Mitochondrial and nuclear gene sequencing confirms the presence of the invasive sea anemone Diadumene lineata (Verrill, 1869) (Cnidaria: Actiniaria) in Argentina

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Aquatic Biology

Introduction

Presumably native to Japan, Diadumene lineata (Verrill, 1869) is among the sea anemones recognized as a potentially invasive species that has been widely reported in coastal areas of most continents (e.g., Shick & Lamb, 1977; Ting & Geller, 2000; Hancock, Goeke & Wicksten, 2017; Glon et al., 2020; Gimenez, Rivera & Brante, 2022). Its success as an alien species has been facilitated by its ability to withstand wide ranges of temperature and salinity (Shick, 1976; Podbielski et al., 2016; Ryan & Miller, 2019), as well as its ability to reproduce asexually via longitudinal fission or pedal laceration (Gollasch & Riemann-Zürneck, 1996; Ting & Geller, 2000; Ryan & Kubota, 2016).

Introduced populations of D. lineata are often ephemeral (Stephenson, 1935; Shick, 1976; Dunn, 1982) and mainly consist of clones (Glon et al., 2020). It has been assumed that this species only reproduces asexually outside its native range because the populations studied in the invaded areas were composed of either sterile individuals or only males or females, not both sexes simultaneously (e.g., Shick & Lamb, 1977; Minasian, 1982; Ting & Geller, 2000; Glon et al., 2020). However, recent reports have documented the presence of fertile males and females on both the Pacific and Atlantic coasts of the USA (Newcomer, Flenniken & Carlton, 2019; Ryan & Miller, 2019). The occurrence of simultaneously fertile male and female individuals in introduced populations indirectly suggests the possibility of sexual reproduction events taking place in colonized areas, increasing the likelihood of permanent establishment and dispersion of the species in the new area.

The first record of D. lineata (= Haliplanella lineata) in Argentina (Southwestern Atlantic Ocean) dates back to 2004 in the intertidal zone of Las Grutas, Province of Río Negro (Excoffon, Acuña & Zamponi, 2004). The reported specimens did not exhibit the typical color pattern or smooth column (they had a black and vesiculated-like scapus), but this was considered as intraspecific variation (Excoffon, Acuña & Zamponi, 2004). It was later reported in salt marshes in the Bahía Blanca estuary (Buenos Aires Province), where it was found in sediments associated with the roots and stems of Spartina alterniflora Loisel, 1807 (Molina et al., 2009). In 2013, it was reported in rocky Patagonian shores by the citizen science program ProyectoSub (https://www.proyectosub.org.ar/, identification made by DL). Furthermore, it was mentioned in rocky Patagonian marshes (Battini & Bortolus, 2020) and in Puerto Pirámides, on the coast of Golfo Nuevo, Province of Chubut, based solely on photographs (iNaturalist, 2022) (Fig. 1). Additionally, its worldwide distribution has recently been modeled, reporting the highest probabilities of occurrence in the northern coastal region of Buenos Aires Province (Gimenez, Rivera & Brante, 2022). No voucher specimens were deposited in any cases, except for the specimens from Bahía Blanca. Unfortunately, probably by logistical constraints, none of these reports included molecular data to support species identification.

Distribution of Diadumene lineata documented along the coast of Argentina.

Figure 1: Distribution of Diadumene lineata documented along the coast of Argentina.

Diadumene lineata is traditionally recognized by its column color pattern, which is dark green or brown, with longitudinal stripes of orange, yellow, white, or green (Hancock, Goeke & Wicksten, 2017). However, taxonomic identifications based just on external features (e.g., color pattern and tentacle number) or internal morphological characteristics (e.g., the number of mesenteries, and shape of muscles) can be challenging, especially since specimens derived from asexual reproduction often exhibit irregular arrangements of structures (Atoda, 1973). Therefore, identifications using molecular information would ensure accurate species identification (Beneti et al., 2015).

Correct species identification is crucial when studying invasive species. It represents the minimum requirement for such studies, and species identification based solely on morphological characteristics often requires the expertise of a taxonomist, which may be limited or even unavailable depending on the taxa (Darling & Blum, 2007; Schwindt et al., 2020).

