Hostname: page-component-745bb68f8f-v2bm5 Total loading time: 0 Render date: 2025-02-11T04:17:17.490Z Has data issue: false hasContentIssue false
  • English
  • Français

Study of two species, one new and one known, of the genus Aporcella Andrássy, 2002 (Dorylaimida, Aporcelaimidae) from Iran, with a note on its phylogeny

Published online by Cambridge University Press:  19 June 2020

A. Naghavi ,
G. Niknam Open the ORCID record for G. Niknam [Opens in a new window] ,
N. Vazifeh  and
R. Peña-Santiago
A. Naghavi
Affiliation:
Department of Plant Pathology, College of Agriculture, Lorestan University, Khoramabad, Iran
G. Niknam*
Affiliation:
Department of Plant Protection, Faculty of Agriculture, University of Tabriz, Tabriz, Iran
N. Vazifeh
Affiliation:
Department of Plant Protection, Faculty of Agriculture, University of Tabriz, Tabriz, Iran
R. Peña-Santiago
Affiliation:
Departamento de Biología Animal, Biología Vegetal y Ecología, Universidad de Jaén, Campus ‘Las Lagunillas’ s/n, Edificio B3, 23071Jaén, Spain
*
Author for correspondence: G. Niknam, E-mail: g_niknam@tabrizu.ac.ir
Rights & Permissions [Opens in a new window]

Abstract

Two species of the genus Aporcella, one new and one previously known, collected from cultivated fields in Iran are studied. Description, morphometrics, illustrations (both line and microphotographs) and D2–D3 sequences are provided for Aporcella talebii sp. n., which is characterized by its 1.66–2.02-mm-long body, lip region offset by constriction and 15–17 μm broad, odontostyle 14–17.5 μm long, neck 412–484 μm long, pharyngeal expansion occupying 46–50% of total neck length, uterus simple and 1.6–2.0 times the corresponding body diameter long, V = 52–59, tail conical (40–50 μm, c = 37–47, c′ = 1.1–1.4) with a weak but perceptible dorsal concavity at the end and male absent. Morphometrics, microphotographs and D2–D3 sequences of Aporcella simplex are also presented, this being its first Asian record. Molecular analyses confirm the monophyly of the genus, its close relationship with other taxa lacking pars refringens vaginae and the polyphyly of Aporcelaimidae.

Keywords

Aporcella talebii sp. nAporcella simplexBayesian inference28S rDNAmorphologymorphometricstaxonomy
Type
Research Paper
Information
Journal of Helminthology , Volume 94 , 2020 , e164
Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press

Introduction

The taxonomical history of the genus Aporcella Andrássy, 2002 is relatively short, but interesting. Originally created to accommodate its type (and then only) species, Aporcella gibberocaudada from Chile, it was classified under the family Aporcelaimidae Heyns, 1965. Later, Andrássy (Reference Andrássy2009) transferred Aporcelaimellus parapapillatus Botha & Heyns, 1990 from South Africa to it. Again, Andrássy (Reference Andrássy2012) described the new species Aporcella magna from Chile too, and transferred Aporcelaimus pseudospiralis Botha & Heyns, 1990, also from South Africa, to Aporcella. Álvarez-Ortega et al. (Reference Álvarez-Ortega, Subbotin and Peña-Santiago2013) proposed a new concept for the genus, including the first molecular analysis of one of its species, Aporcella simplex (Thorne & Swanger, 1936) Álvarez-Ortega, Subbotin & Peña-Santiago, 2013, which resulted in a new approach to the evolutionary relationships of the group since it did not share a recent common ancestor with other aporcelaims. Two new members were subsequently added to the genus catalogue – namely, Aporcella charidemiensis Álvarez-Ortega & Peña-Santiago, 2016 from Spain, and Aporcella malekimilanii Naghavi, Niknam, Vazifeh & Peña-Santiago, 2019 from Iran. Molecular data of these two species confirmed previous results about the evolutionary relationships of the group.

