Huffmanela persica, Ghanei-Motlagh & Fast & Groman & Kumar & Soliman & El-Matbouli & Saleh, 2023

Huffmanela persica View in CoL sp. nov.

Taxonomic summary

Type definitive host: Daggertooth pike conger, Muraenesox cinereus (Forsskål) , Anguilliformes , Muraenesocidae , date of collection, February 2021.

Type locality: Persian Gulf off the coast of Zir Ahak, Bushehr, Iran (28°17’ N, 51°13’ E) GoogleMaps .

Site of infection: Ovary, tunica serosa of stomach ( Fig. 2A View Fig ). Conspicuous masses of eggs of H. persica sp. nov. were observed in the ovaries of all 13 fish infected. Te egg aggregations were simultaneously found in the serosae of stomach of 3 out of 13 fish infected by the nematode. All fish examined were also infected by larval (viscera) and adult (stomach and intestine) forms of anisakids and raphidascaridids. Adult forms (male and female) of H. persica sp. nov. were not observed.

Prevalence: 65% (13 infected out of 20).

Etymology: Te specific name persica (Persian) refers to the country of its occurrence ( Iran).

Molecular characterization: Nucleotide sequences of the 18S rDNA (OQ418445), 28S rDNA (OQ428648) and ITS rDNA (OQ428649) of the new species have been deposited in GenBank.

Deposited specimens: Syntype eggs collected from the host ( M. cinereus ) were deposited in the Helminthological Collection , Institute of Parasitology , Biology Centre of the Czech Academy of Sciences, České Budějovice, Czech Republic (catalog no. N-1277) .

ZooBank registration:

To comply with the regulations set out in article 8.5 of the amended 2012 version of the International Code of Zoological Nomenclature [ 37], details of the new species have been submitted to ZooBank. Te Life Science Identifier (LSID) of the article is urn:lsid:zoobank.org:pub:84ABB846-5AF2-4008-97F6-573A68DFD1BB . Te LSID for the new species name Huffmanela persica is urn:lsid:zoobank.org:act:.

Description of eggs

Grossly visible eggs of H. persica sp. nov. were mostly observed in the form of black aggregates with different dimensions which were randomly distributed in the infected tissues ( Fig. 2B View Fig ). Scalpel scrapings obtained from fresh and fixed egg clusters showed thousands of variously oriented eggs with untinted, brown or black eggshells depending on the stage of development of each egg. Four stages of egg development (from less developed to fully developed eggs) are reported herein based upon morphology and morphometry of eggs as well as embryonic stages of development observed in eggs. Tese include stage I (meiotic stage), stage II (early mitotic embryonated stage), stage III (late embryonated stage) and stage IV (vermiform larvated stage).

Stage I eggs

Stage I eggs ( Figs. 3A, a View Fig ; 4A–D View Fig ; 5H View Fig ) were evidently recently laid eggs in probably meiosis I with a distinctly spherical nucleus mainly located centrally in the granular cytoplasm and no developed or two poorly developed plugs at poles. Eggs in stage I spherical shaped (occasionally shrunken and wrinkled), with light amber rigid eggshell walls and no discernable layering. Egg morphometrics (n = 15) recorded in stage I was as follows: total length (with uterine layer, UL) 34.14–44.32 (38.12 ± 2.97); total length (without UL) 30.51–39.51 (34.06 ± 2.76); total width (with UL) 32.65–41.25 (35.50 ± 2.06); total width (without UL) 30.45–37.20 (32.60 ± 1.72); shell thickness (with UL) 3.27–6.07 (4.74 ± 0.81); shell thickness (without UL) 1.54–2.99 (2.47 ± 0.44); nucleus length 8.2–10.71 (9.24 ± 0.87); nucleus width 7.57–10.08 (8.53 ± 0.74).

Stage II eggs

Stage II represents various stages of early embryonic development within the eggshell from single-cell (probably meiosis II) stage to multiple cell mitotic stages ( Fig. 3B, b; C, c; D, d View Fig ). Eggs in the single-cell stage ( Fig. 3B, b View Fig ) were distinguished by having a spherical nucleus present in the granular cytoplasm and two newly developed polar plugs. Eggs in the two-cell stage ( Fig. 3C, c View Fig ) had a symmetric pattern as the result of the first cell division. Eggs containing multi-cell stages ( Fig. 3D, d View Fig ) showed further development of embryo, where the inner space of the rigid eggshell wall was partly or completely occupied by a multicellular mass. Eggs in stage II were elliptical or oblong, light yellow to light brown, with polar plugs (apparently two-layered) slightly or markedly protruding and no distinct shell layers. Egg morphometrics (n = 40) obtained in stage II: total length (inclusive of protruding polar plugs and UL) 46.79–65.84 (58.26 ± 4.83); total length (exclusive of protruding part of polar plugs and UL) 43.24–61.85 (54.08 ± 4.85); total width (with UL) 31.51–40.80 (35.43 ± 2.23); total width (without UL) 30.35–39.52 (33.57 ± 2.35); shell thickness (with UL) 3.43–8.44 (5.20 ± 1.11); shell thickness (without UL) 2.70–7.57 (4.28 ± 1.14); polar plug width 7.52–15.76 (9.78 ± 1.65).

