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Integrative taxonomy reveals a cryptic species of the nudibranch genus Polycera (Polyceridae) in European waters

Published online by Cambridge University Press:  30 July 2020

Cecilie Gotaas Sørensen ,
Cessa Rauch ,
Marta Pola  and
Manuel António E. Malaquias Open the ORCID record for Manuel António E. Malaquias [Opens in a new window]
Cecilie Gotaas Sørensen
Affiliation:
Section of Taxonomy and Evolution, Department of Natural History, University Museum of Bergen, University of Bergen, PB7800, 5020-Bergen, Norway
Cessa Rauch
Affiliation:
Section of Taxonomy and Evolution, Department of Natural History, University Museum of Bergen, University of Bergen, PB7800, 5020-Bergen, Norway
Marta Pola
Affiliation:
Departamento de Biología, Facultad de Ciencias, Universidad Autónoma de Madrid, Campus de Excelencia Internacional UAM + CSIC, Madrid, Spain Centro de Investigación en Biodiversidad y Cambio Global (CIBC-UAM), Campus de Excelencia Internacional UAM + CSIC. C/Darwin 2, 28049Madrid, Spain
Manuel António E. Malaquias*
Affiliation:
Section of Taxonomy and Evolution, Department of Natural History, University Museum of Bergen, University of Bergen, PB7800, 5020-Bergen, Norway
*
Author for correspondence: Manuel António E. Malaquias, E-mail: Manuel.Malaquias@uib.no
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Abstract

This work aimed to test whether the colour variability featured by the European nudibranch Polycera quadrilineata is consistent with the concept of a single polychromatic species or may hide multiple lineages. Samples from across the geographic range of P. quadrilineata together with representatives from worldwide species with a focus on Atlantic diversity, were gathered and studied using an integrative taxonomic approach. Morpho-anatomical characters were investigated by light and scanning electron microscopy. Bayesian molecular phylogenetics using MrBayes, the Automatic Barcode Gap Discovery species delimitation method, and haplotype network analysis using the PopArt software were employed to help delimit species using the mitochondrial gene cytochrome c oxidase subunit I (COI). The results supported the existence of a second species, here described and named Polycera norvegica sp. nov., only known from Norway where it is sympatric with P. quadrilineata. The COI uncorrected p-genetic distance between the two species was estimated at 9.6–12.4%. Polycera norvegica sp. nov. differs by exhibiting a black dotted or patchy dotted pattern occasionally with more or less defined orange/brown patches, but never black continuous or dashed stripes as in P. quadrilineata. The two species share a common colouration with a whitish base and yellow/orange tubercles. Anatomically, P. norvegica sp. nov. has a weaker labial cuticle, a smaller radula with fewer rows, and only four marginal teeth, a reproductive system with a single lobed bursa copulatrix, shorter reproductive ducts, and a penis armed with two kinds of spines: needle-like and hook-shaped penile spines.

Keywords

BiodiversityNudibranchiaPolycera norvegica sp. nov.systematics
Type
Research Article
Information
Journal of the Marine Biological Association of the United Kingdom , Volume 100 , Issue 5 , August 2020 , pp. 733 - 752
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © Marine Biological Association of the United Kingdom 2020

Introduction

The concept of ‘cryptic species’ has been debated and its definition remains a topic of controversy (Struck et al., Reference Struck, Feder, Bendiksby, Birkeland, Cerca, Gusarov, Kistenich, Larsson, Liow, Nowak, Stedje, Bachmann and Dimitrov2018; Korshunova et al., Reference Korshunova, Picton, Furfaro, Mariottini, Pontes, Prkić, Fletcher, Malmberg, Lundin and Martynov2019). Several authors questioned whether cryptic species truly exist or are transitional taxonomic misinterpretations resulting most of all from overlooked morphological characters (Horsáková et al., Reference Horsáková, Nekola and Horsák2019; Korshunova et al., Reference Korshunova, Picton, Furfaro, Mariottini, Pontes, Prkić, Fletcher, Malmberg, Lundin and Martynov2019). The concept is further complicated by the existence of multiple definitions across disciplines. For example, in behavioural ecology the concept applies to species with colourations and shapes that blend with the environment (Todd, Reference Todd1981, Reference Todd1983; Claridge et al., Reference Claridge, Mifsud, Dawson and Saxon2005; Bickford et al., Reference Bickford, Lohman, Sodhi, Ng, Meier, Winker, Ingram and Das2007; Korshunova et al., Reference Korshunova, Picton, Furfaro, Mariottini, Pontes, Prkić, Fletcher, Malmberg, Lundin and Martynov2019). Additionally, several derivatives of the concept have been proposed such as ‘true cryptic species’ (when a priori no morphological differences are recognized regardless of the distribution and ecology of species; Horsáková et al., Reference Horsáková, Nekola and Horsák2019; Korshunova et al., Reference Korshunova, Picton, Furfaro, Mariottini, Pontes, Prkić, Fletcher, Malmberg, Lundin and Martynov2019), ‘pseudo-cryptic species’ and ‘quasi-cryptic species’ (when subtle morphological difference can be recognized; Horsáková et al., Reference Horsáková, Nekola and Horsák2019; Korshunova et al., Reference Korshunova, Picton, Furfaro, Mariottini, Pontes, Prkić, Fletcher, Malmberg, Lundin and Martynov2019), ‘semi-cryptic species’ (morphological differences are very difficult to define; Vondrák et al., Reference Vondrák, Říha, Arup and Søchting2009; Korshunova et al., Reference Korshunova, Picton, Furfaro, Mariottini, Pontes, Prkić, Fletcher, Malmberg, Lundin and Martynov2019), or ‘false cryptic species’ (morphological differences are obvious, but for some reason were missed or not highlighted in previous studies; Korshunova et al., Reference Korshunova, Picton, Furfaro, Mariottini, Pontes, Prkić, Fletcher, Malmberg, Lundin and Martynov2019).

Several recent studies on sea slugs have described cryptic species, sensu species that are morphologically similar but genetically distinct, differing for example in their reproductive biology, life history, feeding biology and/or habitat preferences, or species that depict subtle morphological differences which have mistakenly been interpreted as part of their natural variability. Several examples have been described for Aeolidia Cuvier, 1798 (Carmona et al., Reference Carmona, Pola, Gosliner and Cervera2013; Kienberger et al., Reference Kienberger, Carmona, Pola, Padula, Gosliner and Cervera2016), Glaucus Forster, 1777 (Churchill et al., Reference Churchill, Valdés and Foighil2014), Anteaeolidiella M. C. Miller, 2001 (Carmona et al., Reference Carmona, Bhave, Salunkhe, Pola, Gosliner and Cervera2014a), Spurilla Bergh, 1864 (Carmona et al., Reference Carmona, Lei, Pola, Gosliner, Valdés and Cervera2014b), Cratena Bergh, 1864 (Padula et al., Reference Padula, Araujo, Matthews-Cascon and Schrödl2014), Dendronotus Alder & Hancock, 1845 (Ekimova et al., Reference Ekimova, Korshunova, Schepetov, Neretina, Sanamyan and Martynov2015; Korshunova et al., Reference Korshunova, Martynov, Bakken and Picton2017a), Pteraeolidia Bergh, 1875 (Wilson & Burghardt, Reference Wilson and Burghardt2015), Felimida Ev. Marcus, 1971 (Padula et al., Reference Padula, Bahia, Stöger, Camacho-García, Malaquias, Cervera and Schrödl2016), Flabellinidae Bergh, 1889 (Korshunova et al., Reference Korshunova, Martynov, Bakken, Evertsen, Fletcher, Mudianta, Saito, Lundin, Schrödl and Picton2017b), Chromodoris Alder & Hancock, 1855 (Layton et al., Reference Layton, Gosliner and Wilson2018), Hypselodoris Stimpson, 1855 (Epstein et al., Reference Epstein, Hallas, Johnson, Lopez and Gosliner2018) and Trinchesia Ihering, 1879 (Korshunova et al., Reference Korshunova, Picton, Furfaro, Mariottini, Pontes, Prkić, Fletcher, Malmberg, Lundin and Martynov2019), among others.

The nudibranch gastropod Polycera quadrilineata (O.F. Müller, Reference Müller1776) is the type species of the genus Polycera Cuvier, 1817, and is one of the six species of the genus cited in European waters, together with Polycera elegans Bergh, Reference Bergh1894, Polycera faeroensis Lemche, Reference Lemche1929, Polycera maculata Pruvot-Fol, Reference Pruvot-Fol1951, Polycera hedgpethi Er. Marcus, 1964, and Polycera aurantiomarginata García-Gómez & Bobo, Reference García-Gómez and Bobo1984. The species P. hedgpethi is native in California but it is now established in the Mediterranean Sea (Cervera et al., Reference Cervera, Garcia-Gomez, Toscano and García1991, Reference Cervera, Calado, Gavaia, Malaquias, Templado, Ballesteros, García-Gómez and Megina2004; Caballer & Ortea, Reference Caballer and Ortea2002; Keppel et al., Reference Keppel, Sigovini and Tagliapietra2012; Giacobbe & De Matteo, Reference Giacobbe and De Matteo2013).

