HELICINAE, Rafinesque, 1815

Neiber, Marco T., Korábek, Ondřej, Glaubrecht, Matthias & Hausdorf, Bernhard, 2022, A misinterpreted disjunction: the phylogenetic relationships of the North African land snail Gyrostomella (Gastropoda: Stylommatophora: Helicidae), Zoological Journal of the Linnean Society 194 (4), pp. 1236-1251 : 1245-1248

publication ID	https://doi.org/10.1093/zoolinnean/zlab059
publication LSID	lsid:zoobank.org:pub:3ACD5252-F163-406B-ABCC-6B0F6457AA81
DOI	https://doi.org/10.5281/zenodo.6458766
persistent identifier	https://treatment.plazi.org/id/03E587AC-E16F-DF46-FC7C-0628FDD6FB0F
treatment provided by	Plazi (2022-04-13 06:56:05, last updated 2024-11-28 16:47:16)
scientific name	HELICINAE
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SYSTEMATICS OF THE HELICINAE View in CoL

Our phylogenetic analyses strongly support the monophyletic origin of the Maghreb radiation of Helicinae in the Oligocene in the Maghreb region ( Figs 3 View Figure 3 , 4 View Figure 4 ). However, our analyses do not provide a robust resolution of the relationships within the Maghreb radiation. Based on these results, we propose to include all groups of the Maghreb radiation (Thebini, Otalini and Ereminini) in a single tribe, for which the oldest available name is Thebini (see Table 1 View Table 1 for an overview of classifications and newly proposed synonyms of the Maghreb radiation of Helicinae based on molecular phylogenetic analyses). Holyoak et al. (2020) proposed subdividing the Maghreb groups into three tribes: Thebini (in the strict sense only including Theba ), Ereminini and Otalini (with a further subdivision into subtribes Otalina and Cantareusina Holyoak et al., 2020). However, Otalini in the sense of Holyoak et al. (2020) is neither statistically supported in their nor in our analyses ( Figs 3 View Figure 3 and 4 View Figure 4 ). The western Alpine Macularia was weakly joined with the North African Eremina in the analyses of Holyoak et al. (2020), but was not assigned to any tribe by these authors. Contrary to the analysis of Holyoak et al. (2020), our analyses strongly support a sister-group relationship of Macularia and the Thebini (in the wide sense). Because of the wide geographic disjunction between the western Alpine Macularia and the primarily Maghrebian Thebini, we suggest a tribe Maculariini trib. nov. [type genus: Macularia Albers, 1850 ; diagnosis: Helicinae supported by the following apomorphic nucleotide substitutions (based on the alignment deposited in TreeBase under the study accession number 27632): 16S (position 267: T → A; position 283: A → T); only positions considered with data for all taxa and only changes with a consistency index of 1.00 given] to adapt the Linnean systematics of Helicinae to the new findings (ZooBank registration: https://zoobank.org/ urn:lsid:zoobank.org:act:71BA5313-1FA2-48AE-8A3F-8ED8791EE4EE ).

*According to Holyoak et al. (2020) the specimen determined as Massylaea massylaea (Morelet, 1851) by Bouaziz-Yahiatene et al. (2017) is a misidentified Eobania constantina (Forbes, 1838) . † This placement was based on a misidentified sequence from GenBank attributed to Eremina desertorum (Forsskål, 1775) ( AY841335 View Materials ; in fact Levantina ).

This proposed classification closely mirrors the biogeographic history of the Helicinae . The Eastern Mediterranean Helicini diverged from the Western Mediterranean clade in the Eocene ( Fig. 4 View Figure 4 ). In the Late Eocene or Early Oligocene, the Western Mediterranean clade split into Allognathini in the Iberian Peninsula, Maculariini in the region of the future western Alps and Thebini on terranes probably including the Rif-Betic and Kabylies blocks that were at that time adjacent to south-western Europe, but later drifted south-westwards to form part of the Maghreb region ( Rosenbaum et al., 2002). Further phylogenetic investigations are necessary to provide a better resolution within the tribes as a basis for more detailed biogeographic reconstructions.

References

Bouaziz-Yahiatene H, Pfarrer B, Medjdoub-Bensaad F, Neubert E. 2017. Revision of Massylaea Mollendorff, 1898 (Stylommatophora, Helicidae). ZooKeys 694: 109 - 133.