Stage III eggs

Eggs in stage III ( Fig. 3E, e; F, f View Fig ) demonstrating higher development of embryo were characterized by possessing spatially differentiated forms (bean-like or tadpole-like embryos; Fig. 3E, e; F, f View Fig ), two easily distinguishable apparent shell layers and mild to moderate degrees of embryonic bending within the eggshell. Eggs in stage III elliptical or oblong in shape, brown in color, containing two protruding polar plugs, with bilayer shell inclusive of a thin and light (hyaline) inner layer alongside with a thick and dark outer layer (this layering is an optical illusion under light microscopy caused by the birefringent properties of chitin; see Bond and Huffman, 2023) [ 25]. Morphometric measurements of eggs (n = 27) in stage III are summarized as follows: total length (with protruding polar plugs and UL) 59.39–70.98 (62.44 ± 2.60); total length (without protruding part of polar plugs and UL) 54.75–61.67 (57.39 ± 1.94); total width (with UL) 32.46– 44.75 (34.95 ± 3.03); total width (without UL) 30.62– 43.30 (32.88 ± 3.05); shell thickness (with UL) 3.81–5.73 (4.90 ± 0.52); shell thickness (without UL) 2.92–5.02 (3.77 ± 0.46); polar plug width 8.18–11.09 (9.39 ± 0.68).

Stage IV eggs

Stage IV eggs ( Figs. 3G, g; H, h View Fig ; 4E–I View Fig ; 5G, I View Fig ) were differentiated by having brown to dark-brown color, oblong or elliptical shape, varying degrees of larval formation within egg from threefold stage (pretzel, Fig. 3G, g View Fig ) to five–sixfold stage (fully developed larva, Fig. 3H, h View Fig ), dark outer layer much thicker in width and two distinctly protruding polar plugs. Morphometric data obtained from stage IV eggs (n = 71) were as follows: total length (with protruding polar plugs and UL) 60.37–75.13 (66.62 ± 3.04); total length (without protruding part of polar plugs and UL) 54.37–67.86 (62.03 ± 2.94); total width (with UL) 32.54–44.63 (36.46 ± 2.65); total width (without UL) 30.96–43.39 (34.41 ± 2.78); shell thickness (with UL) 4.48–7.17 (5.63± 0.53); shell thickness (without UL) 3.51–6.11 (4.63 ± 0.55); polar plug width 8.43–12.00 (10.29 ± 0.79); larval width in fully developed eggs 6.09–9.16 (7.91 ± 0.61); larval length (n = 17) in fully developed eggs 196.27–231.49 (209.51 ± 10.64).

Egg surface ornamentations

Te rigid eggshell wall (or its integral outermost layer, Pellicula Ovi ) at all stages adorned with irregular protuberances on the surface ( Fig. 4B–D, H, I View Fig ). Eggs thoroughly surrounded by a thin transparent UL decorated with closely and regularly spaced mammiform mounds (superficial projections, Figs. 3 I–T View Fig , 4B–D, F, G View Fig ) appearing to form pointed serrated-like ridges ( Fig. 3J, N, R View Fig ) (occasionally appearing as interconnecting ridges; Figs. 3J View Fig , 4D View Fig ) on the egg surface (the appearance of ridges is most likely a geometric illusion; see Figs. 1–3 View Fig View Fig View Fig , 7, 8 of Žďárská et al. 2001, Fig. 30 of Bond, 2020 and Fig. 24 of Bond and Huffman, 2023) [ 25], resulting in manifestation of a fine superficial sculpture on the surface of eggs examined with light microscope ( Fig. 3K, O, S View Fig ). UL mammiform mounds predominantly with a tendril-like vermiform appendage extending from the tip, sometimes adjoined to that of a neighboring mound ( Fig. 4A–F View Fig ).

Pathological lesions

Te serosal surface of the stomach in infected fish contained eggs of H. persica sp. nov. at various stages of development ( Fig. 5A–D View Fig ) and degenerated encapsulated metazoans ( Fig. 5A, B View Fig ; more likely larval forms of Anisakis and less likely adult forms of Huffmanela as the females are usually extremely long, are rarely found encapsulated and are not much thicker than the eggs), all of which were enclosed in a fibro-granulomatous infiltrate. Ovigerous lamellae of the ovary were infected with nests of developing eggs from the nematode H. persica . Te eggs were located within both clusters of immature and previtellogenic oocytes and the connective tissue of the lamellae and encased by a fibro-granulomatous infiltrate containing both histiocytes and eosinophilic granular leukocytes ( Fig. 5E, F View Fig ).

Gene characterization and phylogenetic analysis Sequencing of purified PCR products of 18S, 28S and ITS regions from H. persica sp. nov. resulted in DNA fragments with different lengths (855 bp, 1264 bp and 1127 bp, respectively). Te BLAST analysis revealed that 18S rDNA gene sequence of H. persica sp. nov. shared 93–96% identity (ID) and 83–96% query coverage (QC) with Huffmanela species collected from freshwater bony fish including H. cf. huffmani of Bullard et al., 2022 (ON838248, 93.12% ID and 96% QC), H. huffmani (ON838249, 94.62% ID and 88% QC), H. huffmani (ON838251, 96.08% ID and 83% QC) and H. cf. huffmani (ON838247, 95.80% ID and 83% QC) and 86–89% ID and 81–95% QC with those isolated from marine cartilaginous fish including Huffmanela sp. (ON838247, 86.28% ID and 95% QC) and Huffmanela markgracei Ruiz and Bullard, 2013 (ON838250, 89.38% ID and 81% QC). According to the ML tree generated from 18S rDNA sequences ( Fig. 6 View Fig ), H. persica was not grouped with previously reported species of Huffmanela . However, a sister relationship was recovered between the new species of marine origin with freshwater species of Huffmanela ( H. huffmani and H. cf. huffmani ), all of which are known to infect teleost fish. A sister group relationship was also found between Huffmanela species infecting teleost fish ( H. huffmani , H. cf. huffmani and H. persica ) with those parasitizing elasmobranch fish ( H. markgracei and Huffmanela sp. ). Phylogenetic analysis based on 18S rDNA dataset strongly corroborated monophyly of the subfamily Huffmanelinae ( Fig. 6 View Fig ).