In this study, we obtained DNA sequences of two mitochondrial and two nuclear markers from four specimens of D. lineata collected in Argentina. One specimen was collected in Mar Chiquita (Buenos Aires Province) while three specimens were collected in Garipe beach (Chubut Province), separated by 800 km. Additionally, we conducted an analysis of the internal morphology, and the types and size range of cnidae using specimens collected from three coastal locations along the Argentine coast. These analyses aimed to support taxonomic identification by integrating morphological and molecular data to confirm the presence of the invasive sea anemone D. lineata in the country. Furthermore, given the presumed ephemeral nature of introduced D. lineata populations and their exclusive asexual reproduction outside their native range, we examined the internal anatomy of representatives from the Argentine coast to assess the presence of gametogenic tissue, providing insight into their potential for sexual reproduction.

Materials and Methods

Sampling

Eight specimens of putative D. lineata were collected in the intertidal zone of Garipe beach (42°35′55.51″S, 64°49′25.94″W), Chubut Province, in November 2013 (austral spring), fifty specimens were collected in the intertidal zone of Mar Chiquita (37°44′30.45″S, 57°24′54.98″W) in April 2021 (austral autumn), and twenty specimens in the coast of San Clemente del Tuyú (36°21′42.10″S, 56°42′45.64″W) in June 2017 (austral winter), both localities in Buenos Aires Province (Fig. 1). Specimens were collected by hand, using a small blunt knife. Individuals from Buenos Aires Province were transferred to the laboratory and kept in an aquarium for photographing their living coloration while those from Chubut Province were photographed both in situ and in the laboratory. Some specimens were fixed and preserved in 96% ethanol for molecular studies, but most were anesthetized in 5% MgCl2 solution or menthol crystals, then fixed in 7–10% formalin in seawater for several months before being transferred to 70% ethanol for long-term storage. Voucher specimens were deposited in the invertebrate collection of the Museo Argentino de Ciencias Naturales “Bernardino Rivadavia” (MACN) and assigned the following numbers: MACN-In 44051 (Garipe beach, Chubut), MACN-In 44052 (San Clemente del Tuyú, Buenos Aires) and MACN-In 44053 (Mar Chiquita, Buenos Aires).

Molecular data collection and phylogenetic analysis

Total genomic DNA was extracted from tissue from four specimens (three from Garipe beach and one from Mar Chiquita) following the procedures implemented by Lauretta et al. (2014). We targeted two mitochondrial (12S and 16S rDNA) and two nuclear (18S and 28S rDNA) gene regions. PCR profiles followed those described in Brugler et al. (2018). PCR products were purified and sequenced by Macrogen, Korea. The new sequences from 12S, 16S, 18S and 28S have been deposited in GenBank (Tables 1, S1) and were compared with those from D. lineata and other congeners obtained from Genbank (S1). We performed two different analyses of the genetic data. First the sequences were aligned using ClustalW in BioEdit (Hall, 1999) with default parameters, and the Kimura’s two-parameter (K2P) model (Kimura, 1980) of base substitution was used to calculate genetic distances using MEGA11 (Tamura, Stecher & Kumar, 2021). This metric is suitable for sequences with low divergence rates (Nei & Kumar, 2000) and has been employed in calculating distances for other actiniarians (e.g., Beneti et al., 2015; González-Muñoz et al., 2015; Grajales & Rodríguez, 2016; Yoshikawa et al., 2022), facilitating comparisons across different groups (Daly et al., 2010). Then, a phylogenetic reconstruction was carried out following the approach implemented by Gusmão, Grajales & Rodríguez (2018) for a similar analysis of Diadumene spp. We incorporated our 12S, 16S, and 18S sequences into the matrix from Gusmão, Grajales & Rodríguez (2018), which consists of three mitochondrial gene regions (12S, 16S and COX3) and one nuclear (18S) (S1). The matrix included representatives of the superfamily Metridioidea and used four species of Actinioidea Rafinesque, 1815 as outgroups. The other sequences were obtained from GenBank (see S1 for details). The gene regions were aligned separately using MAFFT (Multiple Alignment using Fast Fourier Transform) ver. 7 (https://mafft.cbrc.jp/alignment/server/) with the E-INS-I strategy, Gap open penalty of 1.53, and default parameters. For the 12S, 16S and 18S sequences, hypervariable regions were removed using Gblocks (Castresana, 2000) with relaxed parameters. The final matrix consisted of 86 taxa and 3,757 total sites. We use a maximum likelihood approach with the IQ-TREE webserver (Trifinopoulos et al., 2016) to infer the phylogenetic relationships. The best substitution model for our data was selected using a different partition per gene (best-fit model according to BIC (Bayesian Information Criterion): TIM2+F+I+G4: 12s, HKY+F+I+G4: 16s, TIM2e+I+G4: 18s, TIM3+F+G4: COX3_1, TIM2e+G4: COX3_2, TPM2u+F+I+G4: COX3_3) (Kalyaanamoorthy et al., 2017). Gaps were treated as missing data in the analyses. Support for each node was calculated using ultrafast bootstrap with 1,000 replicates (Hoang et al., 2018).