This is the second contribution devoted to characterize Iranian Aporcella species after the previous one (Naghavi et al., Reference Naghavi, Niknam, Vazifeh and Peña-Santiago2019) dealing with the description of A. malekimilanii and Aporcella vitrinus (Thorne & Swanger, 1936) Álvarez-Ortega, Subbotin & Peña-Santiago, 2013. It pursues the study of two members of the genus, one new and one known, including their molecular analyses and a discussion of their evolutionary relationships.

Materials and methods

Soil sampling

Soil samples were taken from a depth of 5 to 30 cm in rhizosphere of fruit trees and common wheat in East Azarbaijan province, Iran, during 2015 to 2016. Nematodes were extracted from 500 cm3 of soil using the modified method of Brown & Boag (Reference Brown and Boag1988).

Processing and examination of nematodes

The extracted nematodes were relaxed and killed by heat, fixed and transferred to dehydrated glycerine according to De Grisse's (Reference De Grisse1969) method, and mounted on permanent glass slides for handling. The specimens were examined and measured with an Olympus BX41 light microscope, Olympus Corporation, Shinjuku, Tokyo, Japan equipped with differential interference contrast optics and a drawing tube attached to it. Morphometrics include Demanian indices and other usual ratios and measurements, the most important of which are presented in table 1. Microphotographs were taken using a DP50 digital camera, Olympus Corporation, Shinjuku, Tokyo, Japan attached to the same light microscope and edited by Adobe® Photoshop® software, www.ir-tci.org. Line drawings were prepared based on the digital images using CorelDRAW® software, version 12, www.designer.com.

Table 1. Morphometrics of Aporcella talebii sp. n.

All measurements are in μm (except L in mm) and in the form: mean ± standard deviation (range).

L = body length; a = body length/maximum body diameter; b = body length/neck length; c = body length/tail length; c′ = tail length/body diameter at anus; V = distance vulva-anterior end × 100/body length.

Molecular identification

Nematode DNA was extracted from three to four individuals and polymerase chain reaction (PCR) assays were conducted as described by Archidona-Yuste et al. (Reference Archidona-Yuste, Navas-Cortés, Cantalapiedra-Navarrete, Palomares-Rius and Castillo2016). The D2–D3 segments were amplified using the D2A (5′-ACAAGTACCGTGAGGGAAAGTTG-3′) and D3B (5′-CGGAAGGAACCAGCTACTA-3′) primers (Nunn, Reference Nunn1992). PCR products were purified after amplification using a Thermo Scientific GeneJET Gel Extraction Kit (Fermentas), Carlsbad, California, USA according to the procedure recommended by the manufacturer, and used for sequencing in both direction by D2A and D3B primers.

The PCR cycle conditions were as follows: one cycle of 94°C for 2 min, followed by 35 cycles of 94°C for 30 s, annealing temperature of 55°C for 45 s, 72°C for 3 min and finally one cycle of 72°C for 10 min. The purified PCR products were sent for sequencing to the Bioneer Company in South Korea. The nematode sequences obtained in this study were deposited in the GenBank database under accession numbers MH727511 and MH727515 for Aporcella talebii sp. n. and MH727506, MH727512, MH727513 and MH727514 for A. simplex.

Phylogenetic analyses

D2–D3 segments, partial 28S ribosomal DNA (rDNA) of previously deposited Aporcelaimidae Heyns, 1965 representatives and some other nematodes belonging to closely related families were obtained from the GenBank database and used for phylogenetic reconstruction. Outgroup taxa for the dataset were chosen following early published studies (Álvarez-Ortega & Peña-Santiago, Reference Álvarez-Ortega and Peña-Santiago2016; Peña-Santiago & Varela, Reference Peña-Santiago and Varela2017). The newly obtained and previously published sequences were aligned using MEGA6 software (Tamura et al., Reference Tamura, Stecher, Peterson, Filipski and Kumar2013). Phylogenetic analysis of the sequences datasets were performed based on Bayesian inference (BI) using MrBayes 3.1.2, https://bioweb.psteur.fr/packages/pack@mrbayes@3.1.2. The best-fitted model of DNA evolution was obtained using MrModel test 2.3 (Nylander, Reference Nylander2004) with Akaike-supported model in conjunction with PAUP* version 4.0b10 (Swofford, Reference Swofford2003). BI analysis under a general time-reversible of invariant sites and gamma-shaped distribution (GTR + I + G) model for the D2–D3 expansion segment of the 28S rDNA gene was done. The BI analysis was run using four Metropolis-coupled Markov Monte Carlo for 1 × 108 generation. Two runs were performed for each analysis. After discarding burn-in samples and evaluating convergence, the remaining samples were retained for further analysis. Posterior probabilities are given on the appropriate clade. The tree was visualized using Fig Tree version 1.4.2 and edited with Adobe Illustrator 19.0.9, http://tree.bio.ed.ac.uk/software/figtree/