The species name P. quadrilineata was first introduced by O.F. Müller (Reference Müller1776, as Doris), but only later the author included a description and illustrations of the species with details about its type locality in Drøbak, Oslofjord, Norway (O.F. Müller, Reference Müller1779: 37; pl. 17, figures 4–6) (see Figure 1). The species is known from Lofoten in the north-western coast of Norway southwards to the Iberian Peninsula, Mediterranean Sea (as far as Greece), and the archipelagos of the Canary Islands, Madeira and the Azores (Bergan & Anthon, Reference Bergan and Anthon1977; Thompson & Brown, Reference Thompson and Brown1984; Thompson, Reference Thompson1988; Cervera et al., Reference Cervera, Calado, Gavaia, Malaquias, Templado, Ballesteros, García-Gómez and Megina2004; Antoniadou et al., Reference Antoniadou, Koutsoubas and Chintiroglou2005; Trainito, Reference Trainito2005; Martínez-Pita et al., Reference Martínez-Pita, Sánchez-España and García2006; Martynov et al., Reference Martynov, Korshunova and Savinkin2006; Trainito & Doneddu, Reference Trainito and Doneddu2014; Micaroni et al., Reference Micaroni, Strano, Di Franco, Crocetta, Grech, Piraino and Boero2018). It can reach up to 30–45 mm in length and is highly variable in colour with a translucent creamy-whitish base, that can be partly or almost entirely covered with continuous or dashed black stripes, or occasionally black or greyish blotches, and may have yellow or orange wart-like tubercles present dorsally (Eales, Reference Eales1967; Thompson & Brown, Reference Thompson and Brown1984; Thompson, Reference Thompson1988; Picton & Morrow, Reference Picton and Morrow1994; Hayward & Ryland, Reference Hayward and Ryland1995; Rudman, Reference Rudman1999; Moen & Svensen, Reference Moen and Svensen2014; Telnes, Reference Telnes2018).

Fig. 1. Original illustration of Polycera quadrilineata (adapted from O. F. Müller, Reference Müller1779).

Polycera quadrilineata is a common species between the intertidal zone to depths of 30 m where it feeds on bryozoans of the genera Electra Lamouroux, 1816 and Membranipora d'Blainville, 1830 (Thompson & Brown, Reference Thompson and Brown1984; Thompson, Reference Thompson1988; Picton & Morrow, Reference Picton and Morrow1994), but specimens have been reported between 60–300 m (Bergan & Anthon, Reference Bergan and Anthon1977). Around the British Isles the species reproduces and lay eggs during late spring and early summer (Miller, Reference Miller1961; Bruce et al., Reference Bruce, Jones and Colman1963; Thompson & Brown, Reference Thompson and Brown1984), but in Norway we found aggregations of the species from November in the winter to June in late spring, although the exact time of these peaks of abundance can vary from year to year (Erling Svensen, personal observation). The egg-mass is white and crescent-shaped and the eggs are spherical, small and have been documented to range between 0.06–0.08 mm in diameter (Schmekel et al., Reference Schmekel, Portmann, Richter and Bousani-Baur1982; Martínez-Pita et al., Reference Martínez-Pita, Sánchez-España and García2006; Martínez-Pita & García, Reference Martínez-Pita and García2017), which according to Martínez-Pita et al. (Reference Martínez-Pita, Sánchez-España and García2006) is an egg size typically found in species with planktotrophic larval development.

Whether the highly polychromatic pattern of P. quadrilineata is consistent with a case of extreme intraspecific variability in nudibranchs or hides a possible complex of species was never tested before. In this work an integrative approach combining DNA and morpho-anatomical characters was used to investigate the taxonomic status of P. quadrilineata, i.e. the hypothesis whether it is one single biological lineage with extensive chromatic variability or alternatively, comprises a complex of multiple species.

Materials and methods

Taxon sampling

Specimens were obtained by intertidal sampling, scuba-diving down to 30 m deep, and dredging using triangular, epibenthic and kelp dredges on board the research vessel ‘Hans Brattström’ owned by the University of Bergen, Norway (UiB). Most collected specimens were deposited in the scientific collections of the Department of Natural History, University Museum of Bergen, UiB (ZMBN).

Specimens were photographed alive with a digital SLR camera equipped with macro-lens, measured with a ruler (mm) for their maximum length (H), and frozen overnight inside plastic jars with seawater to ensure the body was kept fully extended for later possible anatomical studies. Afterwards, specimens were defrosted and fixed in absolute ethanol (>96%). Additionally, 47 sequences of the cytochrome c oxidase subunit I (COI) of Polycera quadrilineata and other Polyceridae taxa, representing a total of 17 species, together with the outgroup species Jorunna tomentosa (Cuvier, Reference Cuvier1804) were obtained from GenBank and BOLD databases (Table 1). The nudibranch species J. tomentosa (family Discodorididae) was chosen for outgroup taxa in the phylogenetic analyses based on the results of Palomar et al. (Reference Palomar, Pola and Garcia-Vazquez2014).

Table 1. Material examined and used for molecular analysis, including sampling locality, habitat, voucher number and GenBank or BOLD accession numbers

Specimens (S) from the same lot were coded sequentially with the acronym S1, S2, S3, etc., in the column ‘Sample no’. Novel sequences are marked with an asterisk.

DNA extraction, amplification, purification and sequencing

Tissue samples for DNA extraction were gathered from 69 specimens of Polycera quadrilineata sensu lato by cutting a small part of their foot or mantle using forceps or a scalpel and were kept in 1.5 ml Eppendorf tubes filled with absolute ethanol. In rare cases, when specimens were too small to cut off enough tissue the whole specimen was used. To prevent contamination forceps and scalpel blades were rinsed with ethanol between each sample.

DNA was extracted from tissue samples using the ‘Qiagen DNeasy Blood and Tissue Kit’ (QIAGEN, catalogue no. 69506), following the protocol for ‘Purification of Total DNA from Animal Tissues (Spin-Column)’. Amplification of the gene COI was performed through polymerase chain reaction (PCR) using the universal primers by Folmer et al. (Reference Folmer, Black, Hoeh, Lutz and Vrijenhoek1994) and a total reaction volume of 50 μl using 17.5 μl Sigma water (ddH2O), 5 μl buffer, 5 μl dNTP, 10 μl Q-solution, 7 μl MgCl, 2 μl of each primer (10 μM), 0.5 μl TAQ and 1 μl DNA. Some amplifications were carried out with only 25 μl volume using the same cocktail mix, but replacing the standard buffer with CoralLoad (CL) buffer from Qiagen, using only half of each quantity. PCR thermal cycles included an initial denaturation at 95°C for 3 min, followed by 39 cycles of 45 s at 94°C (denaturation), 45 s at 45°C (annealing), 2 min at 72°C (extension), and a final extension step at 72°C for 10 min, before cooling down. In order to rule out contamination, a negative and positive control were added to each PCR run. The negative control consisted of distilled water (ddH2O), whereas the positive control used DNA extract from a previously successfully tested sea slug species, namely Aplysia punctata (Cuvier, Reference Cuvier1803).

The quality of PCR products was assessed using gel electrophoresis, by running 4 ml of PCR mixed with 1 μl Ficoll 5× loading buffer on a 1.0% agarose gel prepared with half-strength TAE 1× buffer (tris-acetate-EDTA) containing the staining agent GelRed covered in TAE 1× buffer. For the PCR products already containing a loading buffer (i.e. the CL buffer), 5 μl PCR product were added directly into the gel. To quantify and estimate the length of amplified DNA fragments, a 5 μl FastRuller ladder marker was used. The gel was run for 30 min at 80 V and was posteriorly analysed under a Syngene UV-radiation machine. GeneSnap and GeneTools softwares (Syngene, Cambridge, UK) were used for imaging and manual DNA quantification, respectively.

Successful PCR products were purified using EXO-SAP, a combination of the enzymes Exonuclease I (EXO I) and Shrimp Alkaline Phosphatase (SAP), with each purification sample containing 8 μl PCR product and 2 μl EXOSAP (0.1 μl EXO, 1.0 μl SAP and 0.9 μl ddH2O). Reactions were run for 30 min at 37°C (incubation), followed by 15 min at 85°C (enzyme inactivation), and 4°C for cooling in the thermal cycler. Sequencing reactions were prepared in 1.5 ml Eppendorf tubes (kept on ice) using 1 μl of purified PCR product mixed with 6 μl of ddH2O, 1 μl primer (3.2 μM), 1 μl BigDye (BD) and 1 μl of sequence buffer. This process was repeated independently for each of the two primers (forward and reverse). The reactions were conducted in a thermal cycler for 5 min at 96°C (initial denaturation), followed by 25 cycles of 10 s at 96°C (denaturation), 5 s at 50°C (annealing), and 4 min at 60°C, before cooling down at 6°C. Afterwards, 10 μl ddH2O were added to each sequencing reaction and PCRs were delivered for Sanger sequencing using a capillary-based Applied Biosystem 3730XL DNA Analyzer at the DNA sequencing facility of the Department of Biological Sciences, UiB.

Phylogenetic and species delimitation analyses

The programme Geneious v. 11.0.3 was used to inspect, assemble and edit the chromatograms of the forward and reverse DNA strands. Sequences of each sample were checked by careful examination of the chromatograms and trimmed at both ends to remove parts of low quality and were translated to protein sequences using the invertebrate mitochondrial genetic code to ensure that there were no stop-codons present. Possible contamination of sequences was accessed by comparing with available sequences of molluscs through the BLAST toll in GenBank. Sequences were aligned using MUSCLE (Edgar, Reference Edgar2004) implemented in Geneious. The alignment was trimmed at both ends to a position where at least 50% of the sequences had nucleotide data yielding a final alignment with 642 base pairs (bp).

