Poecilimon jonicus (Fieber, 1853)
publication ID |
https://doi.org/ 10.1007/s13127-020-00466-9 |
persistent identifier |
https://treatment.plazi.org/id/225887E9-8F44-FFCC-FF27-FC994E76FA50 |
treatment provided by |
Felipe |
scientific name |
Poecilimon jonicus |
status |
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Evolution of Poecilimon jonicus View in CoL group
According to mitochondrial chronograms ( Fig. 6a–c View Fig ), P. jonicus group sensu lato shares a common ancestor 8–6 Ma ago, a time well corresponding to the Messinian period of the Miocene. As the Anatolian clade ( P. antalyaensis + P. isopterus ) constitutes the basal branch and the Cretan ( P. cretensis ) the subsequent one, Anatolian mainland seems to be the place of origin of the group ancestors. Hence, it can be assumed that desiccation in the Mediterranean during the Messinian salinity crisis (MSC) (5.96–5.33 Ma), especially in the Aegean area (e.g., Steininger and Rögl 1984; Dermitzakis 1990), provided distribution corridor for dispersal of an ancestral stock over the present distribution range of the group. However, the poorly resolved relationships between the Cretan, Balkan, and P. inflatus + P. martinae lineage suggest an early radiation within Anatolia or along the Aegean landmass connecting the Balkans and Anatolia during the MSC ( Fig. 7c View Fig ). The following post-Messinian transgression of the Mediterranean and Aegean area ca. 5.3–5.2 Ma ( Jolivet et al. 2006) acted as a vicariant event resulting in four geographically isolated stocks—ancestral P. inflatus + P. martinae in Anatolia and P. cretensis in Crete, the Northern, and Southern Balkan group in the southern Balkan mainland and on the Peloponnesos, respectively ( Fig. 8a View Fig ). In that case, the expected phylogeny of the group will be [( P. antalyaensis + P. isopterus ) + ( P. cretensis + ( P. inflatus + P. martinae ) + Northern Balkan clade + Southern Balkan clade)].
During Messinian, the level of the Mediterranean dropped after its isolation from the Atlantic. As a result of the MSC, the Aegean landmass was largely united again, and terrestrial migrations between the Balkan mainland and Crete were possible and documented (e.g., Dermitzakis 1990; Lymberakis et al. 2007). With the end of the Messinian 5.33 Ma ago and the Zanclean refill of the Mediterranean basin the Balkans, Anatolia and Crete were disconnected again ca. 5.2 Ma ago ( Meulenkamp 1985; Dermitzakis 1990). We believe these two periods are of major importance for dispersal, early speciation, and subsequent vicariance leading to major lineage splits within the Poecilimon jonicus group ( Figs. 7c View Fig , 8a View Fig ). Within this time frame (5.8/5.6 to 5.2 Ma), the Cretan lineage was established and shortly after that the Balkan lineage splits into a Northern and a Southern group. Roughly at the same time, the P. inflatus branch (present P. inflatus + P. martinae ) was established.
In Pliocene, the land-sea configuration further complicated with the development of many islands and peninsulas, as well as vast inland freshwater areas (marshes and lakes) ( Popov et al. 2004) ( Fig. 8a, b View Fig ). The latter may have contributed to the basal lineage splits within the Northern Balkan group ( P. werneri , P. jonicus superbus ), Southern Balkan group ( P. erimanthos ), and in the Anatolian group ( P. antalyaensis and P. isopterus ) due to vicariant events. Specifically, the lack of P. jonicus superbus in most of Puglia (southeastern corner of Italy) ( Fig. 2 View Fig ), though this area represented an island at the time this taxon originated, may possibly be explained as a result of recent climatic factors.
Latest speciation events are dated to the Pleistocene, starting with the onset of the northern hemisphere glaciation (2.5–2.6 Ma ago), when climate cycles with alternating cooler drier and warmer more humid periods dominated the area. Those climate events have been suggested as triggers for recent lineage splits in other Barbitistini ( Kaya et al. 2015; Chobanov et al. 2017). Pleistocene climate was dominated by two major climatic switches—first ca. 1.4 Ma, when 41- Ka cold-warm cycles become constant, and second, 0.8 Ma, when 100-Ka cycles established ( Lisiecki and Raymo 2007). Those periods of cooling and warming were connected not only with climate changes but also with sea level drops (glacials) and rises (interglacials). Thus, thermophilous animals dependent on modest humidity retreated to refuges and were isolated on islands during stadials (cold dry periods) and regained territories during interstadials (warm humid periods). Interesting correlation may be observed between the intraspecific divergence of the Cretan lineage ( P. cretensis ) and the second Pleistocene climatic switch ( Fig. 6b View Fig ). Patterns of the evolutionary history of Cretan lineages based on early vicariance are documented in various groups ( Parmakelis et al. 2005, 2006; Simaiakis and Mylonas 2008). Populations on the island were completely isolated after the end of the Messinian. Yet, the current appearance of Crete as a united landmass was established only recently, while many smaller island configurations existed during the Pliocene ( Creutzburg 1963; Dermitzakis 1990; Douris et al. 1998; Welter-Schultes 2000) ( Fig. 8a, b View Fig ). Relatively high genetic distances between sampled populations of P. cretensis could be a reflection of vicariant events during the Pleistocene as a result of isolation of the easternmost Cretan territory by lakes/brackish waters around that time.
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