Results

Aporcella talebii sp. n.

Material examined

Twelve females from two locations, in a good state of preservation (figs 1 and 2).

Fig. 1. Aporcella talebii sp. n.: (A) neck region; (B) amphidial pouch; (C) anterior end; (D) entire body; (E) posterior genital branch; (F) posterior body region; (G) lateral chord.

Fig. 2. Aporcella talebii sp. n.: (A) anterior end; (B) amphidial pouch; (C) neck region; (D) entire body; (E) pharyngo–intestinal junction; (F) posterior genital branch; (G) vagina; (H) lateral chord; (I) posterior body region. Scale bars: (a–i) 10 μm; (d) 60 μm.

Measurements

The measurements are presented in table 1.

Description

  • Female. Moderately slender to slender (a = 27–37) nematodes of medium size, 1.66–2.02 mm long. Body cylindrical, tapering toward both ends but more so towards the posterior end as the tail is conical. Upon fixation, body curved ventrad, from an open to a closed C. Cuticle two-layered, 2–3 μm thick at anterior region, 3–5 μm in mid-body and 4.5–6.5 μm on tail; outer layer thin and with constant thickness throughout the body, with an apparently smooth surface; inner layer visibly thicker than the outer one, especially perceptible at caudal region. Lateral chord 8–10.5 μm broad at mid-body, occupying 14–17% of the corresponding body diameter, bearing glandular bodies throughout the body. One ventral and two dorsal body pores usually present at level of odontostyle, plus odontophore in some specimens. Lip region angular, offset from the adjacent body by a constriction, 3.0–3.5 times as wide as high and about one-third (28–34%) of body diameter at neck base; lips moderately separate, with protruding labial and cephalic papillae. Amphidial fovea cup-shaped, its opening 7.5–9 μm broad or 50–60% of lip region diameter. Odontostyle typical of the genus, strong, nearly equal in length (0.9–1.1 times) to lip region diameter, its aperture 9–11 μm or 62–68% of its total length. Odontophore rod-like, 1.4–1.8 times as long as the odontostyle. Guiding ring single, plicate, located at 7–11 μm from the anterior end. Nerve ring at 31–39% of neck length from anterior end. Pharynx entirely muscular, its anterior section gradually enlarging into the basal expansion that is 7.9–8.3 times longer than wide, 3.6–4.1 times longer than body diameter at neck base and occupies up to one half (46–50%) of the total neck length, with gland nuclei situated as follows: DN = 59–60; S1N1 = 68–70; S1N2 = 77–79; S2N = 88–91. Cardia hemispherical to conoid, 13–15 × 8.7–9.5 μm. Reproductive system didelphic–amphidelphic, with both branches equally and well developed, the anterior 287–369 μm or 16–22% of body length, the posterior one 276–387 μm or 16–21% of body length: ovaries comparatively small, in general not reaching the uterus–oviduct junction, anterior 78–109 μm and posterior 75–118 μm long, with oocytes arranged first in two or more rows, then in a single row in the maturation zone; oviduct 108–133 μm (anterior) and 98–137 μm (posterior), consisting of slender part and well-developed pars dilatata with visible lumen; sphincter present at oviduct–uterus junction; uterus a simple, tube-like structure 89–124 μm long or 1.6–2.0 times the corresponding body diameter long; vagina extending inwards 22–37 μm, reaching 38–47% of body diameter, consisting of pars proximalis 14–25 × 16–22 μm with somewhat sigmoid walls and surrounded by developed musculature, and pars distalis 4–9 μm long. Gland cells present on both sides of vagina. Vulva a transverse slit. Prerectum 1.3–2.8, rectum 0.7–1.4 times the anal-body diameter long. Tail conical with finely rounded terminus, ventrally nearly straight, dorsally first convex and then bearing a more or less conspicuous concavity, sometimes with subdigitate outline, inner cuticle continuous but not reaching the tail tip – thus, a short but perceptible terminal hyaline portion exists; caudal pores at about the middle of the tail, one nearly lateral, other subdorsal.