The MEGA X software (Kumar et al., Reference Kumar, Stecher, Li, Knyaz and Tamura2018) was used to estimate uncorrected pairwise (p) distances within and between species (Table 2). The jModelTest2 v. 2.1.10 (Darriba et al., Reference Darriba, Taboada, Doallo and Posada2012) was used to find the best-fit evolutionary model [model selected = GTR + I + G] under the Akaike information criterion (AIC). The Bayesian analysis was performed using MrBayes (Huelsenbeck & Ronquist, Reference Huelsenbeck and Ronquist2001), with three parallel runs of five million generations each, sampling every 1000 generations, with a burn-in set to 25%. MrBayes was run through the portal CIPRES (Miller et al., Reference Miller, Pfeiffer and Schwartz2010) and the consensus phylogram was converted into a graphical tree in FigTree v.1.4.3 (Rambaut, Reference Rambaut2016).

Table 2. Inter- and intraspecific (bold font) uncorrected pairwise (p) distances estimated using MEGA X for Polycera species

The Automatic Barcode Gap Discovery (ABGD) species delimitation analysis (Puillandre et al., Reference Puillandre, Lambert, Brouillet and Achaz2012) was used to help delimiting species using the three evolutionary models available (Simple Distance, Kimura (K80) TS/TV = 2 and Jukes-Cantor (JC69)). Each analysis was run independently using default settings.

Haplotype network analysis

Haplotype network analysis was conducted separately for the two lineages recognized within Polycera quadrilineata sensu lato (P. quadrilineata proper [63 seq.] and Polycera norvegica sp. nov. [17 seq.]), using the programme PopArt v. 1.7 (Population Analysis with Reticulate Trees; Leigh & Bryant, Reference Leigh and Bryant2015). Prior to PopArt the alignment file combining the two lineages was edited using the text editor programme Notepad++ v. npp.7.6.6, and all empty positions at both ends were removed, yielding a final alignment with 594 bp. Sequence P48 (see Table 1) was excluded due to its reduced size (541 bp). Notepad++ was used to generate species-specific alignments and trait files with geographic area codes (i.e. 0 = specimen absent, 1 = specimen present). Alignments were converted into phylip format (phy) using the program Mesquite v.3.51 (Maddison & Maddison, Reference Maddison and Maddison2018). Alignments and trait files were finally run in PopArt to create a standard TCS Network analysis (Clement et al., Reference Clement, Posada and Crandall2000) in order to visualize the genetic relationships and distances between the individual genotypes. The single specimen of P. quadrilineata obtained from Sveio (Norway) was for the sake of geographic proximity considered part of the geographic area Haugesund (Norway). The TCS haplotype networks were edited for more satisfying visualization using both PopArt v. 1.7, Adobe Illustrator, CS6 v.16.0.4 and Gravit Designer v.2019-2.1 at https://gravit.io/.

Morpho-anatomical work and scanning electron microscopy

Dissections were done under a stereo microscope Nikon SMZ-1500 equipped with a camera lucida. The animals were opened by dorsal incision, and the reproductive system and buccal mass, with the radula and labial cuticle were removed. The buccal mass was dissolved in a 10% sodium hydroxide solution until the labial cuticle and radula were cleansed from their surrounding tissue. These structures were then rinsed with water, and examined and photographed under a light microscope using the Life Science Imaging software cellSense v.1.18. The reproductive systems were drawn using the camera lucida, and each penis was isolated, opened, examined and photographed using light microscopy. The labial cuticles and penises were critical point dried using hexamethyldisilane. All parts (radula, penises and labial cuticles) were mounted on metallic stubs for scanning electron microscopy (SEM), and sputter coated with gold-palladium. Observations were done with a Hitachi S-3000N SEM-machine.

Results

Phylogenetic analysis and species delimitation analysis

The molecular phylogenetic analysis included a total of 113 COI sequences containing 66 novel ones and 47 downloaded from GenBank and BOLD databases (Table 1). Eighteen lineages (including the outgroup taxon) were recognized and samples preliminarily identified as Polycera quadrilineata split in two different clades with maximum support. One containing specimens from all over Europe including the type locality (Drøbak, Norway) and colour patterns consistent with the original description (O. F. Müller, Reference Müller1776, Reference Müller1779), and a second clade only with specimens from Norway that was rendered sister (PP = 0.95) to a clade containing individuals from an unidentified Polycera species from South Africa and specimens of Polycera faeroensis from Europe (Figure 2).

Fig. 2. Bayesian molecular phylogenetic tree based on the COI gene. Numbers on branches represent posterior probabilities (PPs). Tree rooted with J. tomentosa. Green box refers to P. quadrilineata and purple box to Polycera norvegica sp. nov. Images refer to main morphotypes of these species and specimen depicted across both boxes represents the shared morphotype.

The genus Polycera as a whole was not rendered monophyletic due to lack of support (PP = 0.55) and inclusion of samples of the genera Polycerella A. E. Verrill, 1880 and Thecacera J. Fleming, 1828. Nevertheless, a clade with maximum support containing six species of Polycera was retrieved, namely with the type species of the genus P. quadrilineata, plus Polycera aurantiomarginata, Polycera capensis, P. faeroensis, Polycera sp.A (from South Africa) and Polycera norvegica sp. nov. (Figure 2).

COI uncorrected pairwise (p) genetic distances showed a 9.6–12.4% difference between P. quadrilineata and P. norvegica sp. nov., and a range of intraspecific variability in the former species of 0–2.4% and 0.2–2.3% in the latter (Table 2). The interspecific genetic distance between all included Polycera species was estimated at a maximum of 18.6–19.7% between P. faeroensis from Portugal and Polycera atra from California, USA and a minimum of 4.3–5.8% between P. capensis from South Africa and Australia and P. aurantiomarginata from Spain and Morocco. Intraspecific COI uncorrected p-distance between all studied Polycera species ranged between 0–2.6%.

The ABGD analyses under the three independent models of evolution retrieved the same number of partitions (=18), which were consistent with the 18 lineages suggested by the topology of the COI phylogenetic tree. Only for P values above 0.012915, the suggested number of partitions was lower, namely 17 groups (Kimura 80) and four with the Simple Distance and Juke-Cantor models (see supplementary material).

Class GASTROPODA Cuvier, 1795
Subclass HETEROBRANCHIA Burmeister, 1837
Superorder NUDIPLEURA Wägele & Willan, 2000
Order NUDIBRANCHIA, Cuvier, 1817
Family POLYCERIDAE Alder & Hancock, 1845
Genus Polycera Cuvier, 1817
Polycera quadrilineata (O. F. Müller, Reference Müller1776)
(Figures 3–6)

Synonyms

Fig. 3. P. quadrilineata. (A–F) Yellow/orange colour morphotype. (G–M) Striped colour morphotype. (A) Rogaland, Norway, ZMBN 127509, photo by C. Rauch and M. A. E. Malaquias, 2019. (B) Vestland, Norway, ZMBN 127690, photo by C. Rauch, 2019. (C) Rogaland, Norway, ZMBN 125859, photo by C. Rauch and A. Schouw, 2018. (D) Vestland, Norway, ZMBN 127676, photo by C. Rauch, 2019. (E) Vestland, Norway, ZMBN 127683, photo by C. Rauch, 2019. (F) Vestland, Norway, ZMBN 127677, photo by C. Rauch, 2019. (G) Vestland, Norway ZMBN 127678, photo by C. Rauch, 2019. (H) Vestland, Norway, ZMBN 127685, photo by C. Rauch, 2019. (I) Møre and Romsdal, Norway, ZMBN 125635, photo by N. Aukan, 2018. (J) Rogaland, Norway, ZMBN 127476, photo by C. Rauch and M. A. E. Malaquias, 2019. (K) Vestland, Norway, ZMBN 125032, photo by C. G. Sørensen and M. A. E. Malaquias, 2018. (L) Vestland, Norway, ZMBN 125033, photo by C. G. Sørensen and M. A. E. Malaquias, 2018. (M) Rogaland, Norway, ZMBN 125689, photo by E. Svensen, 2017.

Fig. 4. Main morphotypes found in P. quadrilineata. (A, B) Striped morphotype. (C, D) Yellow/orange morphotype. (A) Rogaland, Norway, ZMBN 125689, photo by E. Svensen, 2017. (B) Vestland, Norway, ZMBN 94139, photo by M. A. E. Malaquias, 2013. (C) Aquário dos Mosteiros, Azores, ZMBN 87942, photo by M. A. E. Malaquias, 2011. (D) Viken (Drøbak), Norway, ZMBN 127600, photo by H. Jensen, 2019. Drawings by C. G. Sørensen, 2019.

Fig. 5. Scanning electron micrographs of P. quadrilineata. (A) complete radula (ZMBN 127491). (B) Detailed view of the left side of the radula (ZMBN 125688). (C) Labial cuticle (ZMBN 125688). (D) Detail of central region of labial cuticle (ZMBN 127491). (E) Optical microscopy picture of labial cuticle (ZMBN 127491). (F) Close up of tissue from labial cuticle wall (ZMBN 125688). Scale bars: A = 1 mm, B = 300 μm, C = 500 μm, D = 100 μm, E = 1 mm, F = 30 μm.

Fig. 6. Reproductive system and scanning electron micrographs of the penis of P. quadrilineata. (A) Reproductive system (ZMBN 125688). (B) Whole penis (ZMBN 127491). (C) Detail of penis close to genital aperture (ZMBN 127491). (D) Detail of penile spines (ZMBN 125688). am, ampulla; bc, bursa copulatrix; fglm, female gland mass; hd, hermaphroditic duct; gp, genital pore; p, penis; pr, prostate; rs,  receptaculum seminis; vd, vas deferens; vg, vagina. Scale bars: A = 1 mm, B = 300 μm, C = 100 μm, D = 50 μm.

See MolluscaBase (2020)

Type locality: Drøbak, Frogn, Viken (Oslofjord), Norway.

