Achaeta gemmata, Schmelz & Chen & Józefowska, 2024
publication ID |
https://doi.org/ 10.11646/zootaxa.5437.1.1 |
publication LSID |
lsid:zoobank.org:pub:873EED65-BAD8-49CB-A23D-C86F4289E742 |
DOI |
https://doi.org/10.5281/zenodo.10961408 |
persistent identifier |
https://treatment.plazi.org/id/505F5454-FF9D-8D51-FF01-FCCBE921FB90 |
treatment provided by |
Plazi |
scientific name |
Achaeta gemmata |
status |
sp. nov. |
Achaeta gemmata sp. nov.
( Figures 3 View FIGURE 3 , 4 View FIGURE 4 )
Holotype. CEP-DZ-149414-N, adult specimen, anterior 23 segments, unstained whole-mount, with DNA sequences COI PP079496 , ITS PP084618 .
Type locality. Poland, Rudziniec Forest District , forest regenerated after fire, pine stand ( Pinus sylvestris L.), 50°18’09.5”N 18°24’47.7”E, soil type podsol, pH 3.8 (H 2 O) GoogleMaps .
Paratypes. CEP-DZ-149415-N, adult specimen, anterior 15 segments, unstained whole-mount, with DNA sequence ITS PP084619 . CEP-DZ-149416-N to CEP-DZ-149430-N, 15 specimens (8 adult, 3 subadult, 4 juvenile), mostly complete (3 amputees), stained whole mounts. 33 specimens (5 adult, 17 subadult, 11 juvenile), stained whole mounts, in the 1st author’s collection. From type locality or adjacent sites overgrown by Larix decidua , Betula pendula , and Quercus robur L.; soil type podsols, sandy and loamy-sandy texture, pH (H 2 O) 3.7–4.8 .
Further material. A total of c. 1700 specimens, investigated and identified in vivo, from type locality or adjacent sites. Of these: 33 specimens (5 adult, 17 subadult, 11 juvenile), stained whole mounts; 9 specimens, fixed in Bouin’s fluid, preserved in 70% ethanol; c. 130 specimens, preserved in 100% ethanol; from type locality or adjacent sites. Material in the 1st author’s collection.
Diagnosis. Body length 4.5–5 mm; up to 38 segments; pyriform glands and oesophageal appendage absent; pharyngeal glands with secondary lobes in V and VI; two pairs preclitellar nephridia, at 6/7, 7/8; clitellum interrupted ventrally, complete dorsally, cells in conspicuous longitudinal rows; dorsal rows consisting of hyalocytes and interspersed granulocytes; lateral and ventrolateral rows with granulocytes only; last ventral row in longitudinal line with male pores; seminal vesicle absent; male glands small and widely separate; spermatheca length c. 1.5 segments, ectal pores laterally.
Description. Body length (fix) 4.4–4.9 mm. Body diameter (fix) 0.11–0.25 mm; 0.11–0.15 mm at V, 0.15–0.25 at XII, 0.14–0.17 mm at XX. Segment number 31–38 (N=11; 32–34, eight specimens, 31, 35, 38, one specimen each).
Pyriform glands absent, lentiform glands enlarged to ellipsoid cushion-like intracoelomic papillae in anterior segments: dorsally one pair in I anteriorly of brain ( Fig. 3A View FIGURE 3 , 4A View FIGURE 4 ), laterally one pair per segment in II to X ( Fig. 3A View FIGURE 3 , 4G View FIGURE 4 ); ventrally one pair per segment ( Fig. 3A,B View FIGURE 3 ), first pair in III, IV or V, last preclitellar pair in XI, only slightly enlarged; behind clitellum from XIII on, reducing in size in following segments, absent in posterior body half. In living specimens, dorsal papillae in I and lateral papillae conspicuous, ventral papillae inconspicuous. Papillae longer than wider than high. Size of lateral papillae varying among specimens, and often also within a specimen; maximum length 32–50 μm, minimum length 18–32 μm, mean length 27–34 μm. Length within an individual varying, e.g., between 50 μm and 32 μm or 32 μm and 20 μm. Ventral papillae 21–25 μm long and 14–20 μm wide. Papillae not developed in all positions. Additionally, 2 pairs of segmental lentiform cells dorsally, inconspicuous, only seen in whole mounted specimens: one pair closely behind septum, the other pair at level of lateral papillae.