Table 1:
GenBank accession numbers of the taxa included in the genetic distance estimates using the K2P model; new sequences in bold.
Species 12S 16S 18S 28S
D. lineata Mar Chiquita OP683484 OP687084 OP688013 OP683573
D. lineata 308 Garipe beach OP683485 OP687085 OR395177 -
D. lineata 309 Garipe beach OP683486 OP687086 OR395178 -
D. lineata 310 Garipe beach OP683487 OP687087 OP688014 -
Diadumene lineata (Japan) JF832965.1 JF832973.1 JF832987.1 JF832998.1
Diadumene lineata (USA) EU190730.1 EU190774.1 EU190860.1 EU190819.1, KJ483107.1, KJ483108.1
Diadumene lineata (USA–California) MT893227.1 MT895444.1 MT893020.1
Diadumene sp. JF832960.1 JF832976.1 JF832980.1 JF832990.1
Diadumene cincta EU190725.1 EU190769.1 EU190856.1 EU190814.1, KJ483106.1
Diadumene leucolena (Brazil) KY815042.1 KY815043.1 KY815044.1 KJ483123.1
Diadumene leucolena JF832957.1 JF832977.1 JF832986.1 JF832995.1
Diadumene manezinha (Brazil) KY815045.1 KY815046.1 KY815047.1
Diadumene paranaensis KT353112.1
DOI: 10.7717/peerj.16479/table-1

Morphological analysis

Forty specimens from Mar Chiquita and the 20 specimens from San Clemente del Tuyú were dissected and examined under a Leica stereomicroscope (mod. EZ4-W) to assess the mesenterial arrangement and development of gametogenic tissue. Additionally, serial histological sections of five specimens from Mar Chiquita and two from Garipe beach were made for a more thorough search of gametogenic tissue; paraffin sections 5–7 µm thick were stained with hematoxylin-eosin (Estrada-Flores, Peralta & Rivas, 1982). Measurements of cnidae size ranges were obtained from two specimens from each locality (N = 6). Squash preparations were obtained from small tissue portions (1 mm3) of acontia, actinopharynx, mesenterial filaments, column, and tentacles of each individual. For each squash preparation, the length and width of up to 20 undischarged capsules (when possible) of each cnidae type present were randomly measured using microscopy at 1,000× oil immersion. The terminology for cnidae types follows the classification implemented by Gusmão, Grajales & Rodríguez (2018).

Results

Comparison of genetic markers

Our analysis of molecular data revealed a high resemblance between our samples and specimens previously identified as D. lineata in the existing literature. The comparison of aligned sequences of the 12S and 16S mitochondrial markers showed no variation among individuals from Mar Chiquita and Garipe beach, and D. lineata from Japan and the USA (retrieved from GenBank). However, differences were observed when compared with all other congeneric species, such as Diadumene cincta Stephenson, 1925, Diadumene leucolena (Verrill, 1866), Diadumene manezinha Gusmão, Grajales & Rodríguez, 2018, or Diadumene paranaensis Beneti et al., 2015. The divergence estimates between D. lineata and other species of Diadumene varied across these markers, ranging from 0.57‒0.96% for 12S and 1.49‒2.10% for 16S (Tables 2, S2). The 18S nuclear marker sequence from the Garipe beach specimen showed variations compared to those from Mar Chiquita, with 11 substitutions and three ambiguous sites. The positions of these substitutions were based on the sequence of the Diadumene lineata voucher SaCr1A small subunit ribosomal RNA gene (GenBank accession number: MT895444.1, of 1,785 base pairs in length). The substitutions consisted of three transitions: (T to C, at positions 912 and 1176; C to T, at position 1710) and eight transversions (G to C, at positions 767 and 1056; T to A, at positions 882, 1061, 1123; G to C, at position 993; G to T, at position 1049; C to G, at position 1164). The three sites with ambiguities were T to Y, at positions 1277 and 1306; G to R, at position 1296. For the 18S marker, the intraspecific divergences among the sequences of D. lineata varied from 0.00 to 0.74%, whereas between D. lineata and the other species of Diadumene, they ranged from 4.25 to 5.11% (Tables 2, S2). The sequences of the 28S nuclear marker could only be obtained from specimens from Mar Chiquita, but no variation was found between these sequences compared to others of D. lineata from GenBank. However, similarly to the 18S marker, there was an intraspecific divergence of 0.45% in a sequence from California, USA (Table 2). The genetic distance calculated for the 28S nuclear marker between D. lineata and other species of Diadumene ranges from 9.28‒13.74% (Tables 2, S2).