Material examined: See Table 1 for list of specimens only sequenced. Hafrsfjord, Sola, Stavanger, Rogaland, Norway (58°55′50.232″N 5°39′36.6588″E), 1 spc. (S1) sequenced and dissected (yellow/orange morphotype), ZMBN 125688, H = 18 mm. Tingelsædet, Egersund, Rogaland, Norway (58°24′54.1116″N 5°59′57.6852″E), 1 spc. sequenced and dissected (striped morphotype), ZMBN 127491, H = 20 mm.

External morphology (Figures 3 & 4): Based on studied specimens H = 5–30 mm (but specimens with 45 mm have been reported; Moen & Svensen, Reference Moen and Svensen2014). Body surface smooth, covered with scattered tuberculate blotches; number and size of tubercles variable; tubercles either smoothly or sharply edged. Individuals with smaller tubercles often have larger quantity. Head with four to five, rarely six, smooth, digitiform veil processes projecting anteriorly; frontal veil processes yellow or orange in colour; apical tip often whitish. Non-retractile, lamellated rhinophores; stems thick, slightly leaning forwards; lamellated section slightly leaning backwards; average of 10–12 lamellae present, but number can range from 6–15. Eyespots present behind rhinophores; inconspicuous in some specimens. Gill circlet with 7–9, sometimes 11 pinnate gills. Gills white with yellow or orange apical edges, sometimes black pigmentation present on upper part. One elongate cylindrical papilla presents on each side of gill circlet, projecting backwards, sometimes short and stubby with rounded apical tip, otherwise slender with pointed tip; distal part yellowish, proximal half to 2/3 of length white. Mid-dorsal yellow or orange line extends from behind the gills to tip of tail.

Colouration (Figures 3 & 4): Two main colour morphs present.

Yellow/orange colour morph (Figures 3A–F, 4C, D) – ground colour white, translucent, with yellow or orange circular to oval scattered tubercles. Rhinophore stems white with upper half of lamellate part yellow or orange; or rhinophore stems with black, dark brownish or grey pigmentation covering entire stem or restricted to frontal half-part, expanding into upper yellowish lamellate part. Gills with yellow or orange apical edges.

Striped colour morph (Figures 3G–M, 4A, B) – ground colour white, translucent, with small yellow or orange often circular scattered tubercles. Black or dark grey continuous or dashed longitudinal lines present. Thickness and number of dark lines varies between individuals; some almost fully covered, giving specimens a melanistic appearance, while others have fewer lines, with a nearly white background. Rhinophore stems often black, dark or light greyish; lamellae often yellow or orange, sometimes with additional black pigmentation in upper part. Gills, in some darker specimens, can depict dark pigmentation on tips and along edges.

Radula (Figure 5A & B): Radular formula 13 × 5.2.0.2.5 (specimen H = 20 mm). Rachidian tooth absent; laterals elongated, hamate with strong prominent distal cusp; inner laterals smaller, with narrow base and triangular, spatulate distal cusp; outer laterals larger, thicker than inner, over twice the size, distal cusp more pointed and triangular; both laterals with hook-shaped wing-like expansion; wing-like expansion less prominent on inner laterals. Marginal teeth smaller, flat, plate-like, pseudo-rectangular, decreasing in size outwardly; inner marginal with prominent curved spur at anterior end.

Labial cuticle (Figure 5C–F): Large, robust with two large and elongated lateral wings. Well-developed brownish centre with jaw elements.

Reproductive system (Figure 6): Triaulic; hermaphroditic duct long, slender. Ampulla large, robust, kidney-shaped; post-ampullary duct bifurcating into short oviduct leading into large female gland mass and vas deferens through prostate portion. Prostate gland massive, narrowing towards distal vas deferens, closely attached to bursa copulatrix. Inside vas deferens a cup-shaped structure indicates end of the prostatic section. Vas deferens long, narrow, folded before reaching large penile bulb. Penis armed with numerous elongated, pointed, chitinous spines, of similar size; some spines bifid at apical tip. Vaginal duct long, folded, similar in width to vas deferens, connected to bursa copulatrix. Bursa copulatrix large, elongate, with two different parts; larger elongate proximal part, distal part more oval. Base of bursa copulatrix connected to pyriform, small receptaculum seminis by long, thin duct. Short uterine duct emerging close to receptaculum seminis and entering female gland, behind elongated portion of bursa copulatrix.

Ecology: Intertidal and subtidal species commonly found in shallow waters associated with algae. Feeds on encrusted bryozoans of the genera Electra and Membranipora. Reported from depths up 300 m (Bergan & Anthon, Reference Bergan and Anthon1977). Lives in cold to temperate waters between 5–25°C (Picton & Morrow, Reference Picton and Morrow1994; Betti et al., Reference Betti, Bava and Cattaneo-Vietti2017).

Distribution: Widely distributed across Western Europe from Norway (with Lofoten as its northernmost limit), Greenland, Sweden, Denmark, Iceland, Faroes, all around the British Isles, southwards to the Mediterranean Sea, Iberian Peninsula, and archipelagos of the Azores, Madeira and the Canary Islands (Thompson & Brown, Reference Thompson and Brown1984; Thompson, Reference Thompson1988; Evertsen & Bakken, Reference Evertsen and Bakken2005; Moen & Svensen, Reference Moen and Svensen2014).

Polycera norvegica sp. nov.
(Figures 7–10)

LSID urn:lsid:zoobank.org:pub:A36BDEBC-C058-451A-9222-3CC504173890

Fig. 7. Polycera norvegica sp. nov. (A–D) Yellow/orange colour morphotype, (E–H) dotted colour morphotype. (A) Trøndelag, Norway, ZMBN 126023, photo by V. V. Grøtan, 2018. (B) Trøndelag, Norway, ZMBN 126025 (paratype), photo by V. V. Grøtan, 2018. (C) Trøndelag, Norway, ZMBN 126024, photo by V. V. Grøtan, 2018. (D) Rogaland, Norway, ZMBN 127608, photo by O. Meldahl, 2018. (E) Rogaland, Norway, ZMBN 125493 (holotype), photo by A. Schouw and C. Rauch, 2018. (F) Rogaland, Norway, ZMBN 125855, photo by A. Schouw and C. Rauch, 2018. (G) Vestland, Norway, ZMBN 106113, photo by K. Kongshavn and M. A. E. Malaquias, 2015. (H) Vestland, Norway, ZMBN 125917, photo by A. Schouw and C. Rauch, 2018.

Fig. 8. Main morphotypes found in Polycera norvegica sp. nov. (A) Dotted morphotype. (B, C) Yellow/orange morphotype. (A) Vestland, Norway, ZMBN 106113, photo by K. Kongshavn, 2015. (B) Rogaland, Norway, ZMBN 127608, photo by O. Meldahl, 2018. (C) Trøndelag, Norway, ZMBN 126023, photo by V. V. Grøtan, 2018. Drawings by C. G. Sørensen, 2019.

Fig. 9. Scanning electron micrographs of Polycera norvegica sp. nov. (A) Radula (ZMBN 127486). (B) Detailed view of the left side of the radula (ZMBN 127486). (C) Labial cuticle (ZMBN 127486). (D) Close up of tissue from the labial cuticle wall (ZMBN 125492). (E) Labial cuticle (ZMBN 127492). (F) Optical microscopy picture of labial cuticle (ZMBN 125492). Scale bars: A = 1 mm, B = 200 μm, C = 500 μm, D = 20 μm, E = 300 μm, F = 1 mm.

Fig. 10. Reproductive system and scanning electron micrographs of the penis of Polycera norvegica sp. nov. (A) Reproductive system (ZMBN 125492). (B) Whole penis (ZMBN 127486). (C) Detail of penis close to genital aperture (ZMBN 127486). (D) Close up of penile spines (ZMBN 127486). Upper arrow = elongated penile spines. Lower arrow = hook-shaped penile spines. am, ampulla; bc, bursa copulatrix; fglm, female gland mass; hd, hermaphroditic duct; gp, genital pore; p, penis; pr, prostate; rs,  receptaculum seminis; vd, vas deferens; vg, vagina. Scale bars: A = 1 mm, B = 300 μm, C = 100 μm, D = 20 μm.

Diagnosis

Body surface smooth, partially tuberculate. Tubercles rounded or pointed, some more developed than others; tubercles with yellow, light-yellow or orange pigmentation; base colour translucent white. Colour pattern with randomly distributed black, dark grey or brown dots and orange/brown patches; patches most common in head and ‘neck’ region. Frontal veil with four to six long or short processes, smooth, tapering distally; somewhat retractile. Rhinophores lamellated with thick stem, leaning slightly forward; around six to ten lamellae. Seven to nine pinnate gills. Radular formula 8–11 × 4.2.0.2.4; rachidian tooth absent; laterals elongated, hamate with hook-like shaped structures and strong prominent triangular distal cusp; inner laterals narrower, straight; outer laterals thicker, broader than inner, at least twice the size; four marginal teeth, small, nearly quadrangular plates. Labial cuticle small, weak, with two lateral short wings, thin brownish centre with jaw elements. Reproductive system triaulic with long, slender hermaphroditic duct. Ampulla small. Prostate gland large, massive. Penis armed with two types of chitinous spines; one type resembling curvy hooks, the other more elongated. Vaginal duct elongated, slightly bent, shorter than vas deferens, about same width. Bursa copulatrix large, oval.

Type locality: Sandholmane, Haugesund, Norway (59°22′16.2552″N 5°10′55.9524″E).