Brain ( Fig. 3A View FIGURE 3 , 4A View FIGURE 4 ) about 1.7x as long as wide, posteriorly slightly convex, sometimes straight, length 80– 90 μm (viv), 70–73 μm, fix. Ventral nerve cord ganglionic from V. Pharyngeal glands ( Fig. 3A View FIGURE 3 , 4C View FIGURE 4 ) all widely connected dorsally, in V and VI no subdivision into dorsal and ventral lobes; secondary ventral glands in V, VI. Oesophageal appendage absent or not distinguishable light-microscopically. Dorsal blood vessel from VII. Intestine widening gradually, no intestinal diverticula. Pars tumida of midgut in region XXIX–XXXIV, in 3.5–4 consecutive segments. Two pairs of preclitellar nephridia ( Fig. 3A View FIGURE 3 , 4B View FIGURE 4 ), at 6/7, 7/8; anteseptale with coils of canal, bulky, postseptale 1.5x as long as anteseptale, septal constriction slight or absent, postseptale gradually merging into short and thick efferent duct, terminal vesicle absent. Postclitellar nephridia from 15/16 or further back, of similar shape but postseptale more slender and stretched than in preclitellar nephridia. Coelomocytes ( Fig. 4D View FIGURE 4 ) pale, flat, disc-shaped, with varying amounts of refractile granules in the centre, periphery often as a flat hyaline frame; cells almost as wide as long, length 30–35 μm.
Clitellum from XII–1/2XIII, saddle-shaped, no dorsal interruption; cells in conspicuous longitudinal rows; dorsal rows consisting of hyalocytes and interspersed granulocytes ( Fig. 4I View FIGURE 4 ); lateral and ventrolateral rows with granulocytes only ( Fig. 3B View FIGURE 3 , 4H View FIGURE 4 ); last ventral row in longitudinal line with male pores ( Fig. 3B View FIGURE 3 ).
Testis in XI, ovary in XII ( Fig.3B View FIGURE 3 ). Seminal vesicle absent, spermatogonial cysts free in XI dorsally.Spermatozoa 36 μm, heads 14 μm. Sperm funnels ( Fig. 4F View FIGURE 4 ) small, about 2–2.5x as long as wide, 60–100 μm by 26–40 μm, collar almost as wide as funnel body. Vas deferens often coiled in dense regular spirals, diameter 6–7 μm. Male pores ( Fig. 3B View FIGURE 3 ) on body surface, widely distant, surrounded by area glareosa. Male glandular bulb spherical, diameter 25–35 μm (fix), pierced centrally by vas deferens; distance of bulbs 1.5–2x bulb diameter.
Spermathecae ( Fig. 3A View FIGURE 3 , 4C View FIGURE 4 ) short, extending into VI, rarely VII; often confined to V. Ectal pores lateral. Ectal duct slightly longer than wide, 20–24 μm by 14–20 μm (fix, N=6); ampulla 24–34 μm wide (fix, N=6), separated by a constriction from ectal duct in fixed specimens; spermatozoa placed obliquely in ampullar lumen; connecting tube thin, ental reservoir spherical, 30–36μm wide (fix, N=4).
Etymology. Named after the conspicuous lateral papillae. Due to their serial arrangement and easy recognition they appear as true gems when large numbers of specimens have to be identified to species level.
Remarks, morphology. This new species is most similar to Achaeta camerani , a common species in Northern and Central Europe ( Schmelz & Collado 2010) and with additional records from NW Spain ( Collado & Martínez-Ansemil 1996) and Japan ( Nakamura & Christensen 1978). Both species often occurred together at the same plot or even in the same soil sample. They agree in (1) body size, (2) absence of pyriform glands, (2) presence of secondary pharyngeal gland lobes in V and VI, (3) preclitellar nephridia at 6/7, 7/8, (4) absence of a seminal vesicle, (5) short spermathecae with lateral ectal pores, and, most conspicuously, in (6) the saddle-shaped clitellum, without dorsal interruption and with cells arranged in distinct longitudinal rows.
Differences of A. camerani are based on own observations but confirm the details given in Graefe (1980), Chalupský (1992), and Dózsa-Farkas and Felföldi (2017): (1) Oesophageal appendage in V; (2) no conspicuously enlarged papillae; (3) coelomocytes larger, with a thinner margin, and with more granules in the centre; (4) dorsal blood vessel from VIII (in adult specimens); (5) spermathecae smaller, confined to V; (6) no clitellar gland cells in front of and behind the male pores; (7) longitudinal gland cell rows of clitellum with either hyalocytes or granulocytes, not both types in one row: dorsally two longitudinal rows of hyalocytes on each side, each separated by a longitudinal double row of granulocytes.