Table 2:
Estimated divergence (K2P, expressed as a percentage) of Diadumene lineata compared to other Diadumene species, based on the comparison of sequences from the four molecular markers used.
12S 16S 18S 28S
D. lineata Mar Chiquita 0 0 0 0
D. lineata 308 Garipe beach 0 0 0
D. lineata 309 Garipe beach 0 0 0
D. lineata 310 Garipe beach 0 0 0.74
D. lineata (USA) 0 0 0
D. lineata (Japan) 0 0 0
D. lineata MT893227.1/MT893020.1 0 0.45
Diadumene sp. 0.96 1.79 4.25–5.03 11.37
Diadumene cinta 0.96 1.79 4.25–5.03 12.94–13.74
Diadumene manezinha 0.57 1.79 4.32–5.11
Diadumene leucolena 0.57 1.49 4.25–5.04 9.28–9.80
Diadumene paranaensis 2.10
DOI: 10.7717/peerj.16479/table-2

Molecular phylogenetic analysis

The phylogenetic reconstruction recovered the genus Diadumene as monophyletic with high support (100%) and composed of three major clades (Fig. 2): one clade formed by D. cincta, Diadumene sp., and D. paranaensis (100%), a second clade by D. leucolena and D. manezinha (100%), and a third clade by D. lineata from the USA, Japan, and the Argentine samples (100%). Then, Argentine samples were grouped within the D. lineata clade (Fig. 2). Similarly to Larson (2016) and Gusmão, Grajales & Rodríguez (2018), we recovered the clade Metridina of Rodríguez et al. (2012) with high support (100%), which is composed of Diadumenidae as the sister group to a clade with members of Metridiidae Carlgren, 1893 and Acricoactinidae Larson, 2016.

Maximum-likelihood tree from combined analysis of 12S, 16S, COX3, and 18S sequences.

Figure 2: Maximum-likelihood tree from combined analysis of 12S, 16S, COX3, and 18S sequences.

Branch numbers indicate Ultrafast Bootstrap values. Arrows point to D. lineata specimens collected in Argentina.

Morphological examination

Specimens examined showed the external morphology characteristic of D. lineata: tentacles relatively large, thin, smooth without any structures, tapered to a point, grayish or grayish-green and translucent (Figs. 3A, 3B, 3D and 3E); oral disc light-brown or light green, translucent (Fig. 3A); column dark-green with orange stripes on scapus from margin to the limbus (Figs. 3A3D); cinclids clearly visible along the orange stripes (Fig. 3D); white acontia emerging from the mouth or the cinclids when contracted (Fig. 3C). No gametogenic tissue was observed in any of the 60 dissected specimens, nor in those individuals studied with histological sections (Fig. 3F). In addition, the mesenteries presented an irregular arrangement in every specimen examined, with weak and diffuse retractor muscles (Fig. 3F). The cnidom of our specimens of D. lineata was composed of spirocysts, basitrichs, holotrichs, and microbasic p-mastigophores A, B1, and B2a (Fig. 4). However, not all types of cnidocysts were found in every analyzed specimen, and in some cases, their abundance was also dissimilar (Table 3).

In vivo images of Diadumene lineata from Argentina.

Figure 3: In vivo images of Diadumene lineata from Argentina.

(A) in situ, top view, detail of distal part of the column and oral disc (specimen from Garipe beach); (B) top view, detail of oral disc (specimen from Mar Chiquita); (C) top view, oral disc and tentacles contracted; (D) lateral view, detail of column. Arrows point to cinclides; (E) top view, specimen splitting by longitudinal fission in aquarium; (F) histological transversal section, detail of mesenteries with no trace of gametes. Abbreviations.- a, acontia; c, column; ci, cinclides; fi, mesenteric filaments; m, mesenterial retractor muscles; od, oral disc; t, tentacles. Scale bars.-a-e: 5 mm; f: 200 µm.
Cnidae of Diadumene lineata from Argentina.

Figure 4: Cnidae of Diadumene lineata from Argentina.