Type material: Holotype, Sandholmane, Haugesund, Norway (59°22′16.2552″N, 5°10′55.9524″E), ZMBN 125493, H = 5 mm (fixed specimen). Paratypes, Steingardsvika, Espegrend, Bergen, Norway (60°17′46.968″N 5°13′17.184″E), ZMBN 106115, H = 6 mm in fixed specimen. Herdla, Askøy, Bergen, Norway (60°33′41.256″N 4°57′40.0968″E), ZMBN 125917. Skeisvika, Hundvåg, Stavanger, Norway (59°0′23.31″N 5°43′9.1668″E), ZMBN 127608; ZMBN 127607. Uthaug, Ørland, Trøndelag, Norway (63°43′37.2468″N 9°34′20.1072″E), ZMBN 126025, H = 8 mm; ZMBN 126024.

Additional material examined: See Table 1 for list of specimens only sequenced. Tingelsædet, Egersund, Rogaland, Norway (58°24′54.1116″N 5°59′57.6852″E), 1 spc. sequenced and dissected (yellow/orange morphotype), ZMBN 127486, H = 14 mm; 1 spc. (S1) sequenced and dissected (dotted morphotype), ZMBN 125492, H = 9 mm.

External morphology (Figures 7 & 8): Length of studied specimens 2–14 mm (some fixed). Body elongated, limaciform, with distinct marginal ridge; slightly higher than broad, highest and widest at mid-dorsal length close to anus, gills and papillae, ending in elongated and pointy tail. Body surface smooth, covered with scattered tubercles; number and size of tubercles variable, flattened or wart-like. Individuals with dotted morphotype tend to have rounded, slightly elevated, light-yellow tubercles. Head equipped with four to seven digitiform veil processes projecting anteriorly, yellow or orange coloured with whitish tips. Dotted morphotype often with only yellow spots scattered over a whitish-translucent background. Non-retractile, lamellated rhinophores ending in cylindrical knob; stems slightly leaning forward; 6–10 lamellae present. Eyespots present behind rhinophores; nearly indistinguishable in some specimens. Gill circlet with 7–9, sometimes 11 pinnate gills; individuals may possess both smaller and larger gills; gills can partially retract into pocket. One elongate, narrow, papillae present on each side of gill circlet, projecting backwards or laterally; papillae often shorter and stubby with rounded apical tip on individuals with dotted morphotype; often slender with sharper apical tips on individuals with yellow/orange morphotype.

Colouration (Figures 7 & 8): Two main colour morphs present.

Yellow/orange colour morph (Figures 7A–D, 8B, C) – as in yellow/orange morphotype described for P. quadrilineata, but in the studied specimens the rhinophore stems were always whitish lacking black pigmentation. Faint greyish tiny spots may be present on head region and gills.

Dotted colour morph (Figures 7E–H, 8A) – ground colour white, translucent, with black, dark brownish or grey dots scattered over entire surface. Brown/orange patches present on head region or sometimes randomly along body surface. Rhinophores white translucent; lamellae sometimes with a weak hint of light-yellow pigmentation; stem sometimes dark brown or grey Frontal veil processes translucent white, with few scattered yellow patches randomly distributed. Posterior papillae white with yellow tips; sometimes white basal part dotted with yellow or black patches. Gills whitish with yellow, orange, or black spots along rachis and tips.

Radula (Figure 9A & B): Radular formula 11 × 4.2.0.2.4 (specimen H = 14 mm). Rachidian tooth absent; laterals elongated, hamate with strong prominent distal cusp and hook-shaped wing-like expansions along mid-height on outer edges; inner laterals smaller, with narrow base and triangular distal cusp; outer laterals larger, over twice the size of inner laterals, with triangular pointed distal cusp, base broad. Marginal teeth small, flat, plate-like, approximately pseudo-quadrangular, elongated, decreasing in size outwardly; inner marginal with prominent, weakly curved spur at anterior end.

Labial cuticle (Figure 9C–F): Small, weak, with two short lateral wings. Weakly developed brownish centre with jaw elements.

Reproductive system (Figure 10): Triaulic; hermaphroditic duct elongated, thin. Ampulla small, kidney-shaped; post-ampullary duct bifurcating into short oviduct leading to large female gland mass and short vas deferens through prostrate portion. Prostate gland large, massive, narrowing towards distal vas deferens, surrounding bursa copulatrix. Inside vas deferens a cup-shaped structure indicates end of prostatic section. Vas deferens short, narrow, folded before reaching genital pore. Penile bulb reduced. Penis armed with two types of chitinous spines; spines closest to prostate more elongate; spines closest to genital opening hook-shaped. Vaginal duct elongated, slightly bent, shorter than vas deferens, but of similar width. Vagina ends in large oval bursa copulatrix. Bursa copulatrix rounded; base of bursa copulatrix connected to pyriform, small receptaculum seminis by short, thin duct; short uterine duct emerging close to receptaculum seminis, entering female gland.

Ecology: Sublittoral species occurring between 2–15 m depth, often on kelp (Laminaria spp.).

Distribution: Only known from Norway where it has been reported between Trondheim in the central west coast, along the south-west in Bergen, Haugesund, Stavanger and Egersund, and in Larvik in the southern coast.

Haplotype network analysis

The TCS haplotype network of P. quadrilineata with 63 specimens from Scandinavia, Mediterranean Sea and the Azores revealed the presence of 38 distinct haplotypes of which only nine were shared between individuals (Figure 11). From these, four haplotypes were each shared by two individuals (Norway: Bergen, Trondheim and Egersund), two were shared by three individuals (Sweden, Norway: Bergen, Egersund and Drøbak), one by four individuals (Norway: Egersund and Kristiansund), one by five (Sweden, Norway: Bergen, Drøbak and Egersund), and the most common haplotype by 11 individuals (Sweden, Norway: Bergen, Egersund, Kristiansund and Stavanger). Apart from the Azorean specimens which clustered together, the network showed a general lack of geographic structure. The haplotypes from the Azores differed between themselves by two to three base pairs (0.3–0.5%), whereas the difference to the closest haplotype outside the Azores (two haplotypes from Norway) was four base pairs (0.7%).

Fig. 11. TCS haplotype network analysis based on the COI gene generated in the programme PopArt, including sequences from 63 specimens of P. quadrilineata. Lines between black dots represent one mutation, while black dots represent hypothetical haplotypes. Each coloured circle represents a unique haplotype, and the size of each circle indicates how many specimens share that haplotype. Different colours represent geographic locations.

For Polycera norvegica sp. nov. (Figure 12) with 17 specimens (three from northern Norway and 14 from southern-western Norway), the TCS haplotype network revealed a lack of shared haplotypes and geographic structure.

Fig. 12. TCS haplotype network analysis based on the COI gene generated in the program PopArt, including sequences from 17 specimens of Polycera norvegica sp. nov. Lines between black dots represent one mutation, while black dots represent hypothetical haplotypes. Each coloured circle represents a unique haplotype, and the size of each circle indicates how many specimens share that haplotype. Different colours represent geographic locations.

Discussion

Molecular taxonomy has contributed in recent years to unravel a large number of cryptic lineages in sea slug molluscs, otherwise difficult to distinguish using traditional morphological and anatomical characters (see Introduction for an overview). Nevertheless, the concept of ‘cryptic species’ has been debated and remains controversial and subject to several definitions and interpretations (see for reviews Struck et al., Reference Struck, Feder, Bendiksby, Birkeland, Cerca, Gusarov, Kistenich, Larsson, Liow, Nowak, Stedje, Bachmann and Dimitrov2018; Korshunova et al., Reference Korshunova, Picton, Furfaro, Mariottini, Pontes, Prkić, Fletcher, Malmberg, Lundin and Martynov2019). Korshunova et al. (Reference Korshunova, Picton, Furfaro, Mariottini, Pontes, Prkić, Fletcher, Malmberg, Lundin and Martynov2019) considered cryptic species to be transitional taxonomic problems resulting often from incorrect weighting of morphological characters.

The phylogenetic and ABGD analyses (Figure 2 and supplementary material) retrieved one group containing specimens consistent with the original description by O. F. Müller (Reference Müller1776, Reference Müller1779) and collected in Drøbak in the Oslofjord, Norway (Figure 1), which is the type locality of Polycera quadrilineata. These specimens were therefore attributed to the latter species. Whereas, specimens preliminarily ascribed to P. quadrilineata, but which clustered elsewhere in the phylogenetic analysis and grouped separately on the ABGD analyses were attributed to a new species here described, namely Polycera norvegica sp. nov. In the latter species, one of the recognized colour morphs (the dotted colour morph) is in fact fairly distinct from the colour morphs found in P. quadrilineata, but surprisingly conspecificity was never questioned. However, in specimens of both species with the yellow/orange colour morph, separation based only on external chromatic and morphological features is difficult, virtually impossible. In addition, the variability found in the number of lamellae of the rhinophores and gills and maximum length of both species (Results section; Table 3) do not seem to be taxonomically informative and may in fact be ontogenetic or ultimately an artefact of sampling bias.

Table 3. Summary of the most useful characters for diagnosis of Polycera quadrilineata and Polycera norvegica sp. nov

The species P. quadrilineata and P. norvegica sp. nov. are genetically distinct (Table 2; COI uncorrected p-distance = 9.6–12.4%) and bear several discrete anatomic differences in the radula, labial cuticle and reproductive system. The radula of P. quadrilineata is larger, thicker, more elongate, with a greater number of rows, and has an additional marginal tooth on each side. The labial cuticle in P. quadrilineata is comparatively thicker, more robust and with a stronger central brownish area with jaw elements. The reproductive system is substantially distinct between both species. In P. quadrilineata the ampulla is larger and more robust and the bursa copulatrix depicts two different parts with a larger and elongate proximal part and an oval-shaped distal part, whereas P. norvegica sp. nov. has a bursa copulatrix entirely oval. Polycera norvegica sp. nov. has a larger prostate gland and a less developed penial bulb. Both species have armed penis but we have observed in P. norvegica sp. nov. the occurrence of two types of chitinous spines, whereas only one type was observed in P. quadrilineata. Moreover, the tubercles of P. quadrilineata are frequently more smoothly rounded than those found in P. norvegica sp. nov. (see Table 3 for a synopsis of diagnostic characters).