  • Male. Not found, and females do not contain sperm cells.

Molecular characterization

Two sequences of the D2–D3 28S rDNA gene comprising about 800 bp long from two specimens belonging to different populations were obtained and deposited at the GenBank (accession numbers MH727515 and MH727511). In pairwise-distance analysis, two sequences showed seven nucleotide differences and 99% similarity. .

Diagnosis and relationships

The new species is characterized by its 1.66–2.02-mm-long body, lip region offset by constriction and 15–17 μm broad, odontostyle 14–17.5 μm or 0.9–1.1 times the lip region diameter, neck 412–484 μm long, pharyngeal expansion 209–231 μm long or 46–50% of total neck length, female genital system didelphic–amphidelphic, uterus a simple tube 89–124 μm long or 1.6–2.0 times the corresponding body diameter long, vulva a somewhat posterior (V = 52–59) transverse slit, tail conical (40–50 μm, c = 37–47, c′ = 1.1–1.4) with a weak but perceptible dorsal concavity at the end and male absent.

Aporcella talebii sp. n. is very similar to A. malekimilanii Naghavi, Niknam, Vazifeh & Peña-Santiago, 2019, another Iranian, recently described species, from which it can be easily distinguished by its much shorter pharyngeal expansion (209–231 vs. 300–375 μm, 46–50 vs. 58–63% of total neck length) and, consequently, much more posterior position of pharyngeal gland nuclei (DN = 59–60 vs. 50–52; S1N1 = 68–70 vs. 59–61; S1N2 = 77–79 vs. 70–73; S2N = 88–91 vs. 81–86). In addition, it shows a generally smaller-sized body (1.6–2.0 vs. 1.9–2.7 mm long; neck 412–484 vs. 476–619 μm; prerectum 55–84 vs. 105–178 μm). The new species also resembles Aporcella capitulum (Shahina, Musarrat & Siddiqi, 2005) Álvarez-Ortega, Subbotin & Peña-Santiago, 2013 and Aporcella salsa (Andrássy, 2010) Álvarez-Ortega, Subbotin & Peña-Santiago, 2013. It differs from A. capitulum, only known from Pakistan, by its narrower lip region (15–17 vs. 17.5–20 μm), longer neck (412–484 vs. 356–402 μm), significantly different female tail shape (conical with a dorsal concavity vs. regularly convex conoid) and male absent (vs. as frequent as female). From A. salsa, a North American species, by its more slender body (a = 27–37 vs. 24–26), narrower lip region (15–17 vs. 19–20 μm), shorter odontostyle (14–17.5 vs. 18–19 μm), posteriorly located vulva (V = 52–59 vs. 46–52) and somewhat different tail shape (finely rounded vs. more rounded tip, presence vs. absence of a perceptible dorsal concavity and less vs. more developed terminal hyaline portion or lacuna).

Type locality and habitat

Iran, East Azarbaijan province, Sufiyan, Roodghat area, Zeinabad village (GPS coordinates: 38°18′00″N, 46°07′08″E, altitude 1540 m above sea level (a.s.l.)), from the rhizosphere of common wheat (Triticum aestivum L.).

Other locality and habitat

Iran, East Azarbaijan province, Osku, Teymourlu (GPS coordinates: 37°44′35″ N, 45°57′30″E, altitude 1456 m a.s.l.), from the rhizosphere of ‘Red Delicious’ apple (Malus domestica L.).