Notes: (a, e, n) small basitrichs; (b, f, k, o, v) basitrichs; (c, h, l, s, y) small p-mastigophores B2a; (d, j, u) large p-mastigophores B2a; (i, t, z) medium-size p-mastigophores B2a; (g, p) p-mastigophores A; (q, r) p-mastigophores B1; (m, x) holotrichs; (w) spirocysts. Scale bars: a-c, e-I, k-t, v-z: 20 µm; d, j, y: 14 µm.
Table 3:
Comparison of the types and size ranges of cnidae among specimens from the three locations on the Argentine coast.
Categories San Clemente X ± SD S N Mar Chiquita X ± SD S N Garipe beach X ± SD S N
ACONTIA
Small basitrichs 7.9–13.2 × 1.4–2.2 11.2 ± 1.4 × 1.9 ± 0.2 17 2/2 10.3–14.2 × 1.8–2.2 12.0 ± 1.0 × 1.9 ± 0.1 25 2/2
Basitrichs 14.7–19.1 × 2.1–3.0 16.7 ± 1.0 × 2.6 ± 0.2 40 2/2 14.8–19.2 × 2.4–3.0 16.8 ± 1.1 × 2.6 ± 0.2 40 2/2 13.6–17.4 × 1.7–2.2 16.1 ± 1.3 × 1.8 ± 0.2 6 1/2
Small p-mastigophores B2a 12.0–18.9 × 2.7–3.7 16.3 ± 1.98 × 3.2 ± 0.3 18 2/2 14.8–19.7 × 3.0–4.1 17.2 ± 1.3 × 3.5 ± 0.3 20 2/2 11.9 × 3.6 1 1/2
Large p-mastigophores B2a 38.1–52.8 × 4.9–7.6 47.3 ± 3.4 × 5.8 ± 0.7 21 2/2 44.6–55.9 × 6.0–9.4 50.6 ± 3.1 × 7.4 ± 0.6 21 2/2 36.7–48.6 × 4.8–6.7 44.5 ± 3.1 × 5.8 ± 0.5 20 1/2
ACTINOPHARYNX
Small basitrichs 9.7–14.6 × 1.6–2.6 13.1 ± 1.5 × 2.1 ± 0.3 11 2/2 9.9–14.0 × 1.6–2.5 11.7 ± 1.0 × 2.0 ± 0.3 23 2/2
Basitrichs 15.4–18.7 × 2.1–2.9 16.8 ± 1.0 × 2.6 ± 0.2 20 1/2 14.8–21.9 × 2.1–3.3 17.3 ± 1.6 × 2.7 ± 0.3 26 2/2 15.5–24.0 × 1.5–2.6 18.1 ± 3.3 × 2.0 ± 0.4 8 2/2
p-mastigophores A 21.2–21.7 × 3.5–3.6 21.4 ± 0.4 × 3.6 ± 0.1 2 1/2 21.8–24.9 × 2.9–4.4 23.3 ± 1.1 × 3.6 ± 0.5 9 2/2
p-mastigophores B2a I 10.4–13.9 × 3.0–3.8 11.9 ± 1.2 × 3.4 ± 0.3 7 1/2 10.5–13.8 × 3.0–4.0 11.6 ± 1.3 × 3.6 ± 0.4 5 1/2 10.8–12.3 × 2.7–3.0 11.6 ± 1.1 × 2.9 ± 0.2 2 1/2
p-mastigophores B2a II 17.2–35.0 × 2.5–4.7 23.5 ± 4.1 × 3.7 ± 0.4 40 2/2 16.0–29.2 × 3.1–4.8 22.5 ± 2.7 × 3.8 ± 0.4 40 2/2 21.8–26.2 × 3.0–4.0 24.2 ± 1.5 × 3.4 ± 0.3 15 2/2
p-mastigophores B2a III 41.5–53.4 × 5.0–7.5 47.6 ± 3.0 × 6.2 ± 0.5 25 2/2 42.6–47.4 × 8.3–8.4 47.4 ± 6.8 × 8.4 ± 0.2 2 1/2 28.2–50.6 × 3.6–6.4 39.4 ± 9.3 × 5.1 ± 1.0 10 2/2
COLUMN
Basitrichs I 15.3–18.9 × 2.3–3.5 17.0 ± 0.7 × 2.9 ± 0.3 22 2/2 12.3–15.9 × 2.5–3.5 14.3 ± 0.9 × 3.0 ± 0.2 40 2/2 12.0–18.1 × 1.9–2.9 16.1 ± 1.5 × 2.4 ± 0.3 29 2/2
