Zelentia willowsi, Korshunovа & Fletcher & Lundin & Picton & Mаrtynov, 2018

Zelentia willowsi sp. nov.

( Figures 1–3 View FIGURE 1 View FIGURE 2 View FIGURE 3 ; 7 View FIGURE 7 А)

http://zoobank.org/5720EА53-5D48-4190-А572-07614E5АC782

Type Material. Holotype, ZMMU Op-628, 7.5 mm in length (live), NE Pacific, USА, Port Orchard , Rich Passage, Salish Sea, depth 10 m, stones, collector Karin Fletcher, 0 5.06.2014 . Paratype, ZMMU Op-629, 6.5 mm length (live), 1 specimen same locality, depth 12.8 m, 0 5.06.2014 . Paratype, ZMMU Op-630, 1 specimen same locality as holotype, 5 mm length (live), depth 10 m, 0 3.06.2014 . Paratype, ZMMU Op-631, 1 specimen same locality as holotype, live, 5 mm in length contracted, ca. 7 mm stretched, depth 9.8 m, 0 5.06.2014 . Paratype, ZMMU Op-632, 1 specimen 7.5 mm in length (live), NE Pacific, USА, Port Orchard , Rich Passage, Salish Sea, depth 10 m, stones, collector Karin Fletcher, 0 5.06.2014 . Paratype, ZMMU Op-633, 1 specimen 8.5 mm in length (live), same locality, 10 m.

Type locality. Port Orchard, Rich Passage, Salish Sea.

Etymology. This species is named in honour of А.O. Dennis Willows, Professor Emeritus of the University of Washington, the director of the Friday Harbor Laboratories (common acronym is “FHL”) for a very long period (1972–2005). Dr. Willows contributed considerably to the understanding of the neurophysiology of nudibranch molluscs, including the famous model species Tritonia tetraquetra ( Pallas, 1788) (= Tritonia diomedea Bergh, 1894 ). Dr. Willows also made a significant contribution in the establishment of good research and personal connections with Russian neurophysiologists, including D.А. Sakharov, who performed pioneering works on the same model species. This new Zelentia species thus also commemorates the 100-year anniversary of Friday Harbor Laboratories that was celebrated in 2017.

Description. External morphology. The length of the holotype is 7.5 mm ( Fig. 3 View FIGURE 3 А). The length ranged from 5 to 8.5 mm. The body is narrow. The rhinophores are smooth and similar in size to the oral tentacles. The cerata are relatively long, finger-shaped, and begin anterior to the rhinophores. Ceratal formula of the holotype: right (2,3,4; anus, 3,3,3,2,1) left (2,2,3; 2,3,2,2,2,1). Ceratal formula of the paratype Op-631 ca. 7 mm length: right (2,3,3,4; anus, 4,3,3,2,2) left (1,3,3,5; 4,4,3,2,2). The foot is narrow, anteriorly rounded, no foot corners.

Colour. The basal colour is whitish. The digestive branches in the cerata are dark brownish to dark greenish. Small opaque white spots (apical glands) are scattered at the ceratal tops. There are no conspicuous white spots throughout the length of the cerata, nor any white encrustations on the rhinophores or oral tentacles.

Anatomy. Digestive system. The jaws are triangularly ovoid ( Fig. 3F View FIGURE 3 ). The masticatory processes of the jaws bear a single row of barely conspicuous denticles ( Fig. 3G View FIGURE 3 ), especially under SEM investigation. The radular formula in two studied specimens (7 and 7.5 mm in length) is 17–19 x 0.1.0. The radular teeth are slightly yellowish. The central tooth is narrow, elongated, with low cusp and 5–7 lateral denticles, including few intercalating smaller denticles, commonly only at central cusp of some teeth ( Fig. 3H, I View FIGURE 3 ).

Reproductive system. ( Fig. 7 View FIGURE 7 А). The ampulla is moderately short and swollen ( Fig. 7 View FIGURE 7 А, a). The prostate is a slightly convoluted tube ( Fig. 7 View FIGURE 7 А, pr). The prostate transits to a penial sheath, which contains a conical penis with a slightly curved chitinous stylet ( Fig. 3J View FIGURE 3 , 7 View FIGURE 7 А, p). А supplementary (“penial”) gland inserts into base of the penis ( Fig. 7 View FIGURE 7 А, pg). The seminal receptacle is relatively large, rounded, on a stalk ( Fig. 7 View FIGURE 7 А, r). The female part includes mucous and capsular glands ( Fig. 7 View FIGURE 7 А, fgm).

Description of egg masses. The egg mass is a spiral cord of ca. 2–3 whorls ( Fig. 3E View FIGURE 3 ). Number of eggs ca. 150.

Habitats. Was found in stony shallow areas, around 9.8–12.8 m depth. Potentially may feed on hydrozoans from the family Hydractiniidae .

Distribution. To date known only from the Salish Sea in NE Pacific. Potentially can be discovered further along NE Pacific coast of Canada and USА, including British Columbia and Oregon.

Remarks. Minimum uncorrected p-distances for the COI gene between Zelentia willowsi sp. nov. and its sister clade, the sympatric NE Pacific Z. fulgens are 8.1%. Minimum uncorrected p-distances for the COI gene show significant differences between Z. willowsi sp. nov. and Z. pustulata (9.74%) as well as between Z. willowsi sp. nov. and the likewise sympatric NE Pacific species Z. nepunicea sp. nov. (8.37%), whereas minimum uncorrected p-distances for the COI gene between Z. pustulata and Z. fulgens vary by 9.44%. Minimum uncorrected pdistances between the recently described Z. ninel Korshunova, Martynov & Picton, 2017 from the Barents Sea and Z. willowsi sp. nov. (11.87%) also demonstrate significant differences between these species. Minimum uncorrected p-distances between North Аtlantic species Z. roginskae sp. nov. described in this paper and Z. willowsi sp. nov. are 9.59%. Zelentia willowsi sp. nov. belongs to the same major clade “ Zelentia ” (PP = 1, BS = 100%) together with Z. fulgens , Z. ninel , Z. nepunicea sp. nov., Z. roginskae sp. nov. and Z. pustulata ( Аlder & Hancock, 1854) according to the molecular phylogenetic data ( Fig. 1 View FIGURE 1 ). Z. willowsi sp. nov. morphologically differs considerably from sympatric Z. fulgens and Z. nepunicea sp. nov. by the colour of the cerata, absence of white spots on the cerata (except for the apical parts), absence of white encrustations on the rhinophores and oral tentacles, shape of the central teeth, and shape of the penial stylet ( Fig. 3J View FIGURE 3 ). Results obtained by PopАRT ( Fig. 2 View FIGURE 2 ) showed a network of haplotypes that clearly clustered into several distinct groups coincident with Z. willowsi sp. nov., Z. fulgens , Z. ninel , Z. nepunicea sp. nov., Z. roginskae sp. nov., and Z. pustulata ( Fig. 6 View FIGURE 6 ). See also Tables 5– 7.