Type material

Female holotype female and two female paratypes deposited at the Nematode Collection of the Faculty of Agriculture, University of Tabriz, Tabriz, Iran. Four female paratypes with the Nematode Collection of the University of Jaén, Spain.

Etymology

The new species is named in honour of the late Dr Parviz Talebi Chaichi, Associate Professor of Insect Ecology, Department of Plant Protection, Faculty of Agriculture, University of Tabriz, Tabriz, Iran.

Aporcella simplex (Thorne & Swanger, 1936) Loof & Coomans, 1970

Material examined

Twenty females from four locations, in a good state of preservation (fig. 3).

Fig. 3. Aporcella simplex (Thorne & Swanger, 1936) Loof & Coomans, 1970 anterior end, amphidial pouch, vaginae, posterior body region and lateral chord of populations from (A–F) Azarbaijan Shahid Madani University Campus; (G–L) Sheikh Hassan; (M–R) Firooz Salar; and (S–X) Mamaghan, respectively. Scale bars: 10 μm.

Measurements

The measurements are presented in table 2.

Table 2. Morphometrics of the Iranian populations of Aporcella simplex.

All measurements are in μm (except L in mm) and in the form: mean ± standard deviation (range).

L = body length; a = body length/maximum body diameter; b = body length/neck length; c = body length/tail length; c′ = tail length/body diameter at anus; V = distance vulva-anterior end × 100/body length.

Molecular characterization

Four sequences (MH751506, MH751512, MH751513 and MH751514) c. 800 bp long of D2–D3 expansion segments of the 28S rDNA gene were obtained from four specimens belonging to different populations. In pairwise distance analysis, the three sequences MH727512, MH727513 and MH727514 showed 100% similarity, with no inter-population variation. Nevertheless, the MH727506 sequence presented a 2 bp difference, with 99% similarity to the other sequences.

Distribution

Four populations of this species were collected in four Iranian places: (i) East Azarbaijan province, Tabriz, Sheikh Hassan village (GPS coordinates: 38°01′37″N, 46°06′30″E, altitude 1315 m a.s.l.), in the rhizosphere of silver berry (Elaeagnus angustifolia L.); (ii) Mamaghan region, Azarshahr (37°49′39″N, 45°58′17.2″E, altitude 1304 m a.s.l.), in the rhizosphere of walnut (Juglans regia L.); (iii) Azarbaijan, Tabriz, Shahid Madani University Campus (37°48′39″N, 45°56′00″E, altitude 1338 m a.s.l.), in the rhizosphere of white mulberry (Morus alba L.); and (iv) Azarshahr, Gugan, Firooz Salar (37°47′47″N, 45°56′10.2″E, altitude 1340 m a.s.l.), in the rhizosphere of silver berry (E. angustifolia).

Remarks

Some inter-population variations were noted in the Iranian specimens of A. simplex. Thus, females from Azarbaijan Shahid Madani University Campus show a narrower (17.5–19 vs. 20–23 μm) but more expanded lip region, a shorter odontostyle (15–17 vs. 18–22 μm) and odontophore (27–29 vs. 34–38 μm) and a comparatively longer tail (c = 31–35 vs. c = 39–67, c′ = 1.3–1.5 vs. c′ = 0.7–1.2) than those of other populations, and the Mamaghan population has a less convex and somewhat shorter tail. These intraspecific variations, together with those observed in the D2–D3 sequences, are probably due to the influence of environmental conditions. Nevertheless, all of them fit well those previously known in the populations from the USA and Spain (Álvarez-Ortega et al., Reference Álvarez-Ortega, Subbotin and Peña-Santiago2013), with very similar morphology and either totally coincident or widely overlapping morphometrics. The molecular analyses also confirm the identity of the Iranian specimens.