The first three of these differences are recognizable already in juvenile specimens. Of these the oesophageal appendage, present in A. camerani and absent in A. gemmata sp. nov., is most useful for the separation of these two species, whereas differences in papillae and coelomocytes are not always clearcut: lateral papillae can be small and inconspicuous in juveniles of A. gemmata sp. nov., whereas the lateral lense-shaped epidermal gland cells of A. camerani , found in exactly the same location as the papillae in A. gemmata sp. nov., may be inflated to resemble rudimentary or incipient papillae. Considering the coelomocytes, there is overlap in the thinness of the outer margin and the degree of inner granulation.
This new species belongs to the group of Achaeta species without pyriform glands. All species of this group have spermathecal pores in lateral position (vs. ventral in most of the species with pyriform glands) and most of them have lentiform epidermal gland cells in segmentally fixed and repetitive positions. These cells vary among species in number, colouration, and size. Segmental series of enlarged lentiform gland cells with conspicuous inner bulges of the body wall or protrusions beneath it, called papillae in this paper, are described from three further species, A. antefolliculata Dózsa-Farkas & Boros, 2005 , A. hanagarthi Schmelz, 2008 , and A. paranensis Schmelz, 2008 . In all of them, they are developed in different positions:
A. antefolliculata , described and known so far only from Hungary, has one pair each of enlarged lentiform gland cells laterally in III, IV, V, VI, and one dorsal pair in I: this dorsal shift in I is also seen in A. gemmata sp. nov. ( Fig. 3A View FIGURE 3 ). These glands appear to be as large as the lateral papillae in A. gemmata sp. nov. Further differences to the new species are segment number (20–21), only one pair of secondary pharyngeal gland lobes, in V, a smaller spermatheca, which is always confined to V, and clitellar glands cells in transverse rows with a narrow dorsal interruption. Achaeta hanagarthi Schmelz, 2008 and A. paranensis Schmelz, 2008 , both originally described and so far known only from Brazil, have enlarged lentiform gland cells only in ventral, but not in lateral, position; these glands are similar in shape and size to the ventral glands in A. gemmata sp. nov., which are notably smaller than the lateral ones. Further differences to the new species are as follows: A. hanagarthi : no secondary pharyngeal gland lobes, 1st nephridium at 7/8, clitellum widely open dorsally; A. paranensis : oesophageal appendage present, large in V, with canal in IV, intestinal diverticulum in VII, only one pair of preclitellar nephridia, at 5/6.
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The lentiform glands in Achaeta etrusca Rota, 1995 may also belong here (see Rota 2015) even though a figure ( Rota 2015, Fig. 4A View FIGURE 4 ) suggests that they are less enlarged and more similar to the ordinary lentiform gland cells such as found in A. pannonica Graefe, 1989 , A. iberica Graefe, 1989 , A. diddeni Graefe, 2007 , and A. brevivasa Graefe, 1980 . All lentiform gland cells that we consider as enlarged have two different compartments: a non-staining central region which connects with the body surface, and a strongly staining peripheral region which extends into the body cavity. It is mainly this staining region which is responsible for the increase in size of the lentiform gland cells. These two regions are also distinguishable in living organisms, as an inner and outer circle (comp. Fig. 4G View FIGURE 4 ). Schmelz et al. (2008) refer to enlarged and non-enlarged cells as “ type I” cells and “ type II” cells, respectively, but the difference between them is probably only one of degree.
Apart from the gem-like lateral papillae, the dorsal pattern of the clitellar gland cells is a most conspicuous feature of this new species. The complete coverage with longitudinal rows—i.e., the absence of a mid-dorsal gap— is already distinguishable in subadult specimens ( Fig. 4E View FIGURE 4 ), but the full pattern with alternating hyalocytes and granulocytes within a row is only seen in fully adult specimens (comp. Fig. 4I and 4E View FIGURE 4 ). As a further peculiarity, the most ventral row of granulocytes encloses the male pores, and one or two rows of granulocytes may be widened to form incomplete double rows ( Fig. 4H View FIGURE 4 , black asterisk).
Remarks, molecular comparison. Fourty-two COI sequences of 16 species of Achaeta , some of them without valid names, are publicly available. According to uncorrected p-distances calculated based on COI sequences ( Table 2 View TABLE 2 ), high interspecific distances to A gemmata sp. nov. were observed (15.7%–21.8%), except for one specimen, identified as Achaeta cf. brevivasa Graefe, 1980 (0%, GenBank accession number: GU902034) by Erséus et al. (2010), and collected from Sweden. This specimen should be considered as a misidentified Achaeta gemmata sp. nov. Unfortunately, there is no voucher of this specimen for a morphological comparison. Chen et al. (2022) redescribed Achaeta brevivasa collected from China; the specimens correspond well with the original description. The three respective COI sequences (GenBank accession numbers: ON419115–ON419117) differ in 16.4% from that of Achaeta cf. brevivasa sensu Erséus et al. (2010) . There are no DNA sequences from the type series of A. brevivasa and currently no other specimens identified as A. brevivasa with available DNA sequences.