Hausdorf B, Bamberger S, Walther F. 2020. A Sicilian - Cretan biogeographical disjunction in the land snail genus Cornu (Gastropoda: Helicidae). Zoological Journal of the Linnean Society. 192: 59 - 74.

Hesse P. 1911. In: Kobelt W, ed. Iconographie der Land- & Susswasser-Mollusken mit vorzuglicher Berucksichtigung der europaischen noch nicht abgebildeten Arten von E. A. Rossmassler. Neue Folge, Vol. 16 (5 / 6). Wiesbaden: Kreidel, 67 - 119, pls 441 - 450.

Hesse P. 1917. Kritische Fragmente. Nachrichtsblatt der Deutschen Malakozoologischen Gesellschaft 49: 122 - 124.

Holyoak DT, Holyoak GA, Gomez Moliner BJ, Chueca LJ. 2020. Phylogeny, species-limits and taxonomic revision of Otalini (Helicidae) from north-west Africa. Journal of Conchology 43: 551 - 611.

Kneubuhler J, Hutterer R, Pfarrer B, Neubert E. 2019. Anatomical and phylogenetic investigation of the genera Alabastrina Kobelt, 1904, Siretia Pallary, 1926, and Otala Schumacher, 1817 (Stylommatophora, Helicidae). ZooKeys 843: 1 - 37.

Kobelt W. 1904. Iconographie der Land- & Susswasser- Mollusken mit vorzuglicher Berucksichtigung der europaischen noch nicht abgebildeten Arten von E. A. Rossmassler. Neue Folge. Vol. 11. Wiesbaden: Kreidel.

Neiber MT, Hausdorf B. 2015. Molecular phylogeny reveals the polyphyly of the snail genus Cepaea (Gastropoda: Helicidae). Molecular Phylogenetics and Evolution 93: 143 - 149.

Razkin O, Gomez-Moliner BJ, Prieto CE, Martinez-Orti A, Arrebola JR, Munoz B, Chueca LJ, Madeira MJ. 2015. Molecular phylogeny of the western Palaearctic Helicoidea (Gastropoda, Stylommatophora). Molecular Phylogenetics and Evolution 83: 99 - 117.

Rosenbaum G, Lister GS, Duboz C. 2002. Reconstruction of the tectonic evolution of the western Mediterranean since the Oligocene. Journal of the Virtual Explorer 8: 107 - 130.

Wenz W. 1923. Gastropoda extramarina tertiaria. II. In: Diener C, ed. Fossilium Catalogus. I: Animalia 18. Berlin: Junk, 353 - 736.

Figures

Figure 3. Bayesian 50% majority-rule consensus tree based on the combined analysis of partial sequences of the mitochondrial COI and 16 S rRNA genes, as well as a part of the nuclear ribosomal RNA cluster covering parts of the 5.8 S rRNA gene, the complete ITS2 and a part of the 28 S rRNA gene. Values at the branches represent Bayesian posterior probabilities (left) and maximum likelihood bootstrap values (right). For information on vouchers, see Supporting Information, Table S2.

Figure 4. Dated 50% clade credibility tree with median node heights based on the combined analysis of partial sequences of the mitochondrial COI and 16 S rRNA genes, as well as a part of the nuclear ribosomal RNA cluster covering parts of the 5.8 S rRNA gene, the complete ITS2 and a part of the 28 S rRNA gene. Values at the nodes represent node ages in Ma. Bars represent 95% highest posterior density intervals and coloured squares at the nodes and the tips of the tree represent (estimated) ranges from the dispersal–extinction–cladogenesis (DEC) model. The arrows indicate the nodes where the DEC model and the DEC model allowing for founder-event speciation (+J) differed with regard to the estimated ancestral range. The node used for calibration is indicated by an asterisk. Insert map: delimitation of geographical areas considered in the biogeographic analyses: (1) Western Mediterranean region of Europe (incl. western Europe, northern Europe and parts of Central Europe), (2) western North Africa (incl. Cape Verde Islands), (3) Canary Islands and Madeira Archipelago (Macaronesian Archipelagos) and (4) Eastern Mediterranean region (incl. the Middle East, parts of eastern Central Europe and eastern Europe, the Caucasus region and adjacent areas).