The finding of A. simplex in Iran is a remarkable biogeographical novelty, as it represents the first Asian record of the species, which significantly extends its spread since it was previously known to occur in Jamaica (Thorne & Swanger, Reference Thorne and Swanger1936; Andrássy, Reference Andrássy2001), the USA (Thorne & Swanger, Reference Thorne and Swanger1936; Loof & Coomans, Reference Loof and Coomans1970; Tjepkema et al., Reference Tjepkema, Ferris and Ferris1971; Baird & Bernard, Reference Baird and Bernard1984; Andrássy, Reference Andrássy2001; Álvarez-Ortega & Peña-Santiago, Reference Álvarez-Ortega and Peña-Santiago2010; Álvarez-Ortega et al., Reference Álvarez-Ortega, Subbotin and Peña-Santiago2013) and several European countries – namely, Austria (Zolda, Reference Zolda2002), Bulgaria (Ilieva et al., Reference Ilieva, Iliev and Georgieva2017), France (Loof & Coomans, Reference Loof and Coomans1970; Domowska, Reference Domowska2000; Andrássy, Reference Andrássy2001), Italy (Loof & Coomans, Reference Loof and Coomans1970; Andrássy, Reference Andrássy2001), the Netherlands (Loof & Coomans, Reference Loof and Coomans1970; Bongers, Reference Bongers1988; Andrássy, Reference Andrássy2001), Poland (Winizewska-Slipinska, Reference Winizewska-Slipinska1987), Spain (Álvarez-Ortega et al., Reference Álvarez-Ortega, Subbotin and Peña-Santiago2013) and ?Switzerland (Altherr, Reference Altherr1950, Reference Altherr1952). Thus, the species certainly is a typical representative of the Holarctic nematode fauna.

Notes on the phylogeny of Aporcella

As derived from the molecular analyses, the evolutionary relationships of the two species herein studied with its congeners and other dorylaims are represented in the tree of fig. 4. All Aporcella sequences, 15 in total, form a recognizable clade, supporting (83%) the monophyly of the genus. The Aporcella clade is divided into two subclades, one (support 100%) corresponding to six A. simplex sequences, two Californian and four Iranian, another (95%) consisting of nine sequences of four (one Iberian and three Iranian) species. Regarding the external relationships of Aporcella, the same tree shows that it forms a highly supported (100%) clade with discolaims and tylencholaims, and that it does not share a (most) recent ancestor with other aporcelaims, which are separated in two subclades: Sectonema plus Metaporcelaimus on the one side, and Aporcelaimellus plus Makatinus on the other side. These results (once more) confirm the previous ones presented by several authors (Álvarez-Ortega et al., Reference Álvarez-Ortega, Subbotin and Peña-Santiago2013; Álvarez-Ortega & Peña-Santiago, Reference Álvarez-Ortega and Peña-Santiago2016; Naghavi et al., Reference Naghavi, Niknam, Vazifeh and Peña-Santiago2019) regarding the monophyly of Aporcella, its close relationships with other genera lacking a distinct pars refringens vaginae and the polyphyly of aporcelaims as traditionally conceived.

Fig. 4. Bayesian inference tree from the known and newly sequenced Aporcella talebii sp. n. and A. simplex based on sequences of the 28S rDNA region. Posterior probability and bootstrap values exceeding 50% are given on appropriate clades. Scale bar shows the number of substitutions per site. Newly obtained sequences are in bold letters.

Financial support

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

Conflicts of interest

There is no conflicts of interest in this work.