Interestingly these two species were not rendered sister to each other. The COI gene tree phylogeny suggested a closer phylogenetic relationship of P. norvegica sp. nov. with the European species Polycera faeroensis and an apparently undescribed species from South Africa (Polycera sp.A), whereas P. quadrilineata seems to be closer related to the north-eastern Atlantic Polycera aurantiomarginata and Indo-West Pacific Polycera capensis.

All but one sister pair of Polycera species studied in this work have interspecific genetic distances ranging between 8.8–19.7% (Table 2) and intraspecific variabilities between 0–2.6% showing the existence of a clear DNA barcode gap between species. The single exception is between P. capensis and P. aurantiomarginata with a genetic distance ranging from 4.3–5.8%, yet this does not affect the existence of a molecular barcode gap between sister species among the Polycera species studied in this work.

The haplotype network analyses showed genetic diversity and a lack of geographic structure in both species. The fact that the Azorean specimens showed a structural group in the haplotype network of P. quadrilineata could potentially indicate some degree of genetic isolation (Figure 11), which is not surprising given the geography of the Azorean islands located far off in the middle of the North Atlantic Ocean. Shared haplotypes between species from Norway and Sweden hint at a possible gene flow across populations from these two neighbouring countries. Interestingly, no shared haplotypes between sampling localities in Norway were found for P. norvegica sp. nov., but this may simply be because of the low number of specimens included in the analysis (N = 17; Figure 12).

Polycera quadrilineata and P. norvegica sp. nov. are sympatric in Norway, dwelling together on shallow water Laminaria kelp forests. The species P. quadrilineata has been reported to feed upon the encrusted bryozoans Membranipora membranacea (Linnaeus, Reference Linnaeus1767) and Electra pilosa (Linnaeus, Reference Linnaeus1767), but the differences found on the digestive system of P. norvegica sp. nov. with its weaker labial cuticle and distinct radula suggest a possible different diet.

This study showed that even in historically well-studied faunas there is a need to use integrative taxonomic approaches combining DNA and morphological characters together with complementary methodological approaches to truly understand biological diversity. This becomes even more critical when dealing with species that are highly similar morphologically – the so-called ‘cryptic’ or ‘pseudo-cryptic’ species. In those cases, even when subtle morphological differences can be recognized the problem is obviously to access and decide whether the observable differences are part of the natural intraspecific variability of the species or indicate distinct taxa. Drawing this line is often difficult and this is when a barcoding approach can be useful to unravel the putative existence of ‘hidden’ lineages. However, this does not preclude the need to eventually study several gene markers with different evolutionary rates, and for detailed morphological studies in order to establish helpful discrete taxonomic characters and formalize the description of new recognized lineages. It is now recognized that cryptic species are an important component of biodiversity and the only way to uncover this fraction is by using integrative approaches combining and comparing morphological and genetic characters under a multitude of methodological frameworks.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0025315420000612.

Acknowledgements

We are grateful to Anders Schouw, Carles Galià, Erling Svensen, Heine Jensen, Katrine Kongshavn, Matz Berggren, Nils Aukan, Ole Meldahl and Viktor Grøtan for help in collecting and for providing images of specimens. To Louise M. Lindblom and Kenneth Meland (University of Bergen) for help with molecular work, to Mari H. Eilertsen (University of Bergen) for guidance with the haplotype network analysis, Justine Siegwald (University of Bergen) for insightful discussions and Kathe Jensen (Natural History Museum of Copenhagen, Denmark) for help with historical literature.

Financial support

This work was funded by the Norwegian Biodiversity Information Centre, Artsdatabanken Project No. 812038, The sea slugs of Southern Norway: Diversity, barcoding, and invasive species.

