvier, 1816 (Gastropoda: Opisthobranchia) from New Zealand. Proceedings of the Malacological Society of London 62, 443450.Google Scholar
Miller, MA, Pfeiffer, W and Schwartz, T (2010) Creating the CIPRES Science Gateway for inference of large phylogenetic trees. In: Proceedings of the Gateway Computing Environments Workshop (GCE). New Orleans, Louisiana, USA, 18.CrossRefGoogle Scholar
MolluscaBase (eds) (2023a) MolluscaBase. Polyceridae Alder and Hancock, 1845. Accessed through: World Register of Marine Species at: https://www.marinespecies.org/aphia.php?p=taxdetailsandid=177 on 2023-03-17.Google Scholar
MolluscaBase (eds) (2023b) MolluscaBase. Palio Gray, 1857. Accessed through: World Register of Marine Species at: https://www.marinespecies.org/aphia.php?p=taxdetailsandid=182805 on 2023-03-17.Google Scholar
MolluscaBase (eds) (2023c) MolluscaBase. Polycera Cuvier, 1816. Accessed through: World Register of Marine Species at: https://www.marinespecies.org/aphia.php?p=taxdetailsandid=138369 on 2023-03-17.Google Scholar
Nimbs, JM and Smith, SDA (2016) An illustrated inventory of the sea slugs of New South Wales, Australia (Gastropoda: Heterobranchia). Proceedings of the Royal Society of Victoria 128, 44113.CrossRefGoogle Scholar
Odhner, NHJ (1941) New polycerid nudibranchiate Mollusca and remarks on this family. Meddelanden fran Gotesborgs Musei Zoologiska Avdeling 91, 120.Google Scholar
O'Donoghue, CH (1924) Notes on the nudibranchiate Mollusca from the Vancouver Island region. IV. Additional species and records. Transactions of the Royal Canadian Institute 15, 133, pls. 1,2.Google Scholar
Ortea, J (1989) Descripcon de algunos moluscos opistobranchios nuevos recolectados en el archipielago de Cabo Verde. Publicaçóes Ocasionais da Sociedade Portuguesa de Malacologia 13, 1734.Google Scholar
Ortea, J, Rolán, E and Valdés, A (1992) Inclusión de Esuriospinax templadoi Ortea, 1989 (Mollusca: Nudibranchia: Goniodorididae) en el género Paliolla Burn, 1989. Revista de la Academia Canaria de Ciencias IV 3–4, 103107.Google Scholar
Palomar, G, Pola, M and García-Vazquez, E (2014) First molecular phylogeny of the subfamily Polycerinae (Mollusca, Nudibranchia, Polyceridae). Helgoland Marine Research 68, 143153.CrossRefGoogle Scholar
Palumbi, SR, Martin, A, Romano, S, Owen Macmillan, W, Stice, L and Grabowski, G (1991) The Simple Fool's Guide to PCR. Honolulu, USA: Department of Zoology, University of Hawaii.Google Scholar
Pease, WH (1871) Descriptions of nudibranchiate Mollusca inhabiting Polynesia. American Journal of Conchology 6, 299305.Google Scholar
Picton, BE and Morrow, CC (1994) A Field Guide to the Nudibranchs of the British Isles. 143pp. London: Immel Publishing.Google Scholar
Pola, M, Sánchez-Benítez, M and Ramiro, B (2014) The genus Polycera Cuvier, 1817 (Nudibranchia: Polyceridae) in the eastern Pacific Ocean, with redescription of Polycera alabe Collier and Farmer, 1964 and description of a new species. Journal of Molluscan Studies 80, 551561.CrossRefGoogle Scholar
Pruvot-Fol, A (1954) Faune de France. Mollusques opistobranches. Paris.Google Scholar
Rambaut, A (2009) FigTree v1.3.1: Tree Fig. Drawing Tool. Available at http://tree.bio.ed.ac.uk/software/figtree/Google Scholar
Rivest, BR (1984) Copulation by hypodermic injection in the nudibranchs Palio zosterae and P. dubia (Gastropoda, Opisthobranchia). Biological Bulletin 167, 534554.CrossRefGoogle ScholarPubMed
Rudman, WB (2003) Palio zosterae (O'Donoghue, 1924). [In] Sea Slug Forum. Sydney: Australian Museum. Available at http://www.seaslugforum.net/factsheet/palizostGoogle Scholar
Sars, M (1829) Bidrag til söedyrenes naturhistorie. Chr. Dahl, Bergen 1, 160, plates 1–6.Google Scholar
Sørensen, CG, Rauch, C, Pola, M and Malaquias, MAE (2020) Integrative taxonomy reveals a cryptic species of the nudibranch genus Polycera (Polyceridae) in European waters. Journal of the Marine Biological Association of the United Kingdom 100, 733752.CrossRefGoogle Scholar
Thompson, TE (1975) Dorid nudibranchs from Eastern Australia (Gastropoda, Opisthobranchia). Journal of Zoology 176, 477517.CrossRefGoogle Scholar
Verrill, AE (1880) Notice of the remarkable marine fauna occupying the outer banks off the southern coast of New England. The American Journal of Science and Arts 3, 390403.CrossRefGoogle Scholar
Figure 0