References

Altherr, E (1950) Les nématodes du Parc National Suisse (Nématodes libres du sol). Ergebnisse der wissenschaftlichen Untersuchung des schweiszerischen Nationalparks 22, 346.Google Scholar
Altherr, E (1952) Les nématodes du Parc National Suisse (Nématodes libres du sol). 2e partie. Ergebnisse der wissenschaftlichen Untersuchung des schweiszerischen Nationalparks 26, 315356.Google Scholar
Álvarez-Ortega, S and Peña-Santiago, R (2010) Studies on the genus Aporcelaimellus Heyns, 1965 (Dorylaimida: Aporcelaimidae). Four species originally described by Thorne and Swanger in 1936. Nematology 12, 587607.CrossRefGoogle Scholar
Álvarez-Ortega, S and Peña-Santiago, R (2016) Aporcella charidemiensis sp. n. (Dorylaimida: Aporcelaimidae) from the southern Iberian Peninsula, with comments on the phylogeny of the genus. Nematology 18(7), 811821.CrossRefGoogle Scholar
Álvarez-Ortega, S, Subbotin, SA and Peña-Santiago, R (2013) Morphological and molecular characterisation of Aporcelaimellus simplex (Thorne & Swanger, 1936) Loof & Coomans, 1970 and a new concept for Aporcella Andrássy, 2002 (Dorylaimida: Aporcelaimidae). Nematology 15, 165178.CrossRefGoogle Scholar
Andrássy, I (2001) A taxonomic review of the genera Aporcelaimus Thorne & Swanger, 1936 and Metaporcelaimus Lordello, 1965 (Nematoda, Aporcelaimidae). Opuscula Zoologica Budapestinensis 33, 747.Google Scholar
Andrássy, I (2002) New genera and species of nematodes from southern Chile. Opuscula Zoologica Budapestensis 34, 522.Google Scholar
Andrássy, I (2009) Free-living nematodes of Hungary. III. Pedozoologica Hungarica n° 5. Budapest, Hungary, Hungarian Natural History Museum, 608 pp.Google Scholar
Andrássy, I (2010) Two new species of Aporcelaimellus (Nematoda: Dorylaimida) from the Americas. Acta Zoologica Academiae Scientiarum Hungaricae 56, 18.Google Scholar
Andrássy, I (2012) Two new species of the family Aporcelaimidae (Nematoda: Dorylaimida). Acta Zoologica Academiae Scientiarum Hungaricae 23(1), 189199.Google Scholar
Archidona-Yuste, A, Navas-Cortés, JA, Cantalapiedra-Navarrete, C, Palomares-Rius, JE and Castillo, P (2016) Cryptic diversity and species delimitation in the Xiphinema americanum-group complex (Nematoda: Longidoridae) as inferred from morphometric and molecular markers. Zoological Journal of the Linnean Society 176(2), 231265.CrossRefGoogle Scholar
Baird, SM and Bernard, EC (1984) Nematode population and community dynamics in soybean-wheat cropping and tillage regimes. Journal of Nematology 16, 379386.Google ScholarPubMed
Bongers, T (1988) De Nematoden van Nederland. Utrecht, The Netherlands, KNNV, 408 pp.Google Scholar
Botha, A and Heyns, J (1990) Aporcelaimidae (Nematoda: Dorylaimida) from the Kruger National Park. Koedoe 33, 2746.Google Scholar
Brown, DJF and Boag, B (1988) An examination of methods used to extract virus-vector nematodes (Nematoda: Longidoridae and Trichodoridae) from soil samples. Nematologia Mediterranea 16, 9399.Google Scholar
De Grisse, AT (1969) Redescription ou modification de quelques techniques utilisées dans l’étude des nematodes phytoparasitaires. Mededelingen Rijksfakulteit Landbowwetenschappen Gent 34, 351369.Google Scholar
Domowska, E (2000) Nematode communities in subalpine meadows in Central Pyrenees. Annales Zoologici 50, 211220.Google Scholar
Heyns, J (1965) On the morphology and taxonomy of the Aporcelaimidae, a new family of dorylaimoid nematodes. Entomology Memoirs, Department of Agricultural Technical Services, Republic of South Africa 10, 151.Google Scholar
Ilieva, ZI, Iliev, IL and Georgieva, VG (2017) New data on nematodes of the families Aporcelaimidae, Paraxonchidae, Qudsianematidae and Dorylaimidae based on examinations of a Raspberry Plantation in Bulgaria. Acta Zoologica Bulgarica 69(2), 171192.Google Scholar
Loof, PAA and Coomans, A (1970) On the development and location of the oesophageal gland nuclei in Dorylaimina. pp. 79–161 in Proceedings of the IX International Nematology Symposium, Warsaw, Poland, 1967.Google Scholar
Naghavi, A, Niknam, G, Vazifeh, N and Peña-Santiago, R (2019) Morphological and molecular characterisation of two species of Aporcella Andrássy, 2002 (Nematoda: Dorylaimida: Aporcelaimidae) from Iran, with new insights into the phylogeny of the genus. Nematology 21, 655665.CrossRefGoogle Scholar
Nunn, GB (1992) Nematode Molecular Evolution. An Investigation of Evolutionary Patterns among Nematodes based on DNA Sequences. Nottingham, UK, University of Nottingham.Google Scholar
Nylander, JAA (2004) MrModeltest v2. Program Distributed by the Author. Sweden, Uppsala University, Evolutionary Biology Centre.Google Scholar
Peña-Santiago, R and Varela, I (2017) Taxonomy and systematics of the genus Makatinus Heyns, 1965 (Nematoda: Dorylaimida: Aporcelaimidae). Journal of Nematology 49, 245253.CrossRefGoogle Scholar
Shahina, F, Musarrat, AR and Siddiqi, MR (2005) Discolaimium capitulum sp. n., and observation on D. brachyurum Siddiqi and D. upum Baqri & Jairajpuri (Nematoda: Dorylaimida). Pakistan Journal of Nematology 23, 2940.Google Scholar
Swofford, DL (2003) PAUP*: phylogenetic analysis using parsimony (*and other methods), version 4.0b 10. Sunderland, MA, Sinauer Associates.Google Scholar
Tamura, K, Stecher, G, Peterson, D, Filipski, A and Kumar, S (2013) MEGA6: molecular evolutionary genetics analysis version 6.0. Molecular Biology and Evolution 30, 27252729.CrossRefGoogle ScholarPubMed
Thorne, G and Swanger, HH (1936) A monograph of the nematode genera Dorylaimus Dujardin, Aporcelaimus n. g., Dorylaimoides n. g. and Pungentus n. g. Capita Zoologica 6, 1223.Google Scholar
Tjepkema, JP, Ferris, VR and Ferris, JM (1971) Review of the genus Aporcelaimellus Heyns, 1965 and six species groups of the genus Eudorylaimus Andrássy, 1959 (Nematoda: Dorylaimida). Purdue University Agricultural Experiment Station Research Bulletin 882, 1–52.Google Scholar
Winizewska-Slipinska, G (1987) The free-living soil nematodes (Nematoda) of the Swietokrzyskie Mountains. Fragmenta Faunistica 31, 1141.Google Scholar
Zolda, P (2002) Untersuchungen zur Nematodenfauna der Trockenrasen im Nationalpark Neusiedler See – Seewinkel. Verhandlungen der Zoologisch-Botanischen Gesellschaft Österreich 139, 5358.Google Scholar
Figure 0