References

Antoniadou, C, Koutsoubas, D and Chintiroglou, CC (2005) Mollusca fauna from infralittoral hard substrate assemblages in the North Aegean Sea. Belgian Journal of Zoology 135, 119126.Google Scholar
Bergan, K and Anthon, H (1977) Livet i Fjæra, 7th edn. Oslo: J. W. Cappelens Forlag AS.Google Scholar
Bergh, LSR (1894) Eine neue Gattung von Polyceraden (Greilada). Archiv für Naturgeschichte 60, 16.Google Scholar
Betti, F, Bava, S and Cattaneo-Vietti, R (2017) Composition and seasonality of a heterobranch assemblage in a sublittoral, unconsolidated, wave-disturbed community in the Mediterranean Sea. Journal of Molluscan Studies 83, 325332.Google Scholar
Bickford, D, Lohman, DJ, Sodhi, NS, Ng, PKL, Meier, R, Winker, K, Ingram, KK and Das, I (2007) Cryptic species as a window on diversity and conservation. Trends in Ecology and Evolution 22, 148155.CrossRefGoogle ScholarPubMed
Bruce, JR, Jones, NS and Colman, JS (1963) Marine Fauna of the Isle of Man and its Surrounding Seas, 2nd edn revised. Liverpool: Liverpool University Press.Google Scholar
Caballer, M and Ortea, J (2002) Primera cita de Polycera Hedgpethi Marcus, 1964 (Mollusca: Opisthobranchia) para la Península Ibérica. Noticiario de la Sociedad Española de Malacología 37, 5556.Google Scholar
Carmona, L, Pola, M, Gosliner, TM and Cervera, JL (2013) A tale that morphology fails to tell: a molecular phylogeny of Aeolidiidae (Aeolidida, Nudibranchia, Gastropoda). PLoS ONE 8, E63000.CrossRefGoogle Scholar
Carmona, L, Bhave, V, Salunkhe, R, Pola, M, Gosliner, TM and Cervera, JL (2014 a) Systematic review of Anteaeolidiella (Mollusca, Nudibranchia, Aeolidiidae) based on morphological and molecular data, with a description of three new species. Zoological Journal of the Linnean Society 171, 108132.CrossRefGoogle Scholar
Carmona, L, Lei, BR, Pola, M, Gosliner, TM, Valdés, Á and Cervera, JL (2014 b) Untangling the Spurilla neapolitana (Delle Chiaje, 1841) species complex: a review of the genus Spurilla Bergh, 1864 (Mollusca: Nudibranchia: Aeolidiidae): the species complex. Zoological Journal of the Linnean Society 170, 132154.CrossRefGoogle Scholar
Cervera, JL, Garcia-Gomez, JC, Toscano, F and García, FJ (1991) Polycera hedgpethi Marcus, 1964 (Gastropoda, Nudibranchia), una especie indopacifica descubierta en el Mediterraneo. Iberus 8, 225231.Google Scholar
Cervera, JL, Calado, G, Gavaia, C, Malaquias, MA, Templado, J, Ballesteros, MBV, García-Gómez, JC and Megina, C (2004) An annotated and updated checklist of the ophisthobranchs (Mollusca: Gastropoda) from Spain and Portugal (including islands and archipelagos). Boletín del Instituto Español de Oceanografía 20, 1122.Google Scholar
Churchill, CK, Valdés, Á and Foighil, (2014) Molecular and morphological systematics of neustonic nudibranchs (Mollusca: Gastropoda: Glaucidae: Glaucus), with descriptions of three new cryptic species. Invertebrate Systematics 28, 174195.CrossRefGoogle Scholar
Claridge, AW, Mifsud, G, Dawson, J and Saxon, MJ (2005) Use of infrared digital cameras to investigate the behaviour of cryptic species. Wildlife Research 31, 645650.CrossRefGoogle Scholar
Clement, M, Posada, D and Crandall, KA (2000) TCS: a computer program to estimate gene genealogies. Molecular Ecology 9, 16571659.Google ScholarPubMed
Cuvier, G (1803) Mémoire sur le genre Laplysia, vulgairement nommé Lièvre marin, sur son anatomie et sur quelques-unes de ses espèces. Annales du Muséum d'histoire naturelle 2, 287314.Google Scholar
Cuvier, G (1804) Mémoire sur le genre Doris. Annales du Muséum d'Histoire Naturelle 4, 447473.Google Scholar
Darriba, D, Taboada, GL, Doallo, R and Posada, D (2012) Jmodeltest2: more models, new heuristics and parallel computing. Nature Methods 9, 772.CrossRefGoogle Scholar
Eales, N (1967) The Littoral Fauna of the British Isles: A Handbook for Collectors, 4th edn. Cambridge: Cambridge University Press.Google Scholar
Edgar, RC (2004) MUSCLE: multiple sequence alignment with high accuracy and high throughput. Nucleic Acids Research 32, 17921797.CrossRefGoogle ScholarPubMed
Ekimova, I, Korshunova, T, Schepetov, D, Neretina, T, Sanamyan, N and Martynov, A (2015) Integrative systematics of northern and Arctic nudibranchs of the genus Dendronotus (Mollusca, Gastropoda), with descriptions of three new species. Zoological Journal of the Linnean Society 173, 841886.CrossRefGoogle Scholar
Epstein, H, Hallas, J, Johnson, R, Lopez, A and Gosliner, T (2018) Reading between the lines: revealing cryptic species diversity and colour patterns in Hypselodoris Nudibranchs (Mollusca: Heterobranchia: Chromodorididae). Zoological Journal of the Linnean Society 186, 116189.CrossRefGoogle Scholar
Evertsen, J and Bakken, T (2005) Nudibranch diversity (Gastropoda, Heterobranchia) along the coast of Norway. Fauna norvegica 25, 137.Google Scholar
Folmer, O, Black, M, Hoeh, W, Lutz, R and Vrijenhoek, R (1994) DNA primers for amplification of mitochondrial cytochrome c oxidase subunit I from diverse metazoan invertebrates. Molecular Marine Biology and Biotechnology 3, 294299.Google ScholarPubMed
García-Gómez, JC and Bobo, JA (1984) Una nueva especie de Polycera Cuvier (Mollusca: Nudibranchia) del litoral Iberico. Cahiers de Biologie Marine 25, 361373.Google Scholar
Giacobbe, S and De Matteo, S (2013) The potentially invasive opisthobranch Polycera hedgpethi Er. Marcus, 1964 (Gastropoda Nudibranchia), introduced in a Mediterranean coastal lagoon. Biodiversity Journal 4, 359364.Google Scholar
Hayward, PJ and Ryland, JS (1995) Handbook of the Marine Fauna of North-West Europe. Oxford: Oxford University Press.Google Scholar
Horsáková, V, Nekola, JC and Horsák, M (2019) When is a “cryptic” species not a cryptic species: a consideration from the Holarctic micro-landsnail genus Euconulus (Gastropoda: Stylommatophora). Molecular Phylogenetics and Evolution 132, 307320.Google Scholar
Huelsenbeck, JP and Ronquist, F (2001) MrBAYES: Bayesian inference of phylogenetic trees. Bioinformatics (Oxford, England) 17, 754755.CrossRefGoogle ScholarPubMed
Keppel, E, Sigovini, M and Tagliapietra, D (2012) A new geographical record of Polycera hedgpethi Er. Marcus, 1964 (Nudibranchia: Polyceridae) and evidence of its established presence in the Mediterranean Sea, with a review of its geographical distribution. Marine Biology Research 8, 969981.CrossRefGoogle Scholar
Kienberger, K, Carmona, L, Pola, M, Padula, V, Gosliner, TM and Cervera, JL (2016) Aeolidia papillosa (Linnaeus, 1761) (Mollusca: Heterobranchia: Nudibranchia), single species or a cryptic species complex? A morphological and molecular study. Zoological Journal of the Linnean Society 177, 481506.CrossRefGoogle Scholar
Korshunova, T, Martynov, A, Bakken, T and Picton, B (2017 a) External diversity is restrained by internal conservatism: new nudibranch mollusc contributes to the cryptic species problem. Zoologica Scripta 46, 683692.CrossRefGoogle Scholar
Korshunova, T, Martynov, A, Bakken, T, Evertsen, J, Fletcher, K, Mudianta, IW, Saito, H, Lundin, K, Schrödl, M and Picton, B (2017 b) Polyphyly of the traditional family Flabellinidae affects a major group of Nudibranchia: aeolidacean taxonomic reassessment with descriptions of several new families, genera, and species (Mollusca, Gastropoda). ZooKeys 717, 1139.CrossRefGoogle Scholar
Korshunova, T, Picton, B, Furfaro, G, Mariottini, P, Pontes, M, Prkić, J, Fletcher, K, Malmberg, K, Lundin, K and Martynov, A (2019) Multilevel fine-scale diversity challenges the ‘cryptic species’ concept. Scientific Reports 9, 123.CrossRefGoogle ScholarPubMed
Kumar, S, Stecher, G, Li, M, Knyaz, C and Tamura, K (2018) MEGA X: Molecular Evolutionary Genetics Analysis across computing platforms. Molecular Biology and Evolution 35, 15471549.CrossRefGoogle ScholarPubMed
Layton, KK, Gosliner, TM and Wilson, NG (2018) Flexible colour patterns obscure identification and mimicry in Indo-Pacific Chromodoris Nudibranchs (Gastropoda: Chromodorididae). Molecular Phylogenetics and Evolution 124, 2736.CrossRefGoogle Scholar
Leigh, JW and Bryant, D (2015) Popart: full-feature software for haplotype network construction. Methods in Ecology and Evolution 6, 11101116.CrossRefGoogle Scholar
Lemche, H (1929) Gastropoda Opisthobranchiata. Zoology of Faroes 53, 135.Google Scholar
Linnaeus, C (1767) Systema naturae per regna tria naturae: secundum classes, ordines, genera, species, cum characteribus, differentiis, synonymis, locis. Ed. 12. 1., Regnum Animale. 1 & 2. Holmiae, Laurentii Salvii. Holmiae [Stockholm], Laurentii Salvii, pp. 5331327.Google Scholar
Maddison, WP and Maddison, DR (2018) Mesquite: a modular system for evolutionary analysis. Version 3.51. http://www.mesquiteproject.org.Google Scholar
Marcus Er (1964) A new species of Polycera (Nudibranchia) from California. The Nautilus 77, 128131.CrossRefGoogle Scholar
Martínez-Pita, I and García, FJ (2017) Embryonic abnormalities of two sea slug species from South Spain. Thalassas: An International Journal of Marine Sciences 33, 109115.CrossRefGoogle Scholar
Martínez-Pita, I, Sánchez-España, AI and García, FJ (2006) Some aspects of the reproductive biology of two Atlantic species of Polycera (Mollusca: Opisthobranchia). Journal of the Marine Biological Association of the United Kingdom 86, 391399.Google Scholar
Martynov, AV, Korshunova, TA and Savinkin, OV (2006) Shallow-water opisthobranch molluscs of the Murman coast of the Barents Sea, with new distributional data and remarks on biology. Ruthenica 16, 5972.Google Scholar
Micaroni, V, Strano, F, Di Franco, D, Crocetta, F, Grech, D, Piraino, S and Boero, F (2018) Project ‘Biodiversity MARE Tricase’: a biodiversity inventory of the coastal area of Tricase (Ionian Sea, Italy) – Mollusca: Heterobranchia. European Zoological Journal 85, 179192.Google Scholar
Miller, MC (1961) Distribution and food of the nudibranchiate Mollusca of the South of the Isle of Man. Journal of Animal Ecology 30, 95116.CrossRefGoogle 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, LA, pp. 18. https://www.phylo.org/portal2/login!input.action (Accessed online 2019).CrossRefGoogle Scholar
Moen, FE and Svensen, E (2014) Dyreliv i havet; Nordeuropeisk Marin Fauna, 6th edn. Kristiansund: Kom forlag.Google Scholar
MolluscaBase (eds) (2020) MolluscaBase. Polycera quadrilineata (O. F. Müller, 1776). Accessed through: World Register of Marine Species at: http://www.marinespecies.org/aphia.php?p=taxdetails&id=140838.Google Scholar
Müller, OF (1776) Zoologiae Danicae prodromus: seu Animalium Daniae et Norvegiae indigenarum; characteres, nomina, et synonyma imprimis popularium. Havniae: typis Hallageriis, Copenhagen.CrossRefGoogle Scholar
Müller, OF (1779) Zoologia Danica, seu, Animalium Daniae et Norvegiae rariorum ac minus notorum descriptiones et historia. Hauniae et Lipsiae: Sumtibus Weygandinis, Copenhagen.Google Scholar
Padula, V, Araujo, AK, Matthews-Cascon, H and Schrödl, M (2014) Is the Mediterranean nudibranch Cratena peregrina (Gmelin, 1791) present on the Brazilian coast? Integrative species delimitation and description of Cratena minor n. sp. Journal of Molluscan Studies 80, 575584.CrossRefGoogle Scholar
Padula, V, Bahia, J, Stöger, I, Camacho-García, Y, Malaquias, MAE, Cervera, JL and Schrödl, M (2016) A test of color-based taxonomy in nudibranchs: molecular phylogeny and species delimitation of the Felimida clenchi (Mollusca: Chromodorididae) species complex. Molecular Phylogenetics and Evolution 103, 215229.CrossRefGoogle ScholarPubMed
Palomar, G, Pola, M and Garcia-Vazquez, E (2014) First molecular phylogeny of the subfamily Polycerinae (Mollusca, Nudibranchia, Polyceridae). Helgoland Marine Research 68, 143153.CrossRefGoogle Scholar
Picton, BE and Morrow, CC (1994) A Field Guide to the Nudibranchs of the British Isles. London: Immel Publishing.Google Scholar
Pruvot-Fol, A (1951) Etudes des nudibranches de la Méditerranée 2. Archives de Zoologie Expérimentale et Générale 88, 180.Google Scholar
Puillandre, N, Lambert, A, Brouillet, S and Achaz, G (2012) ABGD, Automatic Barcode Gap Discovery for primary species delimitation. Molecular Ecology 21, 18641877.CrossRefGoogle ScholarPubMed
Rambaut, A (2016) FigTree v1.4.3. Tree figure drawing tool. Software available at http://tree.bio.ed.ac.uk/software/figtree/.Google Scholar
Rudman, WB (1999) Polycera quadrilineata (Müller, 1776). Sea Slug Forum. Australian Museum, Sydney. http://www.seaslugforum.net/factsheet/polyquad (Accessed online 2019).Google Scholar
Schmekel, L, Portmann, A, Richter, I and Bousani-Baur, S (1982) Opisthobranchia des Mittelmeeres; Nudibranchia und Saccoglossa. Berlin: Springer-Verlag.CrossRefGoogle Scholar
Struck, TH, Feder, JL, Bendiksby, M, Birkeland, S, Cerca, J, Gusarov, VI, Kistenich, S, Larsson, K-H, Liow, HL, Nowak, MD, Stedje, B, Bachmann, L and Dimitrov, D (2018) Finding evolutionary processes hidden in cryptic species. Trends in Ecology and Evolution 33, 153163.CrossRefGoogle ScholarPubMed
Telnes, K (2018) Nudibranch – Polycera quadrilineata. SeaWater: The Marine Flora and Fauna of Norway. http://www.seawater.no/fauna/mollusca/quadrilineata.html (Accessed online 2019).Google Scholar
Thompson, TE (1988) Molluscs: benthic opisthobranchs (Mollusca: Gastropoda). Synopses of the British Fauna (New Series) No. 8, 2nd edn. Leiden: Linnean Society and The Estuarine and Brackish-water Sciences Association, E. J. Brill/W. Backhuys.Google Scholar
Thompson, TE and Brown, GH (1984) Biology of Opisthobranch Molluscs, vol. 2. London: The Ray Society.Google Scholar
Todd, CD (1981) The ecology of nudibranch molluscs. Oceanography and Marine Biology: An Annual Review 19, 141233.Google Scholar
Todd, CD (1983) Reproductive and trophic ecology of nudibranch molluscs. The Mollusca: Ecology 6, 225259.Google Scholar
Trainito, E (2005) Nudibranchi del Mediterraneo. Guida ai molluschi opistobranchi. Milan: Il Castello.Google Scholar
Trainito, E and Doneddu, M (2014) Nudibranchi del Mediterraneo. Milan: Edizione Il Castello.Google Scholar
Vondrák, J, Říha, P, Arup, U and Søchting, U (2009) The taxonomy of the Caloplaca citrina group (Teloschistaceae) in the Black Sea region; with contributions to the cryptic species concept in lichenology. The Lichenologist 41, 571604.CrossRefGoogle Scholar
Wilson, NG and Burghardt, I (2015) Here be dragons – phylogeography of Pteraeolidia ianthina (Angas, 1864) reveals multiple species of photosynthetic nudibranchs (Aeolidina: Nudibranchia). Zoological Journal of the Linnean Society 175, 119133.Google Scholar
Figure 0