Table 1. Specimens used for molecular analyses, including species, museum voucher, locality, and GenBank vouchers

Figure 1

Table 2. COI gene pairwise uncorrected P-distances (%) within and between species for comparison

Figure 2

Table 3. 16S gene pairwise uncorrected P-distances (%) within and between species for comparison

Figure 3

Table 4. H3 gene pairwise uncorrected P-distances (%) within and between species for comparison

Figure 4

Figure 1. Phylogenetic relationships (BI/ML) based on the mitochondrial COI gene marker. The family Polycerinae is highlighted with an orange spot. The newly sequenced specimens are in bold.

Figure 5

Figure 2. Photographs of living animals. A–C Palio gaeli sp. nov. A, C. MNCN 15.05/200208H; B. MNCN 15.05/200208P; photographs by S. Johnson. D–E Polycera nimbsi sp. nov. D, C.547846; photograph by M. Nimbs. E, C.547849; photograph by S.D.A. Smith.

Figure 6

Figure 3. Drawings of internal anatomy. A,B, buccal bulb and reproductive system of Palio gaeli sp. nov. C, D, buccal bulb, and reproductive system of Polycera nimbsi sp. nov. E, F, buccal bulb, and reproductive system of Paliota galactica sp. nov. Abbreviations: am, ampulla; bb, buccal bulb; bc, bursa copulatrix; fgm, female gland mass; hd, hermaphroditic duct; oe, oesophagus; pr, prostate; ra, radular sac; rs, receptaculum seminis; sgl, salivary gland; va, vagina; vd, vas deferens. Scale bars = 1 mm.

Figure 7

Figure 4. Scanning electron micrographs (SEM) and light microscope photographs (LMP) of Palio gaeli sp. nov. A, labial cuticle (MNCN 15.05/200208H) (LMP); B, detail of labial cuticle (MNCN 15.05/200208H) (LMP); C, complete radula (MNCN 15.05/200208H) (SEM); D, detail of inner and outer lateral teeth (MNCN 15.05/200208P) (SEM); E, detail of marginal teeth (MNCN 15.05/200208P) (SEM); F, detail of penial spines (MNCN 15.05/200208H) (LMP). Scale bars: A, 50 μm; B, 10 μm; C, 300 μm; D, 100 μm; E, 50 μm; F, 10 μm.

Figure 8

Figure 5. Scanning electron micrographs (SEM) and light microscope photographs (LMP) of Polycera nimbsi sp. nov. A, labial cuticle (MNCN 15.05/200210); B, detail of labial cuticle (AM C.547846) (SEM); C, section of radula at rows 3–7 (MNCN 15.05/200210) (SEM); D, detail of a row of teeth (AM C.547846) (SEM); E, penial spines located more proximal to base (AM C.547848) (LMP); F, penial spines located distally (AM C.547848) (LMP); Scale bars: A, 500 μm; B, 50 μm; C, 200 μm; D, 100 μm; E, 50 μm; F, 50 μm.

Figure 9

Figure 6. Photographs of living animals. A-C. Paliota galactica sp. nov. A, B, AM C.547850; C, AM C.547851; photographs by D. Harasti. D. Paliolla templadoi (MNCN 15.05/94863); photograph by M. Pola.

Figure 10

Figure 7. Scanning electron micrographs (SEM) and light microscope photographs (LMP) of Paliota galactica sp. nov. A, labial cuticle (AM C.547850); B, detail of labial cuticle (MNCM 15.05/200209) (SEM); C, view of radula (AM C.547851) (SEM); D, detail of lateral teeth (AM C.547851) (SEM); E, detail of marginal teeth (MNCM 15.05/200209); F, penial spines (AM C.547851) (LMP). Scale bars: A, 500 μm; B, 100 μm; C, 100 μm; D, 50 μm; E, 50; F, 10 μm.

Supplementary material: Image

Pola et al. supplementary material

Pola et al. supplementary material 1

Download Pola et al. supplementary material(Image)
Image 720.1 KB
Supplementary material: Image

Pola et al. supplementary material

Pola et al. supplementary material 2

Download Pola et al. supplementary material(Image)
Image 461.3 KB
Supplementary material: Image

Pola et al. supplementary material

Pola et al. supplementary material 3

Download Pola et al. supplementary material(Image)
Image 867.2 KB
Supplementary material: Image

Pola et al. supplementary material

Pola et al. supplementary material 4

Download Pola et al. supplementary material(Image)
Image 909 KB