Table 1. Morphometrics of Aporcella talebii sp. n.

Figure 1

Fig. 1. Aporcella talebii sp. n.: (A) neck region; (B) amphidial pouch; (C) anterior end; (D) entire body; (E) posterior genital branch; (F) posterior body region; (G) lateral chord.

Figure 2

Fig. 2. Aporcella talebii sp. n.: (A) anterior end; (B) amphidial pouch; (C) neck region; (D) entire body; (E) pharyngo–intestinal junction; (F) posterior genital branch; (G) vagina; (H) lateral chord; (I) posterior body region. Scale bars: (a–i) 10 μm; (d) 60 μm.

Figure 3

Fig. 3. Aporcella simplex (Thorne & Swanger, 1936) Loof & Coomans, 1970 anterior end, amphidial pouch, vaginae, posterior body region and lateral chord of populations from (A–F) Azarbaijan Shahid Madani University Campus; (G–L) Sheikh Hassan; (M–R) Firooz Salar; and (S–X) Mamaghan, respectively. Scale bars: 10 μm.

Figure 4

Table 2. Morphometrics of the Iranian populations of Aporcella simplex.

Figure 5

Fig. 4. Bayesian inference tree from the known and newly sequenced Aporcella talebii sp. n. and A. simplex based on sequences of the 28S rDNA region. Posterior probability and bootstrap values exceeding 50% are given on appropriate clades. Scale bar shows the number of substitutions per site. Newly obtained sequences are in bold letters.