p-mastigophores B2a I 9.5–18.9 × 3.3–5.0 15.6 ± 2.1 × 4.1 ± 0.3 40 2/2 11.2–16.1 × 3.3–4.7 13.5 ± 1.0 × 3.9 ± 0.3 40 2/2 11.7–15.4 × 2.7–3.9 13.4 ± 1.2 × 3.3 ± 0.4 8 2/2
Holotrichs 13.4–20.0 × 3.7–6.2 17.3 ± 1.7 × 5.3 ± 0.7 15 2/2 12.3–18.7 × 4.1–6.1 16.4 ± 1.5 × 5.1 ± 0.5 23 2/2 14.7–18.9 × 2.8–5.7 16.5 ± 1.2 × 4.2 ± 0.8 16 2/2
FILAMENTS
Small basitrichs 10.5–12.7 × 1.5–2.2 11.4 ± 0.6 × 1.8 ± 0.2 15 1/2 9.2–11.8 × 1.5–2.6 10.4 ± 0.7 × 1.8 ± 0.2 40 2/2
Basitrichs 17.0–19.0 × 2.1–2.3 18.0 ± 1.4 × 2.2 ± 0.2 2 1/2 16.0–20.6 × 2.2–2.9 17.6 ± 1.1 × 2.6 ± 0.2 20 1/2 19.4–19.6 × 2.1–3.0 19.5 ± 0.1 × 2.4 ± 0.5 3 1/2
p-mastigophores A 16.7 × 3.4 1 1/2
p-mastigophores B1 I 9.6–11.1 × 3.7–5.7 10.6 ± 0.4 × 4.6 ± 0.6 20 1/2 8.6–11.2 × 3.1–4.0 10.1 ± 0.6 × 3.6 ± 0.3 17 2/2 11.9 × 3.6 1 1/2
p-mastigophores B1 II 15.6–19.6 × 4.5–6.90 17.7 ± 1.1 × 5.4 ± 0.7 20 1/2 16.0–19.2 × 4.3–5.4 17.4 ± 1.2 × 4.6 ± 0.3 11 2/2
p-mastigophores B2a I 9.9–17.6 × 2.7–4.4 12.6 ± 2.2 × 3.4 ± 0.5 20 1/2 9.3–15.8 × 2.6–4.0 12.4 ± 1.4 × 3.2 ± 0.3 31 2/2 11.1–15.0 × 2.7–3.0 13.1 ± 2.8 × 2.9 ± 0.2 2 2/2
p-mastigophores B2a II 22.7–27.2 × 3.0–4.0 25.0 ± 1.4 × 3.6 ± 0.2 20 1/2 19.7–29.1 × 3.1–5.1 26.1 ± 2.0 × 3.8 ± 0.4 40 2/2 21.9–32.4 × 2.9–5.2 24.6 ± 2.8 × 3.5 ± 0.5 17 2/2
p-mastigophores B2a III 48.5–60.3 × 6.1–8.2 54.2 ± 2.8 × 7.0 ± 0.7 16 1/2 46.6–55.6 × 6.4–10.4 51.3 ± 2.0 × 7.5 ± 0.8 22 2/2 41.9–48.9 × 4.0–5.9 45.8 ± 2.0 × 5.3 ± 0.4 20 1/2
TENTACLES
Basitrichs I 14.3–19.6 × 2.–3.1 17.4 ± 1.1 × 2.4 ± 0.2 39 2/2 12.6–16.6 × 2.0–2.9 14.8 ± 0.9 × 2.4 ± 0.2 40 2/2 13.0–23.9 × 1.9–2.5 19.1 ± 4.6 × 2.3 ± 0.2 5 2/2
Spirocysts 13.6–21.4 × 3.0–5.0 16.8 ± 2.0 × 3.8 ± 0.5 20 2/2 11.8–21.2 × 2.7–5.8 16.5 ± 2.8 × 3.7–0.8 40 2/2 13.3–23.5 × 2.1–3.8 18.8 ± 2.3 × 3.0 ± 0.4 40 2/2
Holotrichs 14.7–18.3 × 3.7–5.1 16.6 ± 1.1 × 4.4 ± 0.4 20 1/2 11.2–18.5 × 2.9–3.9 15.5 ± 2.9 × 3.4 ± 0.4 5 1/2
p-mastigophores B2a I 9.5–17.6 × 2.9–4.0 15.0 ± 2.0 × 3.4 ± 0.3 24 2/2 7.7–11.3 × 2.4–3.4 10.0 ± 0.7 × 3.0 ± 0.2 40 2/2 11.9–14.8 × 2.2–3.5 13.1 ± 1.0 × 2.8 ± 0.4 13 2/2
p-mastigophores B2a II 18.2–24.3 × 2.7–3.9 21.2 ± 1.2 × 3.3 ± 0.3 40 2/2 17.1–25.6 × 3.1–4.5 20.5 ± 1.7 × 3.8 ± 0.3 40 2/2 19.4–24.5 × 2.8–4.0 22.3 ± 1.1 × 3.4 ± 0.4 24 2/2
DOI: 10.7717/peerj.16479/table-3