Fig. 1. Original illustration of Polycera quadrilineata (adapted from O. F. Müller, 1779).

Figure 1

Table 1. Material examined and used for molecular analysis, including sampling locality, habitat, voucher number and GenBank or BOLD accession numbers

Figure 2

Table 2. Inter- and intraspecific (bold font) uncorrected pairwise (p) distances estimated using MEGA X for Polycera species

Figure 3

Fig. 2. Bayesian molecular phylogenetic tree based on the COI gene. Numbers on branches represent posterior probabilities (PPs). Tree rooted with J. tomentosa. Green box refers to P. quadrilineata and purple box to Polycera norvegica sp. nov. Images refer to main morphotypes of these species and specimen depicted across both boxes represents the shared morphotype.

Figure 4

Fig. 3. P. quadrilineata. (A–F) Yellow/orange colour morphotype. (G–M) Striped colour morphotype. (A) Rogaland, Norway, ZMBN 127509, photo by C. Rauch and M. A. E. Malaquias, 2019. (B) Vestland, Norway, ZMBN 127690, photo by C. Rauch, 2019. (C) Rogaland, Norway, ZMBN 125859, photo by C. Rauch and A. Schouw, 2018. (D) Vestland, Norway, ZMBN 127676, photo by C. Rauch, 2019. (E) Vestland, Norway, ZMBN 127683, photo by C. Rauch, 2019. (F) Vestland, Norway, ZMBN 127677, photo by C. Rauch, 2019. (G) Vestland, Norway ZMBN 127678, photo by C. Rauch, 2019. (H) Vestland, Norway, ZMBN 127685, photo by C. Rauch, 2019. (I) Møre and Romsdal, Norway, ZMBN 125635, photo by N. Aukan, 2018. (J) Rogaland, Norway, ZMBN 127476, photo by C. Rauch and M. A. E. Malaquias, 2019. (K) Vestland, Norway, ZMBN 125032, photo by C. G. Sørensen and M. A. E. Malaquias, 2018. (L) Vestland, Norway, ZMBN 125033, photo by C. G. Sørensen and M. A. E. Malaquias, 2018. (M) Rogaland, Norway, ZMBN 125689, photo by E. Svensen, 2017.

Figure 5

Fig. 4. Main morphotypes found in P. quadrilineata. (A, B) Striped morphotype. (C, D) Yellow/orange morphotype. (A) Rogaland, Norway, ZMBN 125689, photo by E. Svensen, 2017. (B) Vestland, Norway, ZMBN 94139, photo by M. A. E. Malaquias, 2013. (C) Aquário dos Mosteiros, Azores, ZMBN 87942, photo by M. A. E. Malaquias, 2011. (D) Viken (Drøbak), Norway, ZMBN 127600, photo by H. Jensen, 2019. Drawings by C. G. Sørensen, 2019.

Figure 6

Fig. 5. Scanning electron micrographs of P. quadrilineata. (A) complete radula (ZMBN 127491). (B) Detailed view of the left side of the radula (ZMBN 125688). (C) Labial cuticle (ZMBN 125688). (D) Detail of central region of labial cuticle (ZMBN 127491). (E) Optical microscopy picture of labial cuticle (ZMBN 127491). (F) Close up of tissue from labial cuticle wall (ZMBN 125688). Scale bars: A = 1 mm, B = 300 μm, C = 500 μm, D = 100 μm, E = 1 mm, F = 30 μm.

Figure 7

Fig. 6. Reproductive system and scanning electron micrographs of the penis of P. quadrilineata. (A) Reproductive system (ZMBN 125688). (B) Whole penis (ZMBN 127491). (C) Detail of penis close to genital aperture (ZMBN 127491). (D) Detail of penile spines (ZMBN 125688). am, ampulla; bc, bursa copulatrix; fglm, female gland mass; hd, hermaphroditic duct; gp, genital pore; p, penis; pr, prostate; rs,  receptaculum seminis; vd, vas deferens; vg, vagina. Scale bars: A = 1 mm, B = 300 μm, C = 100 μm, D = 50 μm.

Figure 8

Fig. 7. Polycera norvegica sp. nov. (A–D) Yellow/orange colour morphotype, (E–H) dotted colour morphotype. (A) Trøndelag, Norway, ZMBN 126023, photo by V. V. Grøtan, 2018. (B) Trøndelag, Norway, ZMBN 126025 (paratype), photo by V. V. Grøtan, 2018. (C) Trøndelag, Norway, ZMBN 126024, photo by V. V. Grøtan, 2018. (D) Rogaland, Norway, ZMBN 127608, photo by O. Meldahl, 2018. (E) Rogaland, Norway, ZMBN 125493 (holotype), photo by A. Schouw and C. Rauch, 2018. (F) Rogaland, Norway, ZMBN 125855, photo by A. Schouw and C. Rauch, 2018. (G) Vestland, Norway, ZMBN 106113, photo by K. Kongshavn and M. A. E. Malaquias, 2015. (H) Vestland, Norway, ZMBN 125917, photo by A. Schouw and C. Rauch, 2018.

Figure 9

Fig. 8. Main morphotypes found in Polycera norvegica sp. nov. (A) Dotted morphotype. (B, C) Yellow/orange morphotype. (A) Vestland, Norway, ZMBN 106113, photo by K. Kongshavn, 2015. (B) Rogaland, Norway, ZMBN 127608, photo by O. Meldahl, 2018. (C) Trøndelag, Norway, ZMBN 126023, photo by V. V. Grøtan, 2018. Drawings by C. G. Sørensen, 2019.

Figure 10

Fig. 9. Scanning electron micrographs of Polycera norvegica sp. nov. (A) Radula (ZMBN 127486). (B) Detailed view of the left side of the radula (ZMBN 127486). (C) Labial cuticle (ZMBN 127486). (D) Close up of tissue from the labial cuticle wall (ZMBN 125492). (E) Labial cuticle (ZMBN 127492). (F) Optical microscopy picture of labial cuticle (ZMBN 125492). Scale bars: A = 1 mm, B = 200 μm, C = 500 μm, D = 20 μm, E = 300 μm, F = 1 mm.

Figure 11

Fig. 10. Reproductive system and scanning electron micrographs of the penis of Polycera norvegica sp. nov. (A) Reproductive system (ZMBN 125492). (B) Whole penis (ZMBN 127486). (C) Detail of penis close to genital aperture (ZMBN 127486). (D) Close up of penile spines (ZMBN 127486). Upper arrow = elongated penile spines. Lower arrow = hook-shaped penile spines. am, ampulla; bc, bursa copulatrix; fglm, female gland mass; hd, hermaphroditic duct; gp, genital pore; p, penis; pr, prostate; rs,  receptaculum seminis; vd, vas deferens; vg, vagina. Scale bars: A = 1 mm, B = 300 μm, C = 100 μm, D = 20 μm.

Figure 12

Fig. 11. TCS haplotype network analysis based on the COI gene generated in the programme PopArt, including sequences from 63 specimens of P. quadrilineata. Lines between black dots represent one mutation, while black dots represent hypothetical haplotypes. Each coloured circle represents a unique haplotype, and the size of each circle indicates how many specimens share that haplotype. Different colours represent geographic locations.

Figure 13

Fig. 12. TCS haplotype network analysis based on the COI gene generated in the program PopArt, including sequences from 17 specimens of Polycera norvegica sp. nov. Lines between black dots represent one mutation, while black dots represent hypothetical haplotypes. Each coloured circle represents a unique haplotype, and the size of each circle indicates how many specimens share that haplotype. Different colours represent geographic locations.

Figure 14

Table 3. Summary of the most useful characters for diagnosis of Polycera quadrilineata and Polycera norvegica sp. nov

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