Specimen ID | Genbank Accession N.º | Country | Reference | Achaeta florens sp. nov. | Achaeta gemmata sp. nov. | |
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Achaeta aberrans Nielsen & Christensen, 1961 | CE875 | GU902030.1 | Sweden | Erséus et al. 2010 | 0,19 | 0,18 |
Achaeta affinis Nielsen & Christensen, 1959 | 919 | KY583145.1 | Hungary | Dózsa-Farkas & Felföldi 2017 | 0,19 | 0,20 |
Achaeta affinis Nielsen & Christensen, 1959 | none | GU453383.1 | Denmark | Christensen & Glenner 2010 | 0,20 | 0,19 |
Achaeta bibulba Graefe, 1989 | CE1206 | GU902031.1 | Sweden | Erséus et al. 2010 | 0,20 | 0,21 |
Achaeta bibulba Graefe, 1989 | e115 | MT159573.1 | Russia | Lebedev et al. (unpublished) | 0,19 | 0,21 |
Achaeta bifollicula Chalupský, 1992 | CE1035 | GU902032.1 | Sweden | Erséus et al. 2010 | 0,19 | 0,16 |
Achaeta bohemica ( Vejdovský, 1879) | 885 | KY583141.1 | Hungary | Dózsa-Farkas & Felföldi 2017 | 0,19 | 0,18 |
Achaeta cf. bohemica ( Vejdovský, 1879) | CE1766 | GU902033.1 | Italy | Erséus et al. 2010 | 0,16 | 0,18 |
Achaeta brevivasa Graefe, 1980 | CJJ92 | ON419115.1 | China | Chen et al. 2022 | 0,18 | 0,16 |
Achaeta cf. brevivasa Graefe, 1980 | CE1234 | GU902034.1 | Sweden | Erséus et al. 2010 | 0,20 | 0,00* |
Achaeta camerani ( Cognetti, 1899) | 903 | KY583144.1 | Hungary | Dózsa-Farkas & Felföldi 2017 | 0,22 | 0,21 |
Achaeta camerani ( Cognetti, 1899) | CE790 | GU902035.1 | Sweden | Erséus et al. 2010 | 0,22 | 0,21 |
Achaeta danica Nielsen & Christensen, 1959 | 901 | KY583142.1 | Hungary | Dózsa-Farkas & Felföldi 2017 | 0,19 | 0,16 |
Achaeta cf. danica Nielsen & Christensen, 1959 | 860 | KY583134.1 | Hungary | Dózsa-Farkas & Felföldi 2017 | 0,19 | 0,20 |
Achaeta iberica Graefe, 1989 | CE1051 | GU902036.1 | Sweden | Erséus et al. 2010 | 0,20 | 0,17 |
Achaeta macroampullacea Dózsa-Farkas et al., 2018 | 1091 | MG252131.1 | Korea | Dózsa-Farkas et al. 2018 | 0,21 | 0,17 |
Achaeta tothi Dózsa-Farkas & Felföldi, 2017 | 882 | KY583140.1 | Hungary | Dózsa-Farkas & Felföldi 2017 | 0,21 | 0,19 |
Achaeta unibulba Graefe, Christensen & Dózsa-Farkas, 2005 | 851 | KY583130.1 | Hungary | Dózsa-Farkas & Felföldi 2017 | 0,20 | 0,19 |
Achaeta unibulba Graefe, Christensen & Dózsa-Farkas, 2005 | CE812 | GU902037.1 | Sweden | Erséus et al. 2010 | 0,20 | 0,19 |
Achaeta sp. | 1143 | MH124585.1 | Korea | Nagy et al. (unpublished) | 0,18 | 0,17 |
Achaeta sp. | BIOUG08058-B10 | MF544984.1 | Canada | deWaard et al. 2019 | 0,26 | 0,22 |
Achaeta sp. | 812_E7 | LT905364.1 | Switzerland | Vivien et al. 2017 | 0,18 | 0,17 |
Achaeta sp. | 1021_E7 | LT903839.1 | Switzerland | Vivien et al. 2017 | 0,20 | 0,19 |
COI |
University of Coimbra Botany Department |
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