Discussion

Genetic sequence comparisons support the identification of individuals from Mar Chiquita and Garipe Beach as Diadumene lineata, and thus their presence on the Argentine coast is confirmed by molecular tools. The lack of variation among mitochondrial sequences of D. lineata (i.e. 12S and 16S rDNA) is consistent with the slow rates of mitochondrial sequence evolution observed in many anthozoan groups (Shearer et al., 2002). However, intra-specific variations among mitochondrial sequences have been reported for some species of actiniarians. For instance, González-Muñoz et al. (2015) found two haplotypes of the 12S marker in Phymanthus crucifer (Le Sueur, 1817), which differ by a single substitution within an 824 bp fragment (K2P distance = 0.1215%). Furthermore, Grajales & Rodríguez (2016) reported intra-specific variations in the mitochondrial markers 12S and 16S for several species within Aiptasiidae Carlgren, 1924. In their study, genetic distances calculated by the K2P model ranged between 0.002 and 0.052 for 12S, and between 0.0003 and 0.003 for 16S (Grajales & Rodríguez, 2016). The values of intra-specific divergence for mitochondrial markers described in both previous examples are much lower than the divergence ranges observed in the present study between D. lineata and other species of Diadumene (i.e., 0.57–0.96% for 12S, and 1.49–2.10% for 16S). Therefore, although the absence or low divergence often hinders the recognition of differences among populations, it is useful for distinguishing genetic differences between congeneric species, at least for the studied species of Diadumene.

For the nuclear marker 18S, the intra-specific variation (ranging from 0.00 to 0.74%) is much smaller compared to the inter-specific variation (ranging from 4.25 to 5.11%). Therefore, we consider that the variations among the D. lineata sequences represent intra-specific variability (Table 2). However, these results also suggest that this marker could exhibit some variability among populations of D. lineata. This supports the idea that nuclear markers can also show intra-specific variability in sea anemones, as reported in other studies (e.g., Grajales & Rodríguez, 2016; Brugler et al., 2018).

The cnidae observed in the examined specimens of D. lineata largely agrees with those described by Hand (1955) and Excoffon, Acuña & Zamponi (2004) for this species, both in its composition and in the size ranges of the cnidae. However, the examined specimens exhibit an additional category of p-mastigophores B2a in the actinopharynx and filaments, which are longer (i.e., 41.9–60.3 and 28.2–53.4 µm, respectively) compared to those reported by Hand (1955) (i.e., 18.5–25.0 and 21.5–27.0 µm, respectively) and Excoffon, Acuña & Zamponi (2004) (20–40 µm in the filaments). Nevertheless, the use of different nomenclatures and the absence of images of cnidae types in these previous studies make a proper comparison difficult. Additionally, the presence of holotrichs in the column is reported. A more detailed study on the variation of types and sizes of cnidae among D. lineata specimens from distinct populations is required.

The fact that no trace of gametogenic tissue development was found in the specimens examined suggests that the population was sterile and not capable of sexual reproduction, at least at the time of collection (austral autumn, winter, and spring). Therefore, it is most likely that all the individuals examined are clones due to their high capacity for asexual reproduction. As Stephenson (1935) and Shick & Lamb (1977) reported, we observed a specimen from Mar Chiquita that quickly began to divide longitudinally, which could support this hypothesis (Fig. 3E). If these individuals are indeed clones, then it might be expected that after a period of rapid colonization, the population would eventually decline or individuals would become rare, as has been documented in other locations (e.g., Shick, 1976; Shick & Lamb, 1977). Molina et al. (2009) suggested that there is a stable population of D. lineata in the Bahía Blanca estuary, based on their estimation of population density detecting higher abundances in the summer months; however, it was unclear whether this population was made up of clones or even if included individuals capable of sexual reproduction.

According to Fukui (1995), the peak of sexual reproduction of D. lineata in Japan is during the boreal summer (from July to August in the northern hemisphere) and involves the release of gametes. Spermatogenesis starts in late fall when small cysts occur in the mesoglea and develop from winter to late spring. The growth stage of gametes occurs during and after April, and mature cysts could be observed in mid-summer (Fukui, 1995). Our specimens examined from Mar Chiquita and San Clemente del Tuyú were collected in April and June, respectively (during the austral autumn and winter, respectively), which falls outside the documented period of sexual reproduction for this species. Conversely, the specimens from Garipe Beach were collected in late spring, when gametogenesis should be present. However, the implications that the different seasons of the year may have in the northern and southern hemispheres, such as the change in temperature regime among one of the many environmental factors that may be involved in the sexual reproduction of this species, are unknown.

Diadumene lineata is one of the four species of sea anemones currently considered in the official list of exotic species of Argentina (Ministry of Environment and Sustainable Development of Argentina, 2022), along with Aulactinia reynaudi (Milne Edwards, 1857), currently Bunodactis reynaudi, Oulactis muscosa (Drayton in Dana, 1846) and Boloceroides mcmurrichi (Kwietniewski, 1898). Additionally, Excoffon & Zamponi (1999) documented the occurrence of Sagartia troglodytes (Price in Johnston, 1847), currently Cylista troglodytes, on the coast of Mar del Plata, a species native to European waters. However, there have been no reports of its presence (nor of B. mcmurrichi) in Argentina since then. It has also been demonstrated through molecular tools that the specimens previously identified as A. reynaudi belong to the local species Aulactinia marplatensis (Acuña et al., 2007). Furthermore, ongoing research aims to verify the uncertain presence of O. muscosa and B. mcmurrichi in Argentina. Moreover, the official list of exotic species does not include Metridium senile (Linnaeus, 1761), which is native to the northern hemisphere (Glon et al., 2020), has previously been reported in the country (e.g., Riemann-Zürneck, 1975; Martin et al., 2015), and is recognized as one of the most widely distributed invasive sea anemone species worldwide. Therefore, we consider only two sea anemones as potentially invasive species in Argentina: D. lineata, present since at least 1999 (Excoffon, Acuña & Zamponi, 2004) and M. senile, present in Argentina since at least 1966 (Riemann-Zürneck, 1975).

According to Schwindt et al. (2020), the most probable vectors for the introduction of D. lineata in Argentina are through ship fouling or ballast water. The arrival of this species may be linked to international shipping traffic, with the port of Mar del Plata being a likely initial point of entry. Mar del Plata has a significant port in Argentina, serving both national fishing activities and housing the country’s most important marina (Castro et al., 2021). In fact, Mar del Plata and its surrounding areas have the highest number of reported introduced species (Schwindt et al., 2020), establishing it as a hotspot for invasive marine species (Castro et al., 2021). It is plausible that D. lineata has subsequently spread to other coastal areas, potentially facilitated by recreational vessels, as suggested by Castro et al. (2021) in their detailed study on potential routes of introduction and distribution of invasive ascidian species in the country.

Invasive anemones could harm native benthic communities, as recently observed in Chile with the spread of M. senile (Häussermann et al., 2022), but the impact of D. lineata populations on colonized environments remains uncertain. However, a report from the United Kingdom indicates that this species primarily preys on small crustaceans and may consume bivalve larvae of commercially important species like oysters and mussels, affecting diversity and local fisheries (Wood et al., 2022). Diadumene lineata could compete for space and resources with local species that naturally occupy similar niches along the southern coasts of the Buenos Aires province, such as Anthothoe chilensis (Lesson, 1830) or Tricnidactis errans De Oliveira Pires, 1987. On the other hand, it has been documented that D. lineata is heavily preyed upon by nudibranchs like Aeolidia papillosa (Linnaeus, 1761) (Shick & Lamb, 1977), similar to local reports of mollusks from the genera Spurilla Bergh, 1864 and Pleurobranchaea Leue, 1813 feeding on local species of sea anemones in Argentina (Garese et al., 2012; Bökenhans et al., 2018). Therefore, continuous monitoring of D. lineata populations in Argentina is crucial to observe whether they establish and reproduce, expand their distribution, decline, or potentially cause harm to local species or alterations in benthic communities.

Conclusions

We confirm, for the first time, the presence of Diadumene lineata in Argentina using mitochondrial and nuclear genetic markers and expand the northernmost distribution limits to include the localities of Mar Chiquita and San Clemente del Tuyú. Furthermore, because the specimens analyzed are sterile (and possibly clones), we propose that this species is not currently undergoing sexual reproduction in the studied localities, at least within the observed timeframe. Therefore, systematic population monitoring over the years is necessary to asses and track the reproductive cycle of D. lineata along the Argentinean coast, its spread and potential effects on native communities.

Supplemental Information

Taxa included in this study, with GenBank accession numbers. New data in bold.

DOI: 10.7717/peerj.16479/supp-1

K2P model for 12S, 16S, 18S and 28S.

DOI: 10.7717/peerj.16